Latest from Tom's Hardware in Amd-ryzen-7-3700x

CPU Benchmarks and Hierarchy 2026: CPU Rankings

Jake Roach — Sat, 18 Nov 2023 13:25:13 +0000

Exceptional Prime Day CPU deals

the best

If you're after the ultimate in gaming performance, there's no better option than the Ryzen 7 9800X3D. Thanks to its 93MB of L3 cache, this 8-core/16-thread processor can push out class-leading frame rates in every game out there. With only a 120W TDP, it even stays cooler than the competition, saving you a few extra bucks on that expensive AIO purchase.

Click the coupon box for the $20 discount.View Deal

Get Intel's latest and greatest processor, the 270K Plus, at an all-time low price. The 8p/16e core processor has plenty of oomph to plow through any workflow and games well, too.View Deal

Here are standout CPU deals from the Prime Day event, which is currently taking place.

CPU Benchmarks Rankings 2026

Tom's Hardware

In the album above, you can see our master charts for gaming, single-threaded, and multi-threaded performance for CPUs. For games, all of our testing was done with an Nvidia RTX 5090 FE, and for applications, our testing was done with an Nvidia RTX 2080 Ti FE. For applications, no compute is actively running on the GPU; it’s a glorified display output that shares a driver with our gaming GPU. You can find a full breakdown of the test benches we used at the end of this article.

Gaming CPU Benchmarks Rankings 2026

Gaming CPU Benchmarks Rankings 2026
CPU / (MSRP)	Street Price	1080p Gaming Score	Architecture	Cores/Threads (P+E)	Base/Boost Clock (GHz)	TDP / Maximum Power
Ryzen 7 9850X3D ($500)	$499	100%	Zen 5 X3D	8 / 16	4.7 / 5.6	120W / 162W
Ryzen 7 9800X3D ($480)	$464	97%	Zen 5 X3D	8 / 16	4.7 / 5.2	120W / 162W
Ryzen 9 9950X3D ($700)	$676	95.7%	Zen 5 X3D	16 / 32	4.3 / 5.7	170W / 230W
Ryzen 9 9900X3D ($600)	$530	86.9%	Zen 5 X3D	12 / 24	4.4 / 5.5	120W / 230W
Ryzen 7 7800X3D ($450)	$399	85.6%	Zen 4 X3D	8 / 16	4.2 / 5	120W / 162W
Ryzen 9 7950X3D ($700)	$650	83.9%	Zen 4 X3D	16 / 32	4.2 / 5.7	120W / 162W
Ryzen 5 7600X3D ($300)	$246	80.6%	Zen 4 X3D	6 / 12	4.1 / 4.7	65W / 88W
Core i9-14900K ($550)	$469	78.2%	Raptor Lake Refresh	24 / 32 (8+16)	3.2 / 6	125W / 253W
Core Ultra 7 270K Plus ($300)	$350	77.5%	Arrow Lake Refresh	24 / 24 (8+16)	3.7 / 5.5	125W / 250W
Ryzen 7 7900X3D ($600)	Out of Stock	77.1%	Zen 4 X3D	12 / 24	4.4 / 5.6	120W / 162W
Ryzen 9 9950X ($650)	$520	76.9%	Zen 5	16 / 32	4.7 / 5/7	170W / 230W
Core i9-13900K ($590)	Out of Stock	76.8%	Raptor Lake	24 / 32 (8+16)	3 / 5.8	125W / 253W
Core i7-14700K ($410)	$340	76.4%	Raptor Lake Refresh	20 / 28 (8+12)	3.4 / 5.6	125W / 253W
Core i7-13700K ($410)	Out of Stock	75.8%	Raptor Lake	16 / 24 (8+8)	3.4 / 5.4	125W / 253W
Ryzen 9 9900X ($500)	$439	73.9%	Zen 5	12 / 24	4.4 / 5.6	120W / 162W
Core Ultra 5 250K Plus ($200)	$220	73.3%	Arrow Lake Refresh	18 / 18 (6+12)	4.2 / 5.3	125W / 159W
Core i5-14600K ($320)	$300	72.8%	Raptor Lake Refresh	14 / 20 (6+8)	3.5 / 5.3	125W / 181W
Ryzen 5 9600X ($280)	$188	72.6%	Zen 5	6 / 12	3.9 / 5.4	65W / 88W
Core Ultra 9 285K ($590)	$557	71.8%	Arrow Lake	24 / 24 (8+16)	3.7 / 5.7	125W / 250W
Ryzen 9 7950X ($700)	Out of Stock	71%	Zen 4	16 / 32	4.5 / 5.7	170W / 230W
Core i5-13600K ($320)	$319	70.9%	Raptor Lake	14 / 20 (6+8)	3.5 / 5.1	125W / 181W
Ryzen 7 7700X ($400)	$249	70.6%	Zen 4	8 / 16	4.5 / 5.4	105W / 142W
Core Ultra 7 265K ($400)	$284	70.3%	Arrow Lake	20 / 20 (8+12)	3.9 / 5.5	125W / 250W
Ryzen 9 7900X ($550)	$299	69.2%	Zen 4	12 / 24	4.7 / 5.6	170W / 230W
Ryzen 5 7600X ($300)	$180	67.3%	Zen 4	6 / 12	4.7 / 5.3	105W / 142W
Core Ultra 5 245K ($320)	$202	67.1%	Arrow Lake	14 / 14 (6+8)	4.2 / 5.2	125W / 159W
Core i7-12700K ($410)	$285	65.8%	Alder Lake	12 / 20 (8+4)	3.6 / 5	125W / 190W
Core Ultra 5 225 ($183)	$180	62.5%	Arrow Lake	10 / 10 (6+4)	3.3 / 4.9	65W / 121W
Core i5-12600K ($290)	$185	60.8%	Alder Lake	10 / 16 (6+4)	3.7 / 4.9	125W / 150W
Core i5-14400 ($220)	$250	58%	Raptor Lake	10 / 16 (6+4)	2.5 / 4.7	65W / 154W

You can see the relative score for AMD and Intel CPUs above, measured against the Ryzen 7 9850X3D, which is the fastest gaming CPU on the market, per our testing. So, the Ryzen 7 9800X3D offers 97.04% of the performance of the Ryzen 7 9850X3D, while the Ryzen 9 7900X offers 69.28% of the performance. You can set any CPU as a baseline for comparison with Bench, which is available in Tom’s Hardware Premium.

All of our gaming tests were run with the RTX 5090 FE at 1080p with a mixture of High and Ultra settings. We run each test multiple times — usually between three and five — and pick the median result. In other words, the results we use are real, recorded runs, not an average of several different runs. This is important as some games, such as Far Cry 6, show great CPU scaling but are otherwise inconsistent run-to-run.

In addition to consistent hardware (test benches at the end of this article), we use a consistent test image between platforms. That means the same GPU driver, the same Windows install, the game version, etc. We also tested with Virtualization-Based Security (VBS) turned off, Resizable BAR turned on, and automatic overclocking features disabled. That includes the Intel Extreme power profile and AMD’s PBO, both of which aren’t covered under standard warranty.

For this refresh, we tested 17 games and then calculated a geometric mean of the results. A simple average would provide skewed results with such a large test pool. A geomean provides a more realistic view of how each CPU compares to the others.

Here are the games that we used for testing:

Counter-Strike 2
The Last of Us Part One
Cyberpunk 2077
Starfield
A Plague Tale: Requiem
Hogwarts Legacy
F1 24
Marvel’s Spider-Man 2
Baldur’s Gate 3
Monster Hunter: Wilds
Final Fantasy XIV
Microsoft Flight Simulator 2024
Doom: The Dark Ages
Oblivion Remastered
Far Cry 6
Hitman 3
Minecraft RTX

We’re constantly evaluating new games to include in our test suite — see our recent stories on Resident Evil Requiem CPU scaling and Crimson Desert CPU scaling — but we maintain a list of tried-and-true benchmarks for our hierarchy rankings. We want to avoid including brand-new titles, which may see many updates, to keep our rankings as true to reality as possible. If you want more about the rationale behind our game choices, see our behind the scenes look at our CPU hierarchy testing.

Single-Threaded CPU Benchmarks Rankings 2026

2026 Single-Threaded CPU Benchmarks
	Single-Threaded App Score	Architecture	Cores/Threads (P+E)	Base/Boost Clock (GHz)	TDP / Maximum Power
Core Ultra 7 270K Plus	100%	Arrow Lake Refresh	24 / 24 (8+16)	3.7 / 5.5	125W / 250W
Core Ultra 9 285K	98.5%	Arrow Lake	24 / 24 (8+16)	3.7 / 5.7	125W / 250W
Core Ultra 7 265K	96.8%	Arrow Lake	20 / 20 (8+12)	3.9 / 5.5	125W / 250W
Core i9-14900K	95.4%	Raptor Lake Refresh	24 / 32 (8+16)	3.2 / 6	125W / 253W
Core Ultra 5 250K Plus	94%	Arrow Lake Refresh	18 / 18 (6+12)	4.2 / 5.3	125W / 159W
Ryzen 9 9950X	93.3%	Zen 5	16 / 32	4.7 / 5/7	170W / 230W
Ryzen 7 9850X3D	93.2%	Zen 5 X3D	8 / 16	4.7 / 5.6	120W / 162W
Ryzen 9 9950X3D	92.8%	Zen 5 X3D	16 / 32	4.3 / 5.7	170W / 230W
Core Ultra 5 245K	92.5%	Arrow Lake	14 / 14 (6+8)	4.2 / 5.2	125W / 159W
Core i9-13900K	92.4%	Raptor Lake	24 / 32 (8+16)	3 / 5.8	125W / 253W
Ryzen 9 9900X	92.2%	Zen 5	12 / 24	4.4 / 5.6	120W / 162W
Ryzen 9 9900X3D	90.8%	Zen 5 X3D	12 / 24	4.4 / 5.5	120W / 230W
Ryzen 9 9700X / 105W TDP	90.6% / 90.5%	Zen 5	8 /16	3.8 / 5.5	65W / 88W
Core i7-14700K	90.1%	Raptor Lake Refresh	20 / 28 (8+12)	3.4 / 5.6	125W / 253W
Ryzen 5 9600X / 105W TDP	89% / 88.9%	Zen 5	6 / 12	3.9 / 5.4	65W / 88W
Ryzen 7 9800X3D	87.6%	Zen 5 X3D	8 / 16	4.7 / 5.2	120W / 162W
Core Ultra 5 225	87.3%	Arrow Lake	10 / 10 (6+4)	3.3 / 4.9	65W / 121W
Core i7-13700K	86.7%	Raptor Lake	16 / 24 (8+8)	3.4 / 5.4	125W / 253W
Core i5-14600K	85.8%	Raptor Lake Refresh	14 / 20 (6+8)	3.5 / 5.3	125W / 181W
Ryzen 9 7950X3D	85.4%	Zen 4 X3D	16 / 32	4.2 / 5.7	120W / 162W
Ryzen 9 7950X	85.2%	Zen 4	16 / 32	4.5 / 5.7	170W / 230W
Ryzen 9 7900X3D	84%	Zen 4 X3D	12 / 24	4.4 / 5.6	120W / 162W
Ryzen 7 7700X	84%	Zen 4	8 / 16	4.5 / 5.4	105W / 142W
Core i5-13600K	82.4%	Raptor Lake	14 / 20 (6+8)	3.5 / 5.1	125W / 181W
Core i7-12700K	79.7%	Alder Lake	12 / 20 (8+4)	3.6 / 5	125W / 190W
Core i5-12600K	78.6%	Alder Lake	10 / 16 (6+4)	3.7 / 4.9	125W / 150W
Ryzen 7 7800X3D	77.3%	Zen 4 X3D	8 / 16	4.2 / 5	120W / 162W
Core i5-14400	75.4%	Raptor Lake	10 / 16 (6+4)	2.5 / 4.7	65W / 154W
Ryzen 5 7600X3D	73.2%	Zen 4 X3D	6 / 12	4.1 / 4.7	65W / 88W
Ryzen 5 7600X	71.5%	Zen 4	6 / 12	4.7 / 5.3	105W / 142W

We run hundreds of tests for each CPU, but only a small subset of those tests factor into our single-threaded rankings. We use the mp3 encoder LAME with a single thread (both standard and extended), Cinebench 2026 and 2024’s single-threaded test, the ray-traced renderer POV-ray, and WebXRT4, which runs a series of browser-based applications written in various languages.

The fastest chip in the pool here is the Core Ultra 7 270K Plus, which scores 100%, with every other chip scored relative to it. The Core i9-14900K offers 95.4% of the single-threaded performance of the Core Ultra 7 270K Plus, the Ryzen 5 9600X offers 89% of the performance, and so on.

Most real-world workloads aren’t strictly single-threaded, which is why we include it on a subset of the total tests we run. The goal is to see what relative performance looks like in lightly-threaded applications, as well as look into the overall architecture of different CPUs. Single-threaded performance exposes a lot about the architecture in a way that heavily-threaded applications tend to mask.

We’re, of course, looking at performance on a single core, favoring high clock speeds and IPC (instructions per cycle). However, single-threaded performance also says a lot about what’s going on elsewhere inside the CPU, from the speed of the IMC (integrated memory controller) to the fabric/ring speed. That’s why we see things like the Core Ultra 7 270K Plus outperforming the Core Ultra 9 285K, despite the latter sporting higher clock speeds.

Multi-Threaded CPU Benchmarks Rankings 2026

2026 Multi-Threaded CPU Benchmarks
	Single-Threaded App Score	Architecture	Cores/Threads (P+E)	Base/Boost Clock (GHz)	TDP / Maximum Power
Ryzen 9 9950X3D	100%	Zen 5 X3D	16 / 32	4.3 / 5.7	170W / 230W
Ryzen 9 9950X	96.8%	Zen 5	16 / 32	4.7 / 5/7	170W / 230W
Core Ultra 7 270K Plus	95.6%	Arrow Lake Refresh	24 / 24 (8+16)	3.7 / 5.5	125W / 250W
Core Ultra 9 285K	88.7%	Arrow Lake	24 / 24 (8+16)	3.7 / 5.7	125W / 250W
Ryzen 9 7950X	88%	Zen 4	16 / 32	4.5 / 5.7	170W / 230W
Ryzen 9 7950X3D	84.4%	Zen 4 X3D	16 / 32	4.2 / 5.7	120W / 162W
Core i9-14900K	83.9%	Raptor Lake Refresh	24 / 32 (8+16)	3.2 / 6	125W / 253W
Core i9-13900K	81%	Raptor Lake	24 / 32 (8+16)	3 / 5.8	125W / 253W
Core Ultra 7 265K	78.9%	Arrow Lake	20 / 20 (8+12)	3.9 / 5.5	125W / 250W
Ryzen 9 9900X3D	77%	Zen 5 X3D	12 / 24	4.4 / 5.5	120W / 230W
Ryzen 9 9900X	76.7%	Zen 5	12 / 24	4.4 / 5.6	120W / 162W
Core i7-14700K	75.1%	Raptor Lake Refresh	20 / 28 (8+12)	3.4 / 5.6	125W / 253W
Core Ultra 5 250K Plus	70.9%	Arrow Lake Refresh	18 / 18 (6+12)	4.2 / 5.3	125W / 159W
Core i7-13700K	67.1%	Raptor Lake	16 / 24 (8+8)	3.4 / 5.4	125W / 253W
Ryzen 9 7900X3D	63.9%	Zen 4 X3D	12 / 24	4.4 / 5.6	120W / 162W
Ryzen 7 9850X3D	57%	Zen 5 X3D	8 / 16	4.7 / 5.6	120W / 162W
Ryzen 7 9800X3D	56.9%	Zen 5 X3D	8 / 16	4.7 / 5.2	120W / 162W
Core Ultra 5 245K	55.8%	Arrow Lake	14 / 14 (6+8)	4.2 / 5.2	125W / 159W
Core i5-14600K	53.9%	Raptor Lake Refresh	14 / 20 (6+8)	3.5 / 5.3	125W / 181W
Core i7-12700K	51.9%	Alder Lake	12 / 20 (8+4)	3.6 / 5	125W / 190W
Core i5-13600K	50.3%	Raptor Lake	14 / 20 (6+8)	3.5 / 5.1	125W / 181W
Ryzen 7 9700X / 105W TDP	47.2% / 53.2%	Zen 5	8 /16	3.8 / 5.5	65W / 88W
Ryzen 7 7700X	46.8%	Zen 4	8 / 16	4.5 / 5.4	105W / 142W
Ryzen 7 7800X3D	44.5%	Zen 4 X3D	8 / 16	4.2 / 5	120W / 162W
Ryzen 5 9600X / 105W TDP	39.7% / 41.7%	Zen 5	6 / 12	3.9 / 5.4	65W / 88W
Core i5-12600K	39.5%	Alder Lake	10 / 16 (6+4)	3.7 / 4.9	125W / 150W
Core Ultra 5 225	38.5%	Arrow Lake	10 / 10 (6+4)	3.3 / 4.9	65W / 121W
Ryzen 5 7600X3D	33.1%	Zen 4 X3D	6 / 12	4.1 / 4.7	65W / 88W
Core i5-14400	32.7%	Raptor Lake	10 / 16 (6+4)	2.5 / 4.7	65W / 154W
Ryzen 5 7600X	31.3%	Zen 4	6 / 12	4.7 / 5.3	105W / 142W

Similar to single-threaded rankings, we use a subset of the total tests we run for CPU reviews in ranking multithreaded performance. Cinebench and POV-ray show up here again, this time using as many threads as possible, alongside VRay, four Blender tests, and Handbrake using various codecs. Although most applications will leverage multiple threads these days, we’re specifically looking at applications that will take as many threads as possible to maximize compute.

Compared to single-threaded workloads, heavily-threaded tasks are less concerned with clock speed and put a greater emphasis on interconnects and core-to-core latency. Core count is obviously important, as well, though it’s been somewhat undermined by Intel’s hybrid architectures over the last several generations.

Given that we’re spanning multiple nodes, core count alone isn’t indicative of higher multithreaded performance. Yes, higher core counts within the same generation will usually provide higher multithreaded performance, but a slew of other factors can increase performance, as well, from all-core and uncore frequencies to higher transistor density. Because of the wide swath of factors, you can see much more aggressive scaling with our multithreaded rankings compared to single-threaded rankings.

Integrated GPU Gaming CPU Benchmarks Rankings 2026

Tom's Hardware

iGPU Performance relative to Ryzen 7 5700G
	1280x720	1920x1080
Ryzen 7 5700G B550-E	100%	100%
Ryzen 5 5600G	96.3%	96%
Ryzen 7 4750G	92.9%	94.1%
Ryzen 3 5300G	85.8%	87.2%
Ryzen 5 3400G	83.5%	84.1%
Ryzen 3 3200G	77.1%	78.1%
Intel UHD Graphics 750 32 EU (11600K, 11700K)	58.3%	~48.9%
Intel UHD Graphics 730 24 EU (i5-11400)	51.7%	42.9%
Intel UHD Graphics 630 24 EU (10600K)	36.0%	34.4%

Here's our list of gaming performance with integrated graphics on several of the leading APUs available. We've split this into two different price ranges, so be sure to flip through all of the performance charts. For a bit of commentary and analysis of these results, head to our Ryzen 7 5700G, Ryzen 5 5600G, and Ryzen 3 5300G reviews. The most powerful chip gets a 100, and all others are scored relative to it.

How to Benchmark your CPU

It’s important to know how to benchmark your CPU. It gives you a way to compare performance after an overclock or a CPU upgrade, and it allows you to check if you’re getting the full performance out of your system. Maybe a poor CPU cooler mount is limiting your performance, or maybe your BIOS settings aren’t optimal. Using benchmarks to compare your results lets you see where your rig stacks up, not only for leaderboard purposes, but also basic troubleshooting.

The key to benchmarking your CPU is consistency. The only variable that should change is your CPU, be it a new CPU or an overclock/undervolt. Before starting, make sure to close any applications running in the background. That’s not only to net peak performance, but also to avoid any inconsistencies between runs. Background apps can gobble up threads inconsistently, making it difficult to compare your results from run to run.

If you want more consistency, you can optionally run the following command before benchmarking in an elevated command prompt:

Rundll32.exe advapi32.dll,ProcessIdleTasks

This will force Windows to perform the background tasks it normally does when your PC is idle. It’s not essential, but it’s a good sanity check to make sure there’s nothing interfering with your results.

For applications, you want to test the apps you actually use. If you use the Adobe suite, for example, you can download and use PugetBench for free and compare your results with Puget’s database. A lot of apps don’t have these easy-to-use benchmarking tools and databases, so you need to find a proxy. For instance, Procyon Office measures Microsoft Office performance, but a license costs nearly $1,600 per year. PCMark 10 Basic, which is free, measures open-source office applications. Below, we have some of our favorite free benchmarks for comparing CPU performance.

In games, you can take two approaches: manual or automated. Some modern games include built-in benchmarking tools, such as Cyberpunk 2077 and Doom: The Dark Ages, and although they aren’t perfect, they’re easy to run and highly repeatable. The best way to measure CPU gaming performance, however, is manual benchmarking.

That involves finding a scene where you can go over a specific path repeatedly. That could be starting from a specific checkpoint that you can reload or resorting to a manual save where you start from the exact same position. Regardless, it’s important to avoid randomness in your testing. Keep the path consistent — for example, a walking path through a town — and try not to swing the camera around.

For measuring performance in games, you’ll need a performance monitoring tool. There are simple apps like Nvidia’s FrameView, which logs a ton of information but is a little cumbersome to deal with; it exports data to spreadsheets. CapFrameX is a good alternative, which uses the same backend as FrameView (Intel’s PresentMon), but comes with a user-friendly GUI and extra features like the ability to generate charts right in the app.

After you run your benchmarks, you need a comparison point. Databases like Puget are your best resources on that front. If you’re comparing results to reviews, forum threads, or other systems, keep in mind the variables that can influence performance. It’s not a good idea to compare performance with uncontrolled variables unless you have a wide swath of comparison points.

Best CPU Benchmarks You Can Run

Cinebench 2026 – Cinebench is the quintessential CPU benchmark, used almost universally in reviews, and it’s completely free to download and use.
Geekbench 6 – Geekbench has a number of issues, but it offers a massive database for comparing your system against other similar systems. And it’s free to download and run.
Blender – Blender has a benchmarking utility with a GUI that’s free to download, as well as a large database of results.
PCMark 10 Basic – The main PCMark 10 benchmark is free to use with the Basic edition, allowing you to test productivity performance with open-source office apps, as well as compare your scores with UL’s database.
Handbrake – Handbrake is a powerful, free, and open-source video transcoding tool, and it’s easy to run benchmarks with. Use any video file, make sure your settings are the same, and start a stopwatch to measure the time encoding takes. Lower is better.
WebXPRT 5 – WebXPRT runs a variety of web applications directly in your browser, for free, and with a database to compare results to. It takes a while to run, however.
JetStream 2 – JetStream is a faster browser-based benchmark, though it doesn’t have a database of results.
CPU-Z – CPU-Z isn’t a reliable benchmark for real-world performance, but it includes single- and multithreaded tests, it’s easy to run, and you’ll find results online almost as commonly as Cinebench results.
Y-cruncher – This test calculates Pi with digit extraction, and it’s accelerated with SIMD instructions like AVX. You can only run it from a command line, but it’s relatively straightforward.
PugetBench – Puget includes benchmarks for the biggest apps in the Adobe suite, as well as DaVinci Resolve. The benchmark itself is free, and Puget maintains a large database. You’ll need a license for the applications it tests, however.

2026 CPU Benchmarks Test System and Configuration

2026 CPU Benchmarks Hierarchy Test Setup
Intel LGA 1851 (Arrow Lake and Refresh)
Motherboard	ASRock Z890 Taichi
RAM	2x16GB G.Skill Trident Z Neo RGB DDR5-7200
Intel LGA 1700 (Raptor Lake, Alder Lake)
Motherboard	MSI MPG Z790 Carbon Wi-Fi
RAM	2x16GB G.Skill Trident Z Neo RGB DDR5-7200
AMD AM5 (Zen 5, Zen 4)
Motherboard	MSI MPG X870E Carbon Wi-Fi, Gigabyte Aorus X870E Elite X3D ICE
RAM	2x16GB G.Skill Trident Z Neo RGB DDR5-6000
All Systems
Gaming CPU	Nvidia GeForce RTX 5090 Founder’s Edition
Application GPU	Nvidia GeForce RTX 2080 Ti Founder’s Edition
Cooler	Corsair iCue Link H150i RGB
Storage	2TB Sabrent Rocket 4 Plus
PSU	MSI MPG A1000GS, Gigabyte UD1000GM PG5 V2
Other	Arctic MX-4 TIM, Windows 11 Pro, Alamengda open test bench

MORE: Best CPUs for Gaming
MORE: AMD vs Intel
MORE: 13th-Gen Raptor Lake All We Know
MORE: Zen 4 Ryzen 7000 All We Know
MORE: How to Overclock a CPU
MORE: How to check CPU Temperature
MORE: All CPUs Content

2020 - 2022 CPU Benchmarks Hierarchy

You can find our rankings of the most current-gen systems on the previous page. The results below are from our legacy benchmarks, using a different GPU and test systems than our current CPU benchmark rankings. However, this provides great historical context and also includes other previous-gen CPUs not included in our new test suite. You'll also find our even older legacy rankings further below. These date back over the last decade.

Legacy: 2020 - 2022 CPU Benchmarks Rankings - Windows 10 and 11

Tom's Hardware

Legacy: 2020 - 2022 Gaming CPU Benchmarks Ranking

Legacy: Gaming CPU Benchmarks Hierarchy 2020 - 2022 - Windows 11
	1080p Gaming Score	1440p Gaming Score	Architecture	Cores/Threads (P+E)	Base/Boost GHz	TDP - MTP
$589 - Core i9-13900K	100.00%	100.00%	Raptor Lake	24 / 32 (8+16)	3.0 / 5.8	125 / 253W
$409 - Core i7-13700K	96.09%	97.09%	Raptor Lake	16 / 24 (8+8)	3.4 / 5.4	125 / 253W
$365 - Ryzen 7 5800X3D	94.42%	97.45%	Zen 3	8 / 16	3.4 / 4.5	105W
$319 - Core i5-13600K	90.03%	92.94%	Raptor Lake	14 / 20 (6+8)	3.5 / 5.1	125 / 181W
$474 - Ryzen 9 7900X	87.40%	90.52%	Zen 4	12 / 24	4.7 / 5.6	170 / 230W
$569 - Ryzen 9 7950X	87.25%	90.27%	Zen 4	16 / 32	4.5 / 5.7	170 / 230W
$349 - Ryzen 7 7700X	87.13%	91.55%	Zen 4	8 /16	4.5 / 5.4	105 / 142W
$329 - Ryzen 7 7700	86.19%	88.88%	Zen 4	8 / 16	3.8 / 5.3	65 / 88W
$429 - Ryzen 9 7900	84.75%	88.46%	Zen 4	12 / 24	4.7 / 5.6	170 / 230W
$249 - Ryzen 5 7600X	83.62%	88.44%	Zen 4	6 / 12	4.7 / 5.3	105 / 142W
$229 - Ryzen 5 7600	79.74%	85.97%	Zen 4	6 / 12	3.8 / 5.1	65 / 88W
$550 - Ryzen 9 5950X	72.04%	77.51%	Zen 3	16 / 32	3.4 / 4.9	105W
$350 - Ryzen 9 5900X	71.69%	78.95%	Zen 3	12 / 24	3.7 / 4.8	105W
$235 - Ryzen 7 5800X	70.90%	78.19%	Zen 3	8 / 16	3.8 / 4.7	105W
$210 - Ryzen 7 5700X	69.50%	76.65%	Zen 3	8 / 16	3.4 / 4.6	65W
$165 - Ryzen 5 5600X	67.52%	74.68%	Zen 3	6 / 12	3.7 / 4.6	65W
$189 - Core i5-12400	66.62%	73.53%	Alder Lake	6 / 12 (6+0)	2.5 / 4.4	65 / 117W

Legacy: Gaming CPU Benchmarks Hierarchy 2020 - 2022 - Windows 10
	1080p Gaming Score	1440p Gaming Score	CPU	Cores/Threads	Base/Boost GHz	TDP	Buy
Intel Core i9-12900K DDR4 / DDR5	100% / 93.51%	100% / 95.86%	Alder Lake	16 / 24 (8P+8E)	3.2 / 5.2	125 / 241W	Core i9-12900K
Intel Core i9-11900K	92.48%	97.26%	Rocket Lake	8 / 16	3.5 / 5.3	125W	Core i9-11900K
Intel Core i7-12700K DDR4 / DDR5	97.71% / 91.23%	99.8% / 97.30%	Alder Lake	12 / 20 (8P+4E)	3.6 / 4.9	125 / 190W	Core i7-12700K
AMD Ryzen 9 5900X	90.98%	93.18%	Zen 3	12 / 24	3.7 / 4.8	105W	Ryzen 9 5900X
Intel Core i5-12600K DDR4 / DDR5	90.89% / 84.32%	96.94% / 92.33%	Alder Lake	10 / 16 (6P+4E)	3.7 / 4.9	125 / 150W	Core i5-12600K
AMD Ryzen 9 5950X	90.22%	95.32%	Zen 3	16 / 32	3.4 / 4.9	105W	Ryzen 9 5950X
AMD Threadripper Pro 5975WX	88.71%	89.71%	Zen 3	32 / 64	3.6 / 4.5	280W	Threadripper Pro 5975WX
AMD Ryzen 5 5600X	88.51%	91.79%	Zen 3	6 / 12	3.7 / 4.6	65W	Ryzen 5 5600X
AMD Ryzen 7 5800X	86.85%	91.72%	Zen 3	8 / 16	3.8 / 4.7	105W	Ryzen 7 5800X
Intel Core i7-11700K	86.3%	92.0%	Rocket Lake	8 / 16	3.6 / 5.0	125W	Core i7-11700K
AMD Threadripper Pro 5995WX	86.12%	84.79%	Zen 3	64 / 128	2.7 / 4.5	280W	Threadripper Pro 5995WX
Intel Core i9-10900K	85.01%	91.5%	Comet Lake	10 / 20	3.7 / 5.3	125W	Core i9-9900K
Intel Core i9-10850K	84.6%	91.07%	Comet Lake	10 / 20	3.6 / 5.2	95W	Core i9-10850K
Intel Core i5-11600K	84.06%	90.43%	Rocket Lake	6 / 12	3.9 / 4.9	125W	Core i5-11600K
Intel Core i5-11400	80.98%	87.77%	Rocket Lake	6 / 12	2.6 / 4.4	65W	Core i5-11400
Intel Core i7-10700K	80.66%	87.88%	Comet Lake	8 / 16	3.8 / 5.1	125W	Core i7-10700K
Intel Core i9-10980XE	78.04%	84.04%	Cascade Lake-X	18 / 36	3.0 / 4.8	165W	Core i9-10980XE
Intel W-3175X	76.93%	82.58%	Skylake	28 / 56	3.1 / 4.3	225W	@Newegg
Ryzen 7 5700G*	76.61%	83.1%	Zen 3	8 / 16	3.8 / 4.6	65W	N/A
Intel Core i9-9900KS	76.12%	84.85%	Coffee Lake-R	8 / 16	4.0 / 5.0	127W	Intel Core i9-9900KS
Intel Core i7-10700/F	~	~	Comet Lake	8 / 16	2.9 / 4.8	65W	Intel Core i7-10700
Intel Core i5-10600K	75.42%	82.57%	Comet Lake	6 / 12	4.1 / 4.8	125W	@Newegg
Intel Core i7-9700K	73.62%	81.12%	Coffee Lake-R	8 / 8	3.6 / 4.9	95W	@Amazon
Intel Core i9-9900K / F	73.41%	84.85%	Coffee Lake-R	8 / 16	3.6 / 5.0	95W	Core i9-9900K
AMD Ryzen 9 3950X	72.63%	78.58%	Zen 2	16 / 32	3.5 / 4.7	105W	@Amazon
AMD Threadripper 3970X	72.44%	77.99%	Zen 2	32 / 64	3.7 / 4.5	280W	AMD Threadripper 3970X
AMD Threadripper 3960X	72.07%	77.12%	Zen 2	24 / 48	3.8 / 4.5	280W	AMD Ryzen Threadripper 3960X
AMD Ryzen 5 5600G	71.99%	76.76%	Zen 3	6 / 12	3.9 / 4.4	65W	Ryzen 5 5600G
AMD Ryzen 7 3800XT	71.78%	79.28%	Zen 2	8 / 16	3.9 / 4.7	105W	@Newegg
AMD Threadripper 3990X	71.68%	77.94%	Zen 2	64 / 128	2.9 / 4.3	280W	AMD Ryzen Threadripper 3990X
AMD Ryzen 9 3900XT	71.67%	78.55%	Zen 2	12 / 24	3.8 / 4.7	105W	Ryzen 9 3900XT
AMD Ryzen 9 3900X	~	~	Zen 2	12 / 24	3.8 / 4.6	105W	@Amazon
Intel Core i9-9980XE	~	~	Skylake	18 / 36	4.4 / 4.5	165W	@B&HPhoto
AMD Ryzen 9 3900	~	~	Zen 2	12 / 24	3.1 / 4.3	105W	OEM only
AMD Ryzen 7 3700X	71.43%	79.08%	Zen 2	8 / 16	3.6 / 4.4	65W	Ryzen 7 3700X
AMD Ryzen 7 3800X	71.3%	78.67%	Zen 2	8 / 16	3.9 / 4.5	105W	Ryzen 7 3800X
AMD Ryzen 5 3600XT	70.62%	77.75%	Zen 2	6 / 12	3.8 / 4.5	95W	@Newegg
AMD Ryzen 5 3600	68.63%	75.59%	Zen 2	6 / 12	3.6 / 4.2	65W	@Amazon
Intel Core i9-7960X	~	~	Skylake	16 / 32	2.8 / 4.2	165W	@Newegg
Intel Core i7-8700K	68.47%	76.41%	Coffee Lake	6 / 12	3.7 / 4.7	95W	@Amazon
AMD Ryzen 5 3600X	68.41%	75.60%	Zen 2	6 / 12	3.8 / 4.4	95W	@Newegg
AMD Threadripper Pro 3975WX	67.63%	74.42%	Zen 2	32 / 64	3.5 / 4.2	280W	Threadripper Pro 3975WX
AMD Ryzen 3 3300X	67.49%	74.6%	Zen 2	4 / 8	3.8 / 4.3	65W	@Newegg
Intel Core i5-9600K	67.06%	75.11%	Coffee Lake-R	6 / 6	3.7 / 4.6	95W	@Newegg
AMD Threadripper Pro 3995WX	66.18%	69.28%	Zen 2	64 / 128	2.7 / 4.2	280W	Threadripper Pro 3995WX
Intel Core i5-8600K	65.84%	73.4%	Coffee Lake	6 / 6	3.6 / 4.3	95W	@Newegg
Intel Core i7-8700	65.57%	73.66%	Coffee Lake	6 / 12	3.2 / 4.6	65W	Core i7-8700
Intel Core i7-8086K	65.05%	73.5%	Coffee Lake	6 / 12	4.0 / 5.0	95W	Core i7-8086K
Intel Core i5-9400 / i5-9400F	64.85%	72.08%	Coffee Lake	6 / 6	2.9 / 4.1	65W	@Amazon
Intel Core i5-8400	63.96%	71.2%	Coffee Lake	6 / 6	2.8 / 4.0	65W	@Newegg
AMD Ryzen 5 3500X	~	~	Zen 2	6 / 6	3.6 / 4.1	65W	@Newegg
Core i3-10100	61.88%	69.08%	Comet Lake	4 / 8	3.6 / 4.3	65W	Core i3-10100
AMD Ryzen 7 2700X	59.19%	66.55%	Zen+	8 / 16	3.7 / 4.3	105W	@Newegg
Ryzen 7 4750G*	58.43%	66.46%	Zen 2	8 / 16	3.8 / 4.6	65W	Ryzen 7 4750G
AMD Ryzen 3 3100	57.75%	64.21%	Zen 2	4 / 8	3.8 / 3.9	65W	@Newegg
Intel Core i9-7980XE	~	~	Skylake	18 / 36	2.6 / 4.2	165W	@Amazon
Intel Core i9-7900X	~	~	Skylake	10 / 20	3.3 / 4.3	140W	@Newegg
AMD Ryzen 5 2600X	57.55%	65.33%	Zen+	6 / 12	3.6 / 4.2	95W	@Amazon
Intel Core i7-7700K	~	~	Kaby Lake	4 / 8	4.2 / 4.5	91W	@Amazon
AMD Threadripper 2990WX (GM)	~	~	Zen+	32 / 64	3.0 / 4.2	250W	@Newegg
Intel Core i7-7820X	~	~	Skylake	8 / 16	3.6 / 4.3	140W	@Amazon
AMD Threadripper 2950X (GM)	~	~	Zen +	16 / 32	3.5 / 4.4	180W	@Amazon
AMD Threadripper 2970WX	~	~	Zen +	24 / 48	3.0 / 4.2	250W	@Amazon
AMD Ryzen 7 2700	~	~	Zen+	8 / 16	3.2 / 4.1	65W	@Amazon
AMD Threadripper 1900X (GM)	~	~	Zen	8 / 16	3.8 / 4.0	180W	@Amazon
Intel Core i7-7700	~	~	Kaby Lake	4 / 8	3.6 / 4.2	65W	@Amazon
AMD Ryzen 5 2600	~	~	Zen+	6 / 12	3.4 / 3.9	65W	@Newegg
Intel Core i7-7800X	~	~	Skylake	6 / 12	3.5 / 4.0	140W	@Newegg
Intel Core i5-7600K	~	~	Kaby Lake	4 / 4	3.8 / 4.2	91W	@Amazon
AMD Threadripper 1950X (GM)	~	~	Zen	16 / 32	3.4 / 4.0	180W	@Newegg
AMD Threadripper 1920X (GM)	~	~	Zen	12 / 24	3.5 / 4.0	180W	@Amazon
Intel Core i3-9350KF	56.42%	65.19%	Coffee Lake	4 / 4	4.0 / 4.6	91W	@Amazon
AMD Ryzen 3 5300G	55.54%	62.68%	Zen 3	4 / 8	4.0 / 4.2	65W	OEM Only
AMD Ryzen 7 1800X	53.86%	60.83%	Zen	8 / 16	3.6 / 4.0	95W	@Newegg
Intel Core i5-7600	~	~	Kaby Lake	4 / 4	3.5 / 4.1	65W	@Amazon
Intel Core i3-8100	~	~	Coffee Lake	4 / 4	3.6 / -	65W	@Amazon
Intel Core i5-7500	~	~	Kaby Lake	4 / 4	3.4 / 3.8	65W	@Amazon
Intel Core i5-7400	~	~	Kaby Lake	4 / 4	3.0 / 3.5	65W	@Amazon
AMD Ryzen 7 1700X	~	~	Zen	8 / 16	3.8 / 3.9	95W	@Amazon
AMD Ryzen 5 1600AF	~	~	Zen +	6 / 12	3.2 / 3.6	65W	@Amazon
AMD Ryzen 7 1700	~	~	Zen	8 / 16	3.0 / 3.8	65W	@Newegg
Intel Core i3-8350K	53.84%	61.82%	Coffee Lake	4 / 4	4.0 / -	91W	Core i3 i3-8350K
Intel Core i3-9100	51.96%	60.1%	Coffee Lake-R	4 / 4	3.6 / 4.2	65W	@Newegg
AMD Ryzen 5 1600X	49.99%	57.28%	Zen	6 / 12	3.6 / 4.0	95W	@Amazon
AMD Ryzen 5 1600	~	~	Zen	6 / 12	3.2 / 3.6	65W	@Amazon
AMD Ryzen 5 3400G	48.81%	55.73%	Zen +	4 / 8	3.7 / 4.2	65W	@Amazon
Intel Core i5-7400	~	~	Kaby Lake	4 / 4	3.0 / 3.5	65W	@Newegg
Intel Core i3-8100	48.43%	59.7%	Coffee Lake	4 / 4	3.6 / -	65W	@Amazon
AMD Ryzen 3 3200G	45.96%	52.98%	Zen +	4 / 4	3.6 / 4.0	65W	@Amazon
AMD Ryzen 5 2400G	44.84%	50.67%	Zen+	4 / 8	3.6 / 3.9	65W	@Newegg
AMD Ryzen 5 1500X	~	~	Zen	4 / 8	3.5 / 3.7	65W	@Newegg
Intel Core i3-7350K	~	~	Kaby Lake	2 / 4	4.2 / -	60W	@Newegg
Intel Pentium G5600	~	~	Coffee Lake	2 / 4	3.9 / -	54W	@Newegg
AMD Ryzen 3 2200G	42.16%	48.56%	Zen+	4 / 4	3.5 / 3.7	65W	@Amazon
AMD Ryzen 3 1300X	~	~	Zen	4 / 4	3.5 / 3.7	65W	@Amazon
Intel Core i3-7300	~	~	Kaby Lake	2 / 4	4.0 / -	51W	@BH&Photo
Intel Pentium G5600	37.52%	44.7%	Coffee Lake	2 / 4	3.9 / -	54W	@Intel
Intel Pentium G5400	36.57%	43.31%	Coffee Lake	2 / 4	3.7 / -	54W	@Amazon
Intel Core i3-7100	~	~	Kaby Lake	2 / 4	3.9 / -	51W	@Amazon
AMD Ryzen 5 1400	~	~	Zen	4 / 8	3.2 / 3.4	65W	@Amazon
Intel Pentium G4620	~	~	Kaby Lake	2 / 4	3.7 / -	54W	@Newegg
Intel Pentium G4560	~	~	Kaby Lake	2 / 4	3.5 / -	54W	@Newegg
AMD Athlon 3000G	~	~	Zen+	2 / 4	3.5 / -	35W	@Amazon
AMD Athlon 240GE	~	~	Zen	2 / 4	3.5 / -	35W	@Amazon
AMD Athlon 220GE	~	~	Zen	2 / 4	3.4 / -	35W	@Amazon
AMD Athlon 200GE	~	~	Zen	2 / 4	3.2 / -	35W	@Amazon
AMD Ryzen 3 1200	~	~	Zen	4 / 4	3.1 / 3.2	65W	@Amazon
Zhaoxin KaiXian KX-U6780A	~	~	LuJiaZui	8 / 8	2.7 / -	70W	N/A
AMD A10-9700	~	~	Bristol Ridge	4 / 4	3.5 / 3.8	65W	@Newegg

These tests are from our 2022 test bench. We measured performance for the 1080p CPU gaming benchmarks with a geometric mean of Borderlands 3, Hitman 2, Far Cry 5, Project CARS 3, Red Dead Redemption 2, and Shadow of the Tomb Raider. We measured performance for the 1440p CPU gaming benchmarks with a geometric mean of Borderlands 3, Project CARS 3, Far Cry 5, Red Dead Redemption 2, and Shadow of the Tomb Raider. We conducted these tests in Windows 10.

Legacy: 2020 - 2022 Single-Threaded CPU Benchmarks Rankings

Legacy: 2020 - 2022 Single-Threaded CPU Benchmarks Hierarchy - Windows 10
	Single-Threaded App Score	Architecture	Cores/Threads	Base/Boost GHz	TDP
Intel Core i9-11900K (ABT off/on)	100% / 99.57%	Rocket Lake	8 / 16	3.5 / 5.3	125W
AMD Ryzen 9 5950X	95.31%	Zen 3	16 / 32	3.4 / 4.9	105W
Core i9-12900K DDR5 / DDR4	95.16% / 94.64%	Alder Lake	16 / 24 (8P+8E)	3.2 / 5.2	125 / 241W
Core i7-11700K	94.29%	Rocket Lake	8 / 16	3.6 / 5.0	95W
AMD Ryzen 9 5900X	93.69%	Zen 3	12 / 24	3.7 / 4.8	105W
AMD Ryzen 7 5800X	92.84%	Zen 3	8 / 16	3.8 / 4.7	105W
Intel Core i5-11600K	92.56% / 89.67%	Rocket Lake	8 / 16	3.9 / 4.9	125W
Intel Core i7-12700K DDR5 / DDR4	91.60%	Alder Lake	12 / 20 (8P+4E)	3.6 / 4.9	125W / 190W
AMD Threadripper Pro 5975WX	89.25%	Zen 3	64 / 128	2.7 / 4.5	280W
AMD Ryzen 5 5600X	89.19%	Zen 3	6 / 12	3.7 / 4.6	65W
Ryzen 7 5700G	88.92%	Zen 3	8 / 16	3.9 / 4.4	65W
AMD Threadripper Pro 5995WX	88.48%	Zen 3	64 / 128	3.6 / 4.5	280W
Core i5-12600K DDR4 / DDR5	87.85% / 87.82%	Alder Lake	10 / 16 (6P+4E)	3.7 / 4.9	125 / 150W
Intel Core i9-10900K	86.68%	Comet Lake	10 / 20	3.7 / 5.3	125W
AMD Ryzen 5 5600G	85.75%	Zen 3	6 / 12	3.9 / 4.4	65W
Intel Core i9-10850K	84.87%	Comet Lake	10 / 20	3.6 / 5.2	95W
Intel Core i9-9900KS	83.13%	Coffee Lake-R	8 / 16	4.0 / 5.0	127W
Intel Core i5-11400	83.09%	Rocket Lake	6 / 12	2.6 / 4.4	65W
Intel Core i9-9900K	82.63%	Coffee Lake-R	8 / 16	3.6 / 5.0	95W
Intel Core i7-10700K	82.31%	Comet Lake	8 / 16	3.8 / 5.1	125W
AMD Ryzen 3 5300G	81.51%	Zen 3	4 / 8	4.0 / 4.2	65W
Intel Core i7-9700K	80.36%	Coffee Lake-R	8 / 8	3.6 / 4.9	95W
AMD Ryzen 7 3800XT	79.75%	Zen 2	8 / 16	3.9 / 4.7	105W
AMD Ryzen 5 3600XT	79.11%	Zen 2	6 / 12	3.8 / 4.5	95W
AMD Ryzen 9 3900XT	78.86%	Zen 2	12 / 24	3.8 / 4.7	105W
Intel Core i5-10600K	78.79%	Comet Lake	6 / 12	4.1 / 4.	125W
AMD Ryzen 7 3800X	78.37%	Zen 2	8 / 16	3.9 / 4.5	105W
AMD Ryzen 9 3950X	78.18%	Zen 2	16 / 32	3.5 / 4.7	105W
AMD Ryzen 9 3900X	77.68%	Zen 2	12 / 24	3.8 / 4.6	105W
Intel Core i7-10700/F	~	Comet Lake	8 / 16	2.9 / 4.8	65W
Ryzen 7 4750G	77.2%	Zen 3	8 /16	3.6 / 4.4	65W
AMD Threadripper 3970X	76.52%	Zen 2	32 / 64	3.7 / 4.5	280W
AMD Threadripper 3960X	76.42%	Zen 2	24 / 48	3.8 / 4.5	280W
AMD Threadripper Pro 3975WX	76.36%	Zen 2	32 / 64	3.5 / 4.2	280W
Intel Core i7-8700K	76.32%	Coffee Lake	6 / 12	3.7 / 4.7	95W
AMD Ryzen 7 3700X	76.29%	Zen 2	8 / 16	3.6 / 4.4	65W
Intel Core i7-8086K	76.21%	Coffee Lake	6 / 12	4.0 / 5.0	95W
AMD Ryzen 5 3600X	75.85%	Zen 2	6 / 12	3.8 / 4.4	95W
Intel Core i3-9350KF	75.72%	Coffee Lake	4 / 4	4.0 / 4.6	91W
AMD Ryzen 3 3300X	75.62%	Zen 2	4 / 8	3.8 / 4.3	65W
Intel Core i5-9600K	75.41%	Coffee Lake-R	6 / 6	3.7 / 4.6	95W
Intel Core i9-10980XE	75.24%	Cascade Lake-X	18 / 36	3.0 / 4.8	165W
AMD Threadripper 3990X	75.10%	Zen 2	64 / 128	2.9 / 4.3	280W
Intel Core i7-8700	74.66%	Coffee Lake	6 / 12	3.2 / 4.6	65W
AMD Threadripper Pro 3995WX	74.20%	Zen 2	64 / 128	2.7 / 4.2	280W
AMD Ryzen 5 3600	73.02%	Zen 2	6 / 12	3.6 / 4.2	65W
Intel Core i9-9980XE	~	Skylake	18 / 36	4.4 / 4.5	165W
Intel Core i7-7700K	~	Kaby Lake	4 / 8	4.2 / 4.5	91W
Intel Core i5-8600K	71.08%	Coffee Lake	6 / 6	3.6 / 4.3	95W
Core i3-10100	70.80%	Coffee Lake	4 / 8	3.6 / 4.3	65W
AMD Ryzen 7 2700X	69.53%	Zen+	8 / 16	3.7 / 4.3	105W
Intel Core i3-9100	69.20%	Coffee Lake-R	4 / 4	3.6 / 4.2	65W
AMD Ryzen 3 3100	67.74%	Zen 2	4 / 8	3.8 / 3.9	65W
Intel Core i5-9400 / -9400F	67.67%	Coffee Lake	6 / 6	2.9 / 4.1	65W
Intel Xeon W-3175X	67.51%	Skylake	28 / 56	3.1 / 3.8	225W
AMD Ryzen 5 2600X	66.78%	Zen+	6 / 12	3.6 / 4.2	95W
Intel Core i3-8350K / -8350KF	66.71%	Coffee Lake	4 / 4	4.0 / -	91W
Intel Core i5-8400	66.03%	Coffee Lake	6 / 6	2.8 / 4.0	65W
AMD Ryzen 5 3500X	~	Zen 2	6 / 6	3.6 / 4.1	65W
AMD Ryzen 9 3900	~	Zen 2	12 / 24	3.1 / 4.3	65W
Intel Core i3-7100	~	Kaby Lake	2 / 4	3.9 / -	51W
AMD Threadripper 2950X	~	Zen +	16 / 32	3.5 / 4.4	180W
AMD Threadripper 2990WX	~	Zen+	32 / 64	3.0 / 4.2	250W
AMD Threadripper 2970WX	~	Zen +	24 / 48	3.0 / 4.2	250W
AMD Ryzen 5 3400G	64.86%	Zen +	4 / 8	3.7 / 4.2	65W
AMD Ryzen 5 1600X	63.62%	Zen	6 / 12	3.6 / 4.0	95W
AMD Ryzen 7 1800X	61.99%	Zen	8 / 16	3.6 / 4.0	95W
Intel Core i5-7400	~	Kaby Lake	4 / 4	3.0 / 3.5	65W
AMD Ryzen 3 3200G	60.90%	Zen +	4 / 4	3.6 / 4.0	65W
AMD Ryzen 5 2400G	60.79%	Zen+	4 / 8	3.6 / 3.9	65W
AMD Ryzen 3 1300X	~	Zen	4 / 4	3.5 / 3.7	65W
AMD Ryzen 5 1600AF	~	Zen	6 / 12	3.2 / 3.6	65W
Intel Pentium G5600	60.13%	Coffee Lake	2 / 4	3.9 / -	54W
Intel Core i3-8100	60.12%	Coffee Lake	4 / 4	3.6 / -	65W
AMD Ryzen 3 2200G	57.09%	Zen	4 / 4	3.5 / 3.7	65W
Intel Pentium G5400	56.79%	Coffee Lake	2 / 4	3.7 / -	54W
AMD Athlon 3000G	~	Zen+	2 / 4	3.5 / -	35W
AMD Athlon 220GE	~	Zen	2 / 4	3.4 / -	35W
Intel Pentium G4560	~	Kaby Lake	2 / 4	3.5 / -	54W
AMD Athlon 200GE	~	Zen	2 / 4	3.2 / -	35W
AMD A10-9700	~	Bristol Ridge	4 / 4	3.5 / 3.8	65W
Zhaoxin KaiXian KX-U6780A	~	LuJiaZui	8 / 8	2.7 / -	70W

These results are from our 2022 test bench. We calculate the above single-threaded CPU benchmark rankings based on a geometric mean of the Cinebench, POV-Ray, and LAME CPU benchmarks. The most powerful chip gets a 100, and all others are scored relative to it. We conducted these tests in Windows 10.

Legacy: 2020 - 2022 Multi-Threaded CPU Benchmarks Rankings

Legacy: Multi-Threaded CPU Benchmarks Hierarchy 2020 - 2022 - Windows 10
	Multi-Threaded App Score	Architecture	Cores/Threads	Base/Boost GHz	TDP
AMD Threadripper Pro 5995WX	112.53%	Zen 3	64 / 128	2.7 / 4.5	280W
AMD Threadripper 3990X	100.0%	Zen 2	64 / 128	2.9 / 4.3	280W
AMD Threadripper Pro 3995WX	97.59%	Zen 2	64 / 128	2.7 / 4.2	280W
AMD Threadripper Pro 5975WX	93.14%	Zen 3	32 / 64	3.6 / 4.5	280W
AMD Threadripper Pro 3975WX	82.59%	Zen 2	32 / 64	3.5 / 4.2	280W
AMD Threadripper 3970X	75.74%	Zen 2	32 / 64	3.7 / 4.5	280W
AMD Threadripper 3960X	64.76%	Zen 2	24 / 48	3.8 / 4.5	280W
Intel Xeon W-3175X	59.95%	Skylake	28 / 56	3.1 / 4.3	225W
AMD Ryzen 9 5950X	53.58%	Zen 3	16 / 32	3.4 / 4.9	105W
AMD Ryzen 9 3950X	47.32%	Zen 2	16 / 32	3.5 / 4.7	105W
AMD Ryzen 9 5900X	45.89%	Zen 3	12 / 24	3.7 / 4.8	105W
Intel Core i9-10980XE	43.06%	Cascade Lake-X	18 / 36	3.0 / 4.8	165W
Intel Core i9-9980XE	~	Skylake	18 / 36	4.4 / 4.5	165W
AMD Threadripper 2990WX	~	Zen+	32 / 64	3.0 / 4.2	250W
AMD Ryzen 9 3900X	38.69%	Zen 2	12 / 24	3.8 / 4.6	105W
AMD Ryzen 9 3900XT	38.66%	Zen 2	12 / 24	3.8 / 4.7	105W
Core i9-12900K DDR4 / DDR5	38.39% / 38.11%	Alder Lake	16 / 24 (8P+8E)	3.2 / 5.2	125 / 241W
Intel Core i9-11900K (ABT off/on)	36.01% / 37.07%	Rocket Lake	8 / 16	3.5 / 5.3	125W
AMD Threadripper 2970WX	~	Zen +	24 / 48	3.0 / 4.2	250W
Core i7-11700K	34.26%	Rocket Lake	8 / 16	3.6 / 5.0	125W
Intel Core i9-10900K	33.79%	Comet Lake	10 / 20	3.7 / 5.3	125W
AMD Ryzen 7 5800X	33.48%	Zen 3	8 / 16	3.8 / 4.7	105W
Intel Core i9-10850K	33.38%	Comet Lake	10 / 20	3.6 / 5.2	95W
AMD Threadripper 2950X	~	Zen +	16 / 32	3.5 / 4.4	180W
AMD Ryzen 9 3900	~	Zen 2	12 / 24	3.1 / 4.3	65W
Ryzen 7 5700G	29.73%	Zen 3	8 / 16	3.8 / 4.6	65W
Intel Core i9-9900KS	29.11%	Coffee Lake-R	8 / 16	4.0 / 5.0	127W
Core i7-12700K DDR5 / DDR4	28.77% / 28.77%	Alder Lake	12 / 20 (8P+4E)	2.7 / 3.8	125 / 190W
AMD Ryzen 7 3800XT	28.49%	Zen 2	8 / 16	3.9 / 4.7	105W
AMD Ryzen 7 3800X	28.25%	Zen 2	8 / 16	3.9 / 4.5	105W
Intel Core i7-10700K	28.17%	Comet Lake	8 / 16	3.8 / 5.1	125W
Intel Core i9-9900K	27.78%	Coffee Lake-R	8 / 16	3.6 / 5.0	95W
AMD Ryzen 7 3700X	27.47%	Zen 2	8 / 16	3.6 / 4.4	65W
Intel Core i5-11600K	26.79%	Rocket Lake	8 / 16	3.9 / 4.9	125W
AMD Ryzen 5 5600X	26.15%	Zen 3	6 / 12	3.7 / 4.6	65W
AMD Ryzen 7 4750G	26.06%	Zen 3	8 / 16	3.6 / 4.4	65W
Intel Core i7-10700/F	~	Comet Lake	8 / 16	2.9 / 4.8	65W
Intel Core i5-11400	24.46%	Rocket Lake	6 / 12	2.6 / 4.4	65W
AMD Ryzen 5 5600G	23.33%	Zen 3	6 / 12	3.9 / 4.4	65W
Core i5-12600K DDR4 / DDR5	2308% / 23.07%	Alder Lake	10 / 16 (6P+4E)	3.7 / 4.9	125 / 150W
Intel Core i7-9700K	22.81%	Coffee Lake-R	8 / 8	3.6 / 4.9	95W
AMD Ryzen 5 3600XT	22.28%	Zen 2	6 / 12	3.8 / 4.5	95W
AMD Ryzen 5 3600X	21.76%	Zen 2	6 / 12	3.8 / 4.4	95W
AMD Ryzen 5 3600	21.41%	Zen 2	6 / 12	3.6 / 4.2	65W
AMD Ryzen 7 2700X	21.59%	Zen+	8 / 16	3.7 / 4.3	105W
Intel Core i5-10600K	20.83%	Comet Lake	6 / 12	4.1 / 4.8	125W
Intel Core i7-8700K	20.23%	Coffee Lake	6 / 12	3.7 / 4.7	95W
Core i7-8700	20.04%	Coffee Lake	6 / 12	3.2 / 4.6	65W
Core i7-8086K	19.30%	Coffee Lake	6 / 12	4.0 / 5.0	95W
AMD Ryzen 7 1800X	19.17%	Zen	8 / 16	3.6 / 4.0	95W
AMD Ryzen 5 2600X	16.96%	Zen+	6 / 12	3.6 / 4.2	95W
Intel Core i5-9600K	16.60%	Coffee Lake-R	6 / 6	3.7 / 4.6	95W
AMD Ryzen 5 3500X	~	Zen 2	6 / 6	3.6 / 4.1	65W
Intel Core i7-7700K	~	Kaby Lake	4 / 8	4.2 / 4.5	91W
Intel Core i5-8600K	15.93%	Coffee Lake	6 / 6	3.6 / 4.3	95W
AMD Ryzen 3 5300G	15.83%	Zen 3	4 / 8	4.0 / 4.2	65W
AMD Ryzen 3 3300X	15.55%	Zen 2	4 / 8	3.8 / 4.3	65W
AMD Ryzen 5 1600AF	~	Zen	6 / 12	3.2 / 3.6	65W
AMD Ryzen 5 1600X	15.16%	Zen	6 / 12	3.6 / 4.0	95W
Intel Core i5-9400 / -9400F	15.04%	Coffee Lake	6 / 6	2.9 / 4.1	65W
Intel Core i5-8400	14.76%	Coffee Lake	6 / 6	2.8 / 4.0	65W
AMD Ryzen 3 3100	14.17%	Zen 2	4 / 8	3.8 / 3.9	65W
Core i3-10100	13.37%	Rocket Lake	4 / 8	3.6 / 4.3	65W
Intel Core i3-9350KF	11.76%	Coffee Lake	4 / 4	4.0/4.6	91W
AMD Ryzen 5 3400G	11.31%	Zen +	4 / 8	3.7 / 4.2	65W
Intel Core i3-8350K	10.74%	Coffee Lake	4 / 4	4.0 / -	91W
Intel Core i3-9100	10.70%	Coffee Lake-R	4 / 4	3.6 / 4.2	65W
AMD Ryzen 5 2400G	10.56%	Zen+	4 / 8	3.6 / 3.9	65W
Intel Core i3-8100	9.61%	Coffee Lake	4 / 4	3.6 / -	65W
Intel Core i5-7400	~	Kaby Lake	4 / 4	3.0 / 3.5	65W
AMD Ryzen 3 3200G	8.66%	Zen +	4 / 4	3.6 / 4.0	65W
AMD Ryzen 3 1300X	~	Zen	4 / 4	3.5 / 3.7	65W
Intel Core i3-7100	~	Kaby Lake	2 / 4	3.9 / -	51W
AMD Ryzen 3 2200G	7.99%	Zen	4 / 4	3.5 / 3.7	65W
Intel Pentium G5600	5.43%	Coffee Lake	2 / 4	3.9 / -	54W
AMD Athlon 3000G	~	Zen+	2 / 4	3.5 / -	35W
AMD Athlon 220GE	~	Zen	2 / 4	3.4 / -	35W
Intel Pentium G5400	5.13%	Coffee Lake	2 / 4	3.7 / -	54W
AMD Athlon 200GE	~	Zen	2 / 4	3.2 / -	35W
Intel Pentium G4560	~	Kaby Lake	2 / 4	3.5 / -	54W
AMD A10-9700	~	Bristol Ridge	4 / 4	3.5 / 3.8	65W
Zhaoxin KaiXian KX-U6780A	~	LuJiaZui	8 / 8	2.7 / -	70W

These tests are from our 2022 test bench. The multi-threaded workload column is based on CPU benchmarks performance in Cinebench, POV-ray, vray, Blender (four tests - Koro, Barcellona, Classroom, bmw27), y-cruncher, and Handbrake x264 and x265 workloads. These CPU benchmarks represent performance in productivity-focused applications that tend to require more compute horsepower. The most powerful chip gets a 100, and all others are scored relative to it. We conducted these benchmarks in Windows 10.

Legacy 2023 CPU Benchmarks Hierarchy Test Setup
Hardware
AMD Socket AM4 (400- 500-Series)	AMD Ryzen 2000- 3000- 5000- series processors
	MSI MEG X570 Godlike
	2x 8GB Trident Z Royal DDR4-3600
Intel LGA 1151 (Z490)	Intel Comet Lake processors
	MSI Z370 Gaming Pro Carbon AC
	2x 8GB Trident Z Royal DDR4-3600
AMD Socket AM4 (300-Series)	Ryzen 1000-series processors
	MSI X370 Xpower Gaming Titanium
	2x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2667
Intel LGA 1151 (Z270)	Intel Coffee Lake, Kaby Lake processors
	MSI Z270 Gaming M7
	2x 8GB Trident Z Royal DDR4-3600
Intel LGA 2066	Intel Skylake processors
	MSI X299 Gaming Pro Carbon AC
	2x 8GB Trident Z Royal DDR4-3600
All	Gigabyte GeForce RTX 3090 Eagle
	2TB Intel DC4510 SSD
	EVGA Supernova 1600 T2, 1600W
	Windows 10 Pro version 2004 (build 19041.450)
Cooling	Corsair H115i

Legacy: Pre-2018 Desktop CPU Benchmarks

Recognizing that a lot of older platforms are going to be paired with graphics subsystems multiple generations old, we wanted to define the top of our range to encourage balance between host processing and complementary GPUs. At this point, anyone with a Sandy Bridge-based Core i7 would realize a gain from stepping up to Coffee Lake or Kaby Lake, for example. And putting AMD's top FX CPUs next to a handful of Core i7s and those older Core i5s represents an upgrade to their status.

Currently, our hierarchy consists of 13 total tiers. The bottom half of the chart is largely outdated; you'll notice those CPUs dragging down performance in the latest games, whether you have one of the best graphics cards or not. If you own a CPU in that range, an upgrade could really take your experience to another level.

Really, it's the top five tiers or so that remain viable. And in that top half of the chart, an upgrade is typically worthwhile if it's a least a couple of tiers higher. Otherwise, there's just not enough improvement to warrant the expense of a fresh CPU, motherboard and RAM (not to mention the graphics card and storage solution you'd be considering as well).

Legacy: Pre-2018 Desktop CPU Benchmarks Hierarchy
Intel CPUs	AMD CPUs and APUs
Intel Core i7-8700K
Intel Core i9-7900X
Intel Core i9-7960X
Intel Core i9-7980XE
Intel Core i7-8700K
Intel Core i7-7740X
Intel Core i7-7700K
Intel Core i7-7820X	AMD Ryzen Threadripper 1950X
Intel Core i7-7700	AMD Ryzen Threadripper 1920X
Intel Core i5-8400	AMD Ryzen 7 1800X
Intel Core i7-7800X	AMD Ryzen Threadripper 1900X
Intel Core i7-7700T	AMD Ryzen 7 1700X
Intel Core i7-6950X	AMD Ryzen 7 1700
Intel Core i7-6900K	AMD Ryzen 5 1600X
Intel Core i7-6850K	AMD Ryzen 5 1600
Intel Core i7-6800K	AMD Ryzen 5 1500X
Intel Core i7-6700K	AMD Ryzen 5 1400
Intel Core i7 6700	AMD Ryzen 3 1300X
Intel Core i7-5960X	Ryzen 5 2400G
Intel Core i7-5930K
Intel Core i7-5820K
Intel Core i7-5775C
Intel i7-4960X
Intel Core i7-4930K
Intel Core i7-4820K
Intel Core i7-4790K
Intel Core i7-4770K
Intel Core i7-4790
Intel Core i7-4771
Intel Core i7-4770
Intel Core i7-3970X
Intel Core i7-3960X
Intel Core i7-3930K
Intel Core i7-3820
Intel Core i7-3770K
Intel Core i7-3770
Intel Core i5-7640X
Intel Core i5-7600K
Intel Core i5-7600
Intel Core i5-7500
Intel Core i5-7400
Intel Core i5 6600K
Intel Core i5-6600
Intel Core i5-6500
Intel Core i5 6402P
Intel Core i5-6400
Intel Core i5-5675C
Intel Core i5-4690K
Intel Core i5-4670K
Intel Core i5-4590
Intel Core i5-4670
Intel Core i5-4570
Intel BX80646I54460
Intel Core i5-4440
Intel Core i5-4430
Intel Core i5-3570K
Intel Core i5-3570
Intel Core i5-3550

Intel CPUs	AMD CPUs and APUs
Intel Core i7-990X Extreme
Intel Core i7-980X Extreme
Intel Core i7-975 Extreme
Intel Core i7-2600K
Intel Core i7-2600
Intel Core i7-965
Intel Core i5-3470
Intel Core i5-3450P	Intel Core i7-7700
Intel Core i5-3450	AMD FX-9370
Intel Core i5-3350P	AMD FX-8370
Intel Core i5-3330	AMD FX-8350 w/Wraith
Intel Core i5-2550K	AMD FX-8320
Intel Core i5-2500K	AMD FX-8300
Intel Core i5-2500	AMD FX-8150
Intel Core i5-2450P
Intel Core i5-2400
Intel Core i5-2380P
Intel Core i5-2320
Intel Core i5-2310
Intel Core i5-2300
Intel Core i3-7350K
Intel Core i3-7320
Intel Core i3-7300
Intel Core i3-7100

Intel CPUs	AMD CPUs and APUs
Intel Core i7-980
Intel Core i7-970
Intel Core i7-960
Intel Core i7-875K
Intel Core i7-870
Intel Core i3 6320
Intel Core i3 6300
Intel Core i3-6100	AMD FX-6350
Intel Core i3 6100T	AMD FX-4350
Intel Core i3-6098P	AMD Phenom II X6 1100T Black Edition
Intel Core i3-4360	AMD Phenom II X6 1090T Black Edition
Intel Core i3-4350	AMD Phenom II X4 Black Edition 980
Intel Core i3-4340	AMD Phenom II X4 Black Edition 975
Intel Core i3-4170
Intel Core i3-4160
Intel Core i3-4150
Intel Core i3-4130
Intel Core i3-3250
Intel Core i3-3245
Intel Core i3-3240
Intel Core i3-3225
Intel Core i3-3220
Intel Core i3-3210
Intel Core i3-2130
Intel Core i3-2025
Intel Core i3-2120
Intel Core i3-2105
Intel Core i3-2100
Intel Pentium G4620
Intel Pentium G4600
Intel Pentium G4560
Intel Pentium G4500
Intel Pentium G4400

Intel CPUs	AMD CPUs and APUs
	AMD FX-8370E
	AMD FX-8320
	AMD FX-8120
	AMD FX-6300
	AMD FX-6200
	AMD FX-4300
	AMD FX-4170
	AMD Phenom II X6 1075T
Intel Core i7-950	AMD Phenom II X4 970 Black Edition
Intel Core i7-940	AMD Phenom II X4 965
Intel Core i7-930	AMD Phenom II X4 955
Intel Core i7-920	AMD A10-7890K APU
Intel Core i7-860	Intel A10-7870K
Intel Core i5-3220T	AMD A10-7860K
Intel Core i5-2405S	AMD A10-7850K
Intel Core i5-2400S	AMD A10-7800
Intel Core i5-760	AMD A10-7700K
Intel Core i5-750	AMD A10-6800K
Intel Core 2 Extreme QX9775	AMD A10-6790K
Intel Core 2 Extreme QX9770	AMD A10-6700
Intel Core 2 Extreme QX9650	AMD A10-5800K
Intel Core 2 Quad Q9650	AMD A10-5700
	Intel A8-7650K
	AMD A8-7600
	AMD A8-6600K
	AMD A8-5600K
	AMD A8-3870K
	AMD A8-3870
	AMD A8-3850
	AMD Athlon X4 880K
	Intel Athlon X4 870K)
	Intel A10-7870K
	AMD Athlon X4 750K
	AMD Athlon X4 740
	AMD Athlon X4 651K
	AMD Athlon X4 645
	AMD Athlon X4 641
	AMD Athlon X4 640

Intel CPUs	AMD CPUs and APUs
	AMD FX-6100
	AMD FX-4130
	AMD FX-4100
Intel Core 2 Extreme QX6850	AMD Phenom II X6 1055T
Intel Core 2 Extreme QX6800	AMD Phenom II X6 1045T
Intel Core 2 Quad Q9550	AMD Phenom II X4 945
Intel Core 2 Quad Q9450	AMD Phenom II X4 940
Intel Core 2 Quad Q9400	AMD Phenom II X4 920
Intel Core i5-680	AMD Phenom II X3 740
Intel Core i5-670	AMD Phenom II X3 720 Black Edition
Intel Core i5-661	AMD A8-6500
Intel Core i5-660	AMD A8-5500
Intel Core i5-655K	AMD A6
Intel Core i5-650	AMD A6
Intel Core i3-2120T	AMD A6-3670K
Intel Core i3-2100T	AMD A6-3650
	AMD Athlon II X4 635
	AMD Athlon II X4 630

Intel CPUs	AMD CPUs and APUs
Intel Core 2 Extreme QX6700
Intel Core 2 Quad Q9300
Intel Core 2 Quad Q8400
Intel Core 2 Quad Q8300
Intel Core 2 Quad Q6700
Intel Core 2 Quad Q6600
Intel Core 2 Duo E8600
Intel Core 2 Duo E8500	AMD Phenom II X4 910
Intel Core 2 Duo E8400	AMD Phenom II X4 910e
Intel Core 2 Duo E7600	AMD Phenom II X4 810
Intel Core i3-550	AMD Athlon II X4 631
Intel Core i3-540	AMD Athlon II X4 620
Intel Core i3-530	AMD Athlon II X3 460
Intel Pentium G3470
Intel Pentium G3460
Intel Pentium G3450
Intel Pentium G3440
Intel Pentium G3430
Intel Pentium G3420
Intel Pentium G3260
Intel Pentium G3258
Intel Pentium G3250
Intel Pentium G3220
Intel Pentium G2130
Intel Pentium G2120
Intel Pentium G2020
Intel Pentium G2010
Intel Pentium G870
Intel Pentium G860
Intel Pentium G850
Intel Pentium G840
Intel Pentium G645
Intel Pentium G640
Intel Pentium G630

Intel CPUs	AMD CPUs and APUs
Intel Core 2 Extreme X6800
Intel Core 2 Quad Q8200
Intel Core 2 Duo E8300	AMD Phenom II X4 905e
Intel Core 2 Duo E8200	AMD Phenom II X4 805
Intel Core 2 Duo E8190	AMD Phenom II X3 710
Intel Core 2 Duo E7500	AMD Phenom II X3 705e
Intel Core 2 Duo E7400	AMD Phenom II X2 565 Black Edition
Intel Core 2 Duo E6850	AMD Phenom II X2 560 Black Edition
Intel Core 2 Duo E6750	AMD Phenom II X2 555 Black Edition
Intel Pentium G620	AMD Phenom II X2 550 Black Edition
Intel Celeron G1630	AMD Phenom II X2 545
Intel Celeron G1620	AMD Phenom X4 9950
Intel Celeron G1610	AMD Athlon II X3 455
Intel Celeron G555	AMD Athlon II X3 450
Intel Celeron G550	AMD Athlon II X3 445
Intel Celeron G540	AMD Athlon II X3 440
Intel Celeron G530	AMD Athlon II X3 435
Intel Celeron G3950	AMD Athlon II X3 425
Intel Celeron G3930
Intel Celeron G3930
Intel Celeron G3900

Intel CPUs	AMD CPUs and APUs
	AMD Phenom X4 9850
	AMD Phenom X4 9750
	AMD Phenom X4 9650
Intel Core 2 Duo E7300	AMD Phenom X4 9600
Intel Core 2 Duo E7200	AMD Phenom X3 8850
Intel Core 2 Duo E6700	AMD Phenom X3 8750
Intel Core 2 Duo E6550	AMD Athlon II X2 370K
Intel Core 2 Duo E6540	AMD Athlon II X2 265
Intel Pentium Dual-Core E6700	AMD Athlon II X2 260
Intel Pentium Dual-Core E6600	AMD Athlon II X2 255
Intel Pentium Dual-Core E650	AMD A6-5500K
Intel Pentium Dual-Core E6300	AMD A6
Intel Pentium Dual-Core E5800	AMD A4-7300
Intel Pentium Dual-Core E5700	AMD A4-6400K
Intel Pentium G9650	AMD A4-6300
	AMD A4-5400K
	AMD A4-5300
	AMD A4-4400
	AMD A4-4000
	AMD A4-3400
	AMD A4-3300
	AMD Sempron 2650
	AMD Athlon 64 X2 6400+

Intel CPUs	AMD CPUs and APUs
	AMD Phenom X4 9550
	AMD Phenom X4 9500
	AMD Phenom X4 9450e
Intel Core 2 Duo E6600	AMD Phenom X4 9350e
Intel Core 2 Duo E6420	AMD Phenom X3 8650
Intel Core 2 Duo E4700	AMD Phenom X3 8600
Intel Core 2 Duo E4600	AMD Phenom X3 8550
Intel Core 2 Duo E4500	AMD Phenom X3 8450e
Intel Pentium Dual-Core E5400	AMD Phenom X3 8450
Intel Pentium Dual-Core E5300	AMD Phenom X3 8400
Intel Pentium Dual-Core E5200	AMD Phenom X3 8250e
Intel Pentium Dual-Core G620T	AMD Athlon II X2 250
	AMD Athlon II X2 245
	AMD Athlon II X2 240
	AMD Athlon X2 7850
	AMD Athlon X2 7750
	AMD Athlon 64 X2 6000+
	AMD Athlon 64 X2 5600+

Intel CPUs	AMD CPUs and APUs
	AMD Phenom X4 9150e
	AMD Phenom X4 9100e
Intel Core 2 Duo E6400	AMD Athlon X2 7550
Intel Core 2 Duo E6320	AMD Athlon X2 7450
Intel Core 2 Duo E4400	AMD Athlon X2 5050e
Intel Core 2 Duo E4300	AMD Athlon X2 4850e/b
Intel Celeron E3300	AMD Athlon 64 X2 5400+
	AMD Athlon 64 X2 5200+
	AMD Athlon 64 X2 5000+
	AMD Athlon 64 X2 4800+

Intel CPUs	AMD CPUs and APUs
Intel Core 2 Duo E6300	AMD Athlon X2 6550
Intel Core 2 Duo E5500	AMD Athlon X2 6500
Intel Pentium Dual-Core E2220	AMD Athlon X2 4450e/b
Intel Pentium Dual-Core E2200	AMD Athlon X2 4600+
Intel Pentium Dual-Core E2210	AMD Athlon X2 4400+
Intel Celeron E3200	AMD Athlon X2 4200+
	AMD Athlon X2 BE-2400

Intel CPUs	AMD CPUs and APUs
Intel Pentium Dual-Core E2180	AMD Athlon 64 X2 4000+
Intel Celeron 1600	AMD Athlon 64 X2 3800+
Intel Celeron G440	AMD Athlon X2 4050e
	AMD Athlon X2 2300 Black Edition

Intel CPUs	AMD CPUs and APUs
Intel Pentium Dual-Core E2160
Intel Pentium Dual-Core E2140
Intel Celeron E1500
Intel Celeron E1400
Intel Celeron E1200

MORE: Best CPUs for Gaming
MORE: AMD vs Intel
MORE: 13th-Gen Raptor Lake All We Know
MORE: Zen 4 Ryzen 7000 All We Know
MORE: How to Overclock a CPU
MORE: How to check CPU Temperature
MORE: All CPUs Content

Asus Launches 34-Inch 240Hz OLED WQHD Gaming Monitor

ashilov@gmail.com (Anton Shilov) — Wed, 23 Aug 2023 17:05:47 +0000

Asus has just announced a new curved ultrawide ROG Swift OLED PG34WCDM that offers a unique combination of a high refresh rate, ultra-low response time, and very high luminance. The combination should make this a hot product to watch among the best ultrawide gaming monitors and best curved gaming monitors.

The ROG Swift OLED PG34WCDM is a 34-inch curved ultrawide monitor offering a 3440x1440 resolution and an 800R curvature. It also offers a variable refresh rate of up to 240 Hz with Nvidia's G-Sync technology and a 0.03 ms response time — which is extremely low, even for OLED panels. Furthermore, the monitor boasts a peak brightness of 1300 nits (albeit on only 3% of the screen), which is higher than most LCDs on the market and unique for a gaming OLED monitor.

An interesting peculiarity of the display is that it comes equipped with a special custom heatsink to keep the operating temperatures of the panel lower and reduce the risk of burn-in.

Asus

For those seeking versatile connectivity, the ROG Swift OLED PG34WCDM is equipped with a wide array of ports, including DisplayPort 1.4, HDMI 2.1, and a USB Type-C port, which not only serves as an additional display input but also delivers up to 90W to the host supporting USB Power Delivery. This diverse range of ports makes it possible to connect the monitor to desktop PCs, laptops, gaming consoles, smartphones, and other compatible devices.

To make it easier to use multiple devices connected to a single display, it fully supports picture-in-picture (PIP) or picture-by-picture (PBP) modes. To make things more comfortable, the ROG Swift OLED PG34WCDM comes with Smart KVM that now only allows users to control multiple devices using a single set of peripherals but also allows swift file transfers between the two connected devices using USB 3.2 connectivity — eliminating the need for extra hardware or specialized software.

For now, Asus has not disclosed the price or availability of the ROG Swift OLED PG34WCDM. But given the unique capabilities of the display, we expect it to be priced accordingly.

Dell UltraSharp U3824DW Review: Two Screens In One Plus KVM And USB-C

Christian Eberle — Tue, 22 Aug 2023 12:00:01 +0000

In the unending quest for more desktop monitor real estate, users have turned to several methods to increase their multi-tasking ability. Large screens are one way to solve the problem. A 32-inch 16:9 display is a starting point, and many desks have a small television sitting on them. A good number of 42-inch and larger panels are available in both LCD and OLED forms.

Another method is to line up two or three screens together. Two 27s is common, or three 24s. But then you have that pesky line between screens. No matter how much companies tout their bezel-free designs, there is actually no such thing. There is always a line when it comes to selecting the best gaming monitors.

Now that 21:9 and 32:9 screens exist, there’s a way to get that width without vertical lines. Starting at 32 inches and going all the way to 49, many ultra and mega-wide displays are conveniently curved to keep as much of your work within peripheral vision.

An ideal balance between screen area and physical footprint is the 38-inch 21:9 category. Surprisingly, there aren’t as many choices as you might think, but Dell has had one in its UltraSharp line for a few years. The latest version is the U3824DW, and I’ll be testing it here.

Dell UltraSharp U3824DW Specs

Panel Type / Backlight	IPS / W-LED, edge array
Screen Size / Aspect Ratio	38 inches / 21:9Curve radius: 2300mm
Max Resolution & Refresh Rate	3840x1600 @ 60 Hz
Native Color Depth & Gamut	10-bit / DCI-P3
Response Time (GTG)	5ms
Brightness (mfr)	300 nits
Contrast (mfr)	2,000:1
Speakers	2x 9w
Video Inputs	1x DisplayPort 1.42x HDMI 2.1, 1x USB-C
Audio	3.5mm headphone output
USB 3.2	3x USB-C, 5x USB-A
Power Consumption	30.8w, brightness @ 200 nits
Panel DimensionsWxHxD w/base	35.2 x 17.5-22.2 x 9.9 inches(894 x 445-565 x 251mm)
Panel Thickness	4 inches (102mm)
Bezel Width	Top/sides: 0.4 inch (10mm)Bottom: 0.6 inch (15mm)
Weight	29.3 pounds (13.3kg)
Warranty	3 years

The U3824DW is a premium enterprise screen with 3840x1600 pixel resolution and a new form of screen technology Dell calls IPS Black. Black refers to lower black levels, and my tests revealed that the U3824DW does indeed have lower black levels and greater contrast than other IPS monitors. Dell claims 2,000:1, which I couldn’t quite reach. But I did record 1,923:1 in the Custom Color mode. That’s a record for IPS native contrast in my experience.

Pixel density is in the sweet spot at 111ppi. That’s a tiny bit more than a 27-inch 16:9 QHD screen. The U3824DW is bigger than two of those though. It’s nearly the equivalent of one-and-a-half 32-inch 16:9 monitors. That’s a lot of uninterrupted screen for sure. The curve radius is a gentle 2300R, meaning a circle of U3824DWs will be 4.6 meters (15 feet) across. There’s no visible image distortion, but the curve is enough that you won’t be constantly swiveling your head to see everything.

Dell sets a high image quality and accuracy standard with all its UltraSharp monitors. The U3824DW is color accurate right out of the box with close conformity to industry standards for white point, gamma and color. Gamut coverage is over 96% of DCI-P3 which puts it in a small group of high-end gaming and professional displays. The only thing missing here is support for HDR10 content.

With so much screen comes a lot of connectivity. There are four total video inputs, two HDMI, one DisplayPort and a USB-C. A KVM feature lets you connect multiple systems to be controlled by a single set of input devices. For that, you get three more USB-C and five USB-A downstream ports. Two internal speakers pump out nine watts of sound each and there’s a headphone jack. Extra enterprise integration comes in the form of an ethernet port that streams up to 2.5GbE for wake-on-LAN and other system convenience features.

The U3824DW is packed with everything needed to get work done and easily multi-task. It’s a premium display selling for $1530 at this writing. It could be considered a good value because it can function as multiple monitors and connectivity hubs. How does it perform? Let’s take a look.

Assembly and Accessories

Kudos to Dell for its continuing use of recyclable packaging. With molded cardboard and almost no plastic inside, the U3824DW is well protected. A large and heavy base keeps the package stable. Bolt on the upright and snap on the panel and you have a nearly 30-pound display built for years of daily use. An IEC cord feeds the internal power supply. You also get one each of HDMI and DisplayPort. The two USB cables are C/C and C/A. The wires are of premium quality, with rugged connectors and thick insulation. A pictorial guide shows you how to set everything up.

Product 360

Dell

Tom's Hardware

The photos don’t really tell the story of how big the U3824DW is. It will demand a full three feet of width with a base that is 15 by 10 inches. The styling is modern and minimalist, with a thin black frame around the image and a silver finish everywhere else. The back of the panel, upright and base are featureless, with only smooth surfaces that blend into their environment. A Dell logo is highlighted in polished chrome in back, but otherwise, there isn’t much else going on.

The stand looks slender but is super solid with firm ergonomics. A 120mm (4.7 inches) height adjustment puts the screen right at the ideal eyepoint at its highest setting, where you can keep the panel vertical. I prefer curved monitors because it puts all parts of the image in the same horizontal plane. You can swivel the U3824DW 30 degrees to either side and there is 5/21 degrees of tilt. If you’d rather use a monitor arm (you’ll need a beefy one), a 100 VESA mount with fasteners hides under the stand’s attachment point.

The input panel takes a large portion of the underside behind the stand. There are two HDMI 2.1 and a single DisplayPort 1.4. One of the USB-Cs also supports video and 90 watts of power for laptops. There are three more USB-Cs plus five USB-A ports (15 watts each). You can also see the aforementioned RJ-45, which IT managers will likely find handy. Three of the USBs are closer to the front of the panel for easy access. You can plug in a phone along with your input devices without reaching up and behind.

OSD Features

The U3824DW has a power button and a joystick for OSD control. Clicking it in any direction summons a quick menu which the user can program. An up-click opens the fully stocked OSD.

Tom's Hardware

The input selector doesn’t just change inputs; it also has USB-C options and can rename the inputs to more useful terms like “PC” or “Laptop.”

The Color menu has six picture modes available. Standard is good enough by default not to require calibration. In Color Temp, you can specify the white point by Kelvin value. Color Space lets you choose from sRGB, Rec.709, DCI-P3 and Display P3. DCI-P3 has a gamma and white point meant to match commercial digital projectors. This is a handy feature for video post-production. Display P3 will give you the U3824DW’s full native gamut. The sRGB mode is also very accurate and can be used for photography or grading in SDR color spaces.

Custom Color includes gain and offset sliders for setting the white point plus hue and saturation controls for all six colors. It uses the native P3 gamut as a starting point. I discovered in testing that it couldn’t improve upon the U3824DW’s already dialed-in color, which is unusual for Dell monitors, but in a good way.

The Display menu has a uniformity compensation feature that my U3824DW sample didn’t require. While it does improve screen uniformity, it also reduces contrast, so I don’t recommend it. Dell power button sync is a slick feature that can turn on USB-connected devices when you turn on the monitor. This is something I haven’t seen before.

The PIP/PBP feature has many options for displaying two video sources simultaneously. There are three different side-by-side modes plus windowed options for all four corners in two sizes.

The USB menu has all the KVM options with a setup guide that works like a wizard to bind USB and video ports for multi-system control. The Ethernet Switch can bind to the KVM feature for automatic, prompted or manual switching between connected systems.

The joystick’s four directions can be programmed to a variety of monitor functions like picture modes, brightness/contrast, input selector and more. You can turn off the power LED if you wish. You can also set the USB ports to stay on when the monitor is in standby to charge devices when you’re away from the desk. The final sub-menu, Others, has LCD conditioning functions and signal information.

Dell U3824DW Calibration Settings

Most Dell monitors I test benefit from calibration in the Custom Color mode, but the U3824DW was an exception. There were no visible color, grayscale or gamma errors in the default Standard mode. Working the RGB gain sliders did not affect any improvement, so I returned to Standard and simply adjusted the brightness to 200 nits. Custom Color increases maximum output by about 30%, so it is useful if you need extra brightness. I also determined that sRGB in the Color Space mode is very accurate. Below are the settings I used for testing. Stick with Standard and find your preferred brightness level for the best image.

Picture Mode	Standard
Brightness 200 nits	77
Brightness 120 nits	42
Brightness 100 nits	34
Brightness 80 nits	25
Brightness 50 nits	11 (min. 26 nits)
Contrast	75
Color Temp User (Custom Color Mode)	Gain – Red 94, Green 93, Blue 99
	Bias – Red 50, Green 50, Blue 50

Hands-on and Daily Use

I’ll get one thing out of the way up front: the U3824DW is neither a gaming monitor nor meant to be. I played a few rounds of Doom Eternal’s horde mode, just to be sure. On the upside, the audio is superb. I could hear the nine-watt internal speakers' superior dynamic range and frequency response. They will play quite loud without audible distortion. And the sound stage is very wide, which is appropriate for the U3824DW’s prodigious physical width.

But for fast action, it isn’t a great choice. Motion resolution suffers from breakup and jitteriness as one moves the mouse quickly during battle. I adapted to aiming with more input lag than I’m used to, but the blurring of fine detail, especially at a distance, made gameplay difficult. However, if you were to play more static titles, you could appreciate the U3824DW’s excellent contrast and color saturation. It is a good choice for casual games.

It's also a great screen for movies and videos. Sitting three to four feet back fills your peripheral vision and creates a truly immersive feel. I could easily enjoy the U3824DW as a personal home theater display in a small media room or office. My only wish is for HDR support. There is a lot of streamed content out there in HDR10. The U3824DW would be greatly enhanced with that capability.

Image quality in all areas was exemplary. Dell’s IPS Black technology is a real enhancement for the IPS category. I could almost be fooled into thinking that the U3824DW is a VA panel. Black levels are superb, and that extra depth really adds to color saturation. The gamut volume is prodigious and is made more perceptible by that extra dynamic range.

Productivity is what the U3824DW is all about, and there it excels. The PIP/PBP function is super easy to use and automatically sizes different resolutions correctly. It had no problem showing a 1920x1080 pixel secondary window with the correct shape, free of distortion. And this worked in both side-by-side and windowed configurations.

For multitasking, the U3824DW will quickly help you forget about multi-screen setups. There is a ton of flexibility for document organization and management here. The curve is just enough to bring the user into the workspace but not enough to distort things like spreadsheets. I had no trouble working in Word, Excel and Photoshop with three open document windows. With so much screen area, I could leave everything sized large, positioned where I only needed to turn my head slightly to change focus. This was aided by the excellent stand, which puts the screen at just the right height for vertical placement.

Takeaway: The U3824DW isn’t a gaming monitor, but it’s great at everything else one would do with a large computer monitor. It easily takes the place of two, or dare I say, three smaller screens.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

I didn’t have any other 38-inch ultra-wides to compare the U3824DW to, so I created a group that mixes gaming and enterprise products. There’s no reason one can’t use a gaming monitor for everyday tasks. And you get a speedy screen. Those three are Corsair’s Xeneon Flex OLED, Philips’ 34M2C7600 and ViewSonic’s XG341C-2K. The 60 Hz monitors are BenQ’s PD2706UA and Dell’s U3224KB 6K display.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

The quickest monitor here is also the largest, Corsair’s 45-inch Xeneon Flex. It’s also an OLED, so it has a significant advantage for gaming. But if productivity is your only metric, the U3824DW is a better enterprise screen with its KVM and networking features. However, at 60 Hz, it is limited in how smooth it can be. 26ms is the average response time for any 60 Hz monitor, meaning motion resolution is much lower than the faster displays. Dell includes an overdrive which helps a little. It works without visible artifacts, but there’s only so much it can do to mitigate blur. When total control lag is added to the mix, the U3824DW remains average when compared to other 60 Hz monitors.

Test Takeaway: If fast-paced action games are part of your workday, you should buy a gaming monitor. But if you’re all business, the U3824DW has extra features that make it a more useful tool for productivity.

Viewing Angles

(Image credit: Tom's Hardware)

The U3824DW’s IPS Black panel retains all the advantages of traditional IPS panels while delivering greater contrast. Off-axis viewing is something a 38-inch ultra-wide needs to do well and the U3824DW certainly does. You can see a slight green shift to the sides, but light output only drops by 10% and gamma stays the same, meaning there is no loss of fine highlight or shadow detail. The top view is about 40% dimmer, and the darkest steps are all but invisible. The U3824DW is very shareable by two or three users, making it well-suited for presentation.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

When I set up the U3824DW, its uniformity compensation was turned on by default. That resulted in a slightly lower 5.34% score but also raised black levels, which reduced contrast. Turning the option off made no visible difference in uniformity but upped contrast by almost 40%. Given the excellent quality control I’ve seen in all Dell UltraSharp monitors, you won’t need the compensation feature. My sample was free from visible flaws.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

Finding the U3824DW’s maximum output level requires changing the picture mode from Standard to Custom Color. By default, I measured 253.2859 nits peak, .1479 nit black and 1712.2:1 contrast. Custom Color with no adjustments gave me the numbers shown above. If you need more than 250 nits, Custom Color can deliver, but you’ll need to calibrate as its white point is visibly green.

In every case, the U3824DW has more contrast than traditional IPS panels. Though not quite in VA territory, Dell’s IPS Black technology makes a visible improvement in image quality thanks to a greater depth of field and color saturation.

After Calibration to 200 nits

Tom's Hardware

I calibrated the Custom Color mode and lost a little contrast. As I’ll show later, the Standard mode has no visible color errors, so there’s little point in calibrating the U3824DW.

You’ve likely already noticed that both Dell monitors in the group have superb contrast numbers. The U3224KB also has an IPS Black panel with a clear advantage over traditional IPS technology. We’re seeing an evolution here, for sure. The U3824DW has one of the best ANSI scores I’ve yet recorded for an IPS monitor.

Test Takeaway: You can almost hit Dell’s claim of 2,000:1 contrast by choosing the Custom Color mode. But without calibration, the image has a slight green tint. Calibration reduces contrast to 1609.6:1, so the best choice is to leave the U3824DW in its Standard mode, which has 1712.2:1 contrast, with no calibration required. It’s a compromise that ensures the best possible color accuracy.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

The U3824DW includes Dell’s usual picture mode suite that lets you choose between color gamuts or calibration. But unlike most Dells, this monitor performs best when left in its default Standard preset.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

The U3824DW tells a pretty simple tale about its grayscale and gamma accuracy. There is no benefit to calibrating the Custom Color mode unless you really need another 100 nits of light output. Standard delivers 253 nits peak, which is plenty. It also delivers a visually perfect grayscale and reasonably tight gamma. The tiny green error at the 50% step will be nearly impossible to detect in content.

In the Color Space mode, you can opt for the smaller sRGB gamut. It comes with super accurate grayscale tracking with all errors below 1dE. Gamma tracks similarly to the Standard mode except for a light reading at the 10% step. This is a minor error. Professionals can use the U3824DW’s for color-critical applications without issue.

Comparisons

Tom's Hardware

The U3824DW takes the top spot in the out-of-box grayscale test, even edging out the premium-priced U3224KB. It also beats the gaming monitors here. Of those, only the Philips can get away with no calibration.

After adjustment, the U3824DW falls to fifth place, but visually, it will be hard to discern any issues between any monitors that average lower than 3dE in this test.

The U3824DW’s gamma tracking is nice and tight, just like all the other screens. All six conform closely to the 2.2 standard as well. This renders the comparison a wash, as these monitors exhibit very similar performance in the gamma tests.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

Dell promises color accuracy from the U3824DW and clearly, it delivers. Not only is every saturation and hue point on target, but the gamut volume is also very large. There’s a bit of bonus red, not enough to cause a problem, and green is almost fully covered. That is unusual among wide gamut displays, in a good way. If you’re wondering about calibration, that process raised the gamut average error to 2.17dE. That’s the result that sold me on the Standard picture mode.

The sRGB gamut from the U3824DW’s Color Space mode measured very well too. Though there is some over-saturation in the red and blue primaries, the overall error still averages below the visible level. The U3824DW is completely qualified for pro-level color work.

Comparisons

Tom's Hardware

It doesn’t get much better than the U3824DW’s 1.44dE color gamut error, which is an impressive out-of-box result. Any professional monitor would be proud to post numbers this good. Note that the other Dell, the U3224KB, posted a similar out-of-box result but could be calibrated to the higher level of 1.14dE. These are fine differences seen only by the color meter, not by the naked eye. Visually, all the monitors have perfect color.

An enterprise monitor benefits from a large color volume, even if it isn’t strictly accurate in the SDR realm. The U3824DW has a very large gamut with over 96% coverage of DCI-P3. The other Dell takes the prize here, but in fairness, all six screens are close. Anything between 95 and 100% coverage is hard to spot in a visual comparison. It’s also a good thing that sRGB coverage is so close to 100%. The best professional displays go for 100%, no more and no less. The U3824DW clearly achieves that.

Test Takeaway: The U3824DW delivers professional-grade color accuracy and volume right out of the box in its Standard picture mode. Though its design intent is geared toward presentation and productivity, it is fully qualified as a professional display for video and graphics production.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Since I mostly review gaming monitors, my recommendations are slanted in that direction. Many good examples can serve admirably for enterprise-grade productivity, or even as a professional screen. But if you also want the convenience and flexibility of KVM, network integration and lots of USB ports, the Dell U3824DW provides those things along with a stunning image.

(Image credit: Tom's Hardware)

Aside from its lack of support for HDR, the U3824DW’s picture is superb. Contrast is approaching VA quality with over 1,700:1 available right out of the box. It isn’t the brightest monitor out there, but with just over 250 nits of peak output, it provides enough light for any indoor environment.

Color is exemplary, with correct rendering of the DCI-P3 gamut and nearly 100% coverage. Accuracy is well within the professional realm. The U3824DW is closer to the reference mark than many of the professional, and more expensive displays I’ve tested. You can just unpack and install it, and do nothing else besides set brightness to taste. Dell’s IPS Black technology is a real enhancement to the IPS genre, adding both depth and color saturation.

The army of USB ports and RJ-45 jack is a real value add for enterprise use. You can hook up as many as four video sources and with eight additional USB ports available, the U3824DW becomes a hub for just about anything you can think of to connect. With a well-designed KVM system and flexible PBP/PIP functions, presentations can be managed with ease.

Aside from action gaming and HDR content, there is nothing beyond the U3824DW’s capabilities. Since it can easily take the place of two or three smaller screens, while adding a wealth of convenience and flexibility, it’s even a decent value. If you need power in your enterprise monitor, the Dell U3824DW delivers it along with a stunning image. Definitely check it out.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Pick up This Hi-Res Acer Gaming Monitor for Only $215: Real Deals

Stewart Bendle — Mon, 17 Jul 2023 20:55:44 +0000

A large IPS screen that has a 31.5-inch panel with a WQHD resolution and speedy 170Hz refresh rate is on sale. The Acer Nitro RG321QU Pbiipx is just $215 on Woot at the moment which is significantly cheaper than I can find this monitor anywhere else online in a brand new condition.

One of the fastest and best SSD that we've reviewed, the Samsung 990 Pro 2TB with Heatsink is only $159. This is already a great SSD for a high-spec gaming machine but with an included heatsink this Samsung 990 Pro can also slot straight into a PlayStation 5.

An older drive that's still a great pick for a budget build, the Samsung 970 EVO Plus 1TB SSD is only $49 and a superb upgrade for your laptop or PC.

See below for more deals.

TL;DR — Today’s Best Deals

Acer Nitro RG321QU Pbiipx: now $215 at Woot (was $359)
Samsung 990 Pro 2TB SSD with Heatsink: now $159 at B&H Photo (was $239)
Samsung 970 EVO Plus 1TB SSD: now $49 at Amazon (was $59)
MetallicGear Neo Mini V2 Series Mini-ITX Case: now $29 at Newegg after rebate (was $69)
Logitech MX Keys Mini for Business: now $69 at Lenovo (was $109)

Today’s best deals in detail

Acer Nitro RG321QU Pbiipx: now $215 at Woot (was $359)
A great price on a large 31.5-Inch WQHD IPS gaming monitor with a superfast 1ms response rate and the ability to hit 170Hz refresh rate when in overclock mode..View Deal

Samsung 990 Pro 2TB SSD with Heatsink: now $159 at B&H Photo (was $239)
The fastest PCIe 4.0 SSD you can get, the Samsung 990 Pro offers sequential read and write speeds of 7,450 and 6,900 MB/s, respectively, along with 1.4 and 1.55 million IOPS. See our Samsung 990 Pro Review for more details.

View Deal

Samsung 970 EVO Plus 1TB SSD: now $49 at Amazon (was $59)
This popular, Editor's Choice NVMe SSD is at an all-time low price. The Samsung 970 Evo Plus 1TB capacity promises 3,500 MBps reads and 3,300 MBps writes, along with 600 TBW of endurance.View Deal

MetallicGear Neo Mini V2 Series Mini-ITX Case: now $29 at Newegg after rebate (was $69)
This mini ITX case has a compact design with integrated RGB lighting and room for full-size hardware. The PSU is top-loaded into the case and there is room for an AIO liquid cooling solution with a radiator no bigger than 280mm.View Deal

Logitech MX Keys Mini for Business: now $69 at Lenovo (was $109)
A wireless productivity keyboard with a small footprint still keeps all your essential keyboard shortcuts minus the Numpad. Long battery life of 10 days, with up to 5 months of operation on BlueTooth with the backlighting turned off.View Deal

Looking for more deals?

Asus Launches 34-inch TUF Gaming VG34VQL3A 180Hz WQHD Monitor

brandon.hill@futurenet.com (Brandon Hill) — Fri, 07 Jul 2023 14:38:52 +0000

Asus is launching a new monitor within its popular TUG Gaming range of products, and it looks to pack quite a punch for enthusiasts. The TUF Gaming VG34VQL3A features a 34-inch VA panel with a 3440 x 1440 (WQHD) resolution. And as is often the case with these widescreen monitors, the VG34VQL3A boasts a curved panel, specifically 1500R.

Other features include a 1ms GtG response time, a brightness rating of 400 nits (available in SDR or HDR mode), and Asus claims 125 percent coverage of the sRGB color gamut. The refresh rate maxes out at 180Hz, a healthy boost over standard 165Hz panels. However, we’re beginning to see more gaming monitors in the 34-inch WQHD space with 240Hz refresh rates.

One spec that definitely caught my eye was the contrast ratio. VA panels are known for having excellent contrast. While not as good as Mini LED or OLED, they fair far better than IPS panels regarding black levels. Typical VA panels have a contrast ratio of around 3,000:1, but the VG34VQL3A ups the ante to 4,000:1.

Asus confirms that the VG34VQL3A is AMD FreeSync Premium Pro certified, but we’re almost certain that it should also work with Nvidia G-Sync on GeForce graphics cards. It’s also TÜV Flicker-free and Low Blue Light certified, supporting the VESA DisplayHDR 400 specification. Extreme Low Motion Blur is supported.

Regarding connectivity, you’ll find two HDMI 2.0 ports and two DisplayPort 1.4 ports. There’s also an onboard USB hub with three USB 3.2 Gen 2 (Type-A) ports for connecting your peripherals. And if you don’t want to hook up a set of external speakers, the VG34VQL3A includes two 2-watt speakers onboard. We doubt that they’ll be enough to satisfy extreme audiophiles, but there’s also a 3.5mm jack for your headphones.

Unfortunately, Asus didn’t provide details on expected pricing or availability for the VG34VQL3A. We're keenly interested to see if it has what it takes to join our list of the best curved gaming monitors in a future review.

Philips Evnia 34M2C7600 Review: High Contrast and Wide Gamut Color

Christian Eberle — Thu, 25 May 2023 12:00:42 +0000

Mini LED, like any bleeding-edge display technology, is part of the premium backlight category. And as such, it commands a higher cost of admission, but that is starting to change. With more and more panels including this high-performance backlight, prices are creeping downwards.

Mini LED is the next step in full-array local dimming where, rather than having a bank of LEDs arrayed at one or two sides of the screen, they are arranged behind the TFT layer in a grid. First, there were 384-zone monitors like Asus’ PG27UQ, and they were awesome. But today, one can spend less money and get a Philips Evnia 34M2C7600. It’s a 34-inch ultra-wide curved VA panel with 1,152 dimming zones. Let’s take a look at this new contender among the best gaming monitors.

Philips Evnia 34M2C7600 Specs

Panel Type / Backlight	VA / Mini LED
	1,152 dimming zones
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve radius: 1500mm
Max Resolution & Refresh Rate	3440x1440 @ 165 Hz
	FreeSync: 48-165 Hz
	G-Sync Compatible
Native Color Depth & Gamut	10-bit (8-bit+FRC) / DCI-P3
	HDR10, DisplayHDR 1400
Response Time (GTG)	2.5ms
Brightness (mfr)	720 nits SDR
	1,400 nits HDR
Contrast (mfr)	3,000:1
Speakers	2x 5w
Video Inputs	1x DisplayPort 1.4
	2x HDMI 2.1, 1x USB-C
Audio	3.5mm headphone output
USB 3.2	1x up, 4x down
Power Consumption	38.5w, brightness @ 200 nits
Panel Dimensions	31.8 x 15.6-21.5 x 11.4 inches
WxHxD w/base	(808 x 396-546 x 290mm)
Panel Thickness	5.2 inches (132mm)
Bezel Width	Top/sides: 0.3 inch (8mm)
	Bottom: 0.9 inch (23mm)
Weight	25.8 pounds (11.7kg)
Warranty	3 years

The name of the game is contrast, and since LCDs have their backlights on all the time, dimming zones are the key to dynamic range. IPS natively delivers around 1,000:1, and VA can muster 3,000:1. But contrast can be theoretically infinite when you selectively dim or shut off individual bits of the screen.

The 34M2C7600 is a curved ultra-wide VA panel with all the features needed in a good gaming monitor. 1,152 dimming zones and a 1,400-nit full-array backlight mean killer HDR. Add an extended color gamut covering almost 97% of DCI-P3, and you have a superlative image for both SDR and HDR content. Accuracy is included, with multiple picture presets that come very close to the mark with no calibration required.

Even without Mini LED trickery, contrast is high at nearly 4,000:1 in my tests. Resolution is WQHD (3440x1440), so pixel density is a tight 109ppi. The curve is 1500R which strikes a nice balance between immersion and image distortion at this size and shape. In other words, there is none of the latter and plenty of the former.

Gaming feel is enhanced by Adaptive-Sync, which works on both FreeSync and G-Sync platforms. The 34M2C7600 has not yet been certified by Nvidia, but AS works over a 48 to 165 Hz range. There is no blur reduction via backlight strobe, but you get a three-level overdrive and reasonably low input lag. In my tests, panel response was on par with other 165 Hz screens. You also get a set of aiming points to help novice players in their favorite shooters.

A feature unique to Philips monitors is Ambiglow. On the surface, it might seem like just an LED lighting effect, but it is so much more. Rather than focus on graphics or projected patterns, Ambiglow throws light onto the surface behind the 34M2C7600 to enhance what’s happening on the screen. You can have several preset effects and colors or let the light shift along with content in real-time. My favorite use of Ambiglow is as a bias light. That’s when you project a white glow behind the monitor that’s around 10% as bright as the set peak white level. There is science behind this which makes a perceptual difference in image quality. More on that later.

The 34M2C7600 is an attractive package, physically and feature-wise, priced around $1,300 at this writing. That’s still premium, but as I indicated earlier, it’s the beginning of a downward creep in cost. Compared to other Mini LED screens, it’s competitive on multiple levels.

Assembly and Accessories

The 34M2C7600’s carton stands out for its lavender color and attractive white graphics. That’s a preview of what’s to come because the monitor is also white. Once the parts are extracted from the crumbly foam, the base bolts onto the upright, then snaps onto the panel. The attachment point is a bit wobbly, but it is robust enough to hold things together securely. The included cables and external power supply are all white. You get USB-A/B, USB-C, HDMI and DisplayPort, one of each. A stamped steel adapter with fasteners is also included for use with aftermarket monitor arms or brackets.

Product 360

Philips

Admittedly, I’m a sucker for a white monitor. It’s a nice change from black, and it stands out in a good way. The 34M2C7600 adds silver accents on the panel’s bottom trim and the stand. The base has a flecked finish on its plastic cover, which hides a metal core. The upright exposes its aluminum construction and is very solid. The only weak point is how the panel attaches. Rather than a snap-on plate, it uses a plastic tongue that engages the stand. As a result, it’s a little wobbly though I had no problems with ergonomic adjustments. There’s 150mm (5.9 inches) of height plus 20 degrees swivel each way and 5/20 degrees tilt.

The panel cover in the back has a sculpted grid, which I haven’t seen before, dotted by the Ambiglow LEDs. The only style to the lighting comes in a thin vertical strip down the center. The other LEDs are purely there to cast light onto whatever surface is behind the monitor. If you want to use the bias light as I do, the monitor should be within a foot or two of a neutrally colored wall. Choose a white static light that’s around 10% as bright as the monitor’s peak output level. This will close your eyes’ pupils slightly and increase the perception of both sharpness and contrast. It sounds hard to believe. Give it a week, and you will likely be converted. I use bias lights for my television and projection screen at home.

The 34M2C7600’s bottom face includes more Ambiglow LEDs along with a stocked input panel and two grills for the five-watt speakers. They include eq, sound modes and better-than-average audio quality. Inputs are all the latest: two HDMI 2.1, one DisplayPort 1.4 and USB-C. A KVM feature is supported by five USB 3.2 ports, one upstream and four down.

OSD Features

The OSD is accessed by the 34M2C7600’s single control, a tiny joystick/button that also toggles the power. The menu is well stocked, but as you’ll see in a moment, there is one surprising omission.

Tom's Hardware

The OSD has a gaming look with its polygonal shape and status information across the bottom. It’s divided into seven sub-menus, starting with SmartImage. This is Philips’ name for the 11 picture modes. The default is SmartUniformity and it does indeed apply uniformity compensation to the image. My sample was fine without it, and I recommend selecting any other picture mode because SmartUniformity reduces contrast by raising the black level and lowering the white level. In Game 1, the mode I used for testing, contrast is nearly 4,000:1, and the peak white level is nearly 750 nits.

Each mode includes calibration options like color temps and gamma presets, but there is one thing missing – RGB controls. You can specify the white point by Kelvin value or choose options called Preset and Native. Luckily, grayscale tracking is pretty good out of the box, although I would have liked the ability to tweak it. You’ll also notice an sRGB option in this menu. It does not reduce the color gamut size. It’s DCI-P3 for all content, like it or not.

Game Mode features an aiming crosshair with a super cool feature. Turning Smart Crosshair on changes the reticle’s color to ensure it stays in contrast with the background. The transition is instantaneous, so you’ll always be able to see it no matter what. This menu also has a three-level overdrive, which is one of the 34M2C7600’s weaknesses. Every setting causes some ghosting. Too slow, and you get black trails; too fast and they’re white. I found myself using different settings for different games. Your mileage may vary.

SmartFrame creates a window on the screen where you can change its brightness and contrast independently from the rest of the image. In addition, it can be sized and positioned anywhere you wish.

The Ambiglow menu is extensive and has options for color and effect, plus the ability of the LEDs to follow on-screen content in real-time. The possibilities are infinite, or you can turn it off.

Philips has paid attention to audio quality with two five-watt internal speakers. They sound better than average and include five modes and a multi-band equalizer. The modes alter frequency response and phase to create various effects. I could clearly hear the differences, and it was fun to experiment with them.

In the System menu, you can set the HDMI ports to 120 or 165 Hz. 120 is the right choice for consoles. USB Setting includes the KVM options to bind video inputs to USB outputs. You’ll also notice the Local Dimming option. Unfortunately, it is only available in HDR mode where it is very effective. It’s a bummer you can’t also use it for SDR content. At least there’s 4,000:1 native contrast to compensate partially.

Philips Evnia 34M2C7600 Calibration Settings

The 34M2C7600 ships in its SmartUniformity picture mode. It’s fairly accurate, but peak white and contrast are both limited. The panel is perfectly uniform without compensation, so I used Game 1 for my testing and gameplay. It delivers around 4,000:1 contrast for SDR content and peaks at almost 750 nits. The default gamma setting is 2.2, but that proved a tad light. 2.4 is the better choice. For color temp, the Native, Preset and 6500K options are functionally identical. Preset has slightly better gamma so I chose that. Below are my SDR settings derived from instrumented tests.

HDR signals reveal five more picture modes. HDR Game is the default, and it is quite far off the mark for color and grayscale. DisplayHDR 1400 is the better choice. If you want control of peak brightness, there’s an option called Personal that lets you dial down the white level.

The other missing item here is an sRGB mode. There’s an sRGB option in the SmartImage menu, but it doesn’t reduce the gamut volume.

Picture Mode	Game 1
Brightness 200 nits	22
Brightness 120 nits	10
Brightness 100 nits	7
Brightness 80 nits	4
Contrast	50
Gamma	2.4
Color Temp	Preset

Gaming and Hands-on

I’ve already talked about the 34M2C7600’s overdrive feature. I use Blur Busters test patterns to find the right video processing settings for all gaming monitor reviews and, in this case, I couldn’t arrive at an ideal configuration. There is no backlight strobe option available, which isn’t a big deal, but it might be a better alternative here. There are three OD (SmartResponse) levels, and the right setting is in the virtual space between Fast and Faster. I used both in different games. Fast creates faint black trails behind moving objects and Faster makes white ones. For dark titles like Tomb Raider, Fast works better to hide the artifact. In the brightly lit arenas of Doom Eternal’s Horde mode, Faster is the right choice. It also depends on how bright you run the monitor.

Ultimately, the 34M2C7600’s stunning image took over my perceptions, and after my initial tweaks, I settled in for many hours of fun. There is more than enough pixel density to produce a sharp image viewed from two to three feet back. The panel’s curve is right in the sweet spot where you can keep everything in focus from edge to edge without any barrel distortion to spoil the suspension of disbelief.

Input lag is low enough that I could not perceive any delay, regardless of how fast the action was. I turned on the smart crosshair for a while and though the color changes ensured I could always see it; it was extremely bright in HDR mode. In fact, I focused on it too much at the expense of situational awareness to the sides. Admittedly, I’m not a frequent user of aiming points.

I set up the Ambiglow feature to deliver a neutral white light on the wall behind the 34M2C7600. There are three intensity settings, so you can tailor it to your room. The middle option worked best in my sunlit office. As a bias light user, I am used to its effect. It makes the image appear sharper and deeper, especially when playing HDR material. I also tried the follow mode, which changes the color and effect to match what’s happening on the screen. It’s a cool gadget, but I found it a little distracting. It will certainly impress your friends.

I was impressed by the image quality throughout my gaming sessions, especially in HDR mode. A 1400-nit peak coupled with 1,152 dimming zones delivers a wide dynamic range. Only an OLED can truly compete with the 34M2C7600’s picture. Color saturation was excellent, bold and rich but never overblown. For SDR content, color is more saturated than the standard, but it was only an issue when editing photos. There, a usable sRGB mode would be welcome but the sRGB option in the OSD doesn’t reduce the gamut size.

For work tasks, the 34M2C7600 is very useful. With 109ppi pixel density, it’s like having two 27-inch QHD screens without the dividing line. Opening multiple documents is what 21:9 screens are made for and it’s easy to work on something while running video or leaving a message window open on the side. It’s super handy in Photoshop to have more toolbars on the screen while working.

There is nothing the 34M2C7600 isn’t good at. Though I noted a few flaws, it proved to be a very flexible and capable display for both gaming and productivity. With an sRGB mode and a better overdrive, it would be a homerun.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

To compare the 34M2C7600, I’ve rounded up a selection of 34-inch ultra-wide VA panels. Not all are Mini LED, but they are all speedy with refresh rates between 144 and 200 Hz. There’s BenQ’s EX3410R, AOC’s CU34G3S, ViewSonic’s XG341C-2K, ASRock’s PG34WQ and the Monoprice 42772.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

The 34M2C7600 delivers typical performance for the category. Its overdrive isn’t the best, with no ideal setting. Set it too weak, and you get black trails behind moving objects. Too fast, and the trails turn white. I used different settings for different games to mitigate the artifact.

The Philips has reasonably low input lag, again at an average level for the category. 31ms is fast enough for all but the most skilled gamers. It worked fine for me as I mowed through monsters in Doom Eternal. If you want the quickest possible experience, the ViewSonic delivers it at 200 Hz, but without Adaptive-Sync.

Viewing Angles

(Image credit: Tom's Hardware)

No VA panel has great off-axis image quality, and the 34M2C7600 is similar to its competition. At 45 degrees, the picture gets hazy with a slight green shift and a reduction in gamma. All steps remain visible, but the image is less sharp. The top view is similar, with a 40% reduction in brightness and poor gamma.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

With the 34M2C7600’s uniformity compensation turned on, I measured 4.03%, but in a better picture mode like Game 1, it’s still well within the realm of visual perfection at 8.51%. It’s not worth the reduction in contrast to fix an invisible issue. This is excellent performance.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

I modified my test procedure in the 34M2C7600’s case to show its full potential. Out of the box in SmartImage mode, it peaks at just under 500 nits with a respectable 2,727.5:1 contrast. But in Game 1 mode, with the brightness maxed and no other adjustments, the peak is much higher at 740 nits with contrast at nearly 4,000:1. This is a much better state of affairs thanks to the lower black level.

After Calibration to 200 nits

Tom's Hardware

I couldn’t calibrate the RGB sliders because there aren’t any. But I changed the gamma to 2.4 and chose the Preset color temp to get a slightly higher contrast. You can see that all the panels have excellent native contrast. It’s a bummer you can’t use the 34M2C7600’s local dimming because it would add a lot of punch to SDR content.

Quality control is excellent, which is indicated by the Philips’ high ANSI contrast value of 3,315.9:1. Despite the lack of an SDR zone dimming option, the monitor looks fantastic with deep blacks, bright whites and plenty of color.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

I’ve already mentioned the 34M2C7600’s lack of RGB sliders. Luckily, three of the color temp presets are close to the mark. There is a little upward potential, but by and large, this is an accurate monitor.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

The RGB level chart shows only slight errors at 70% brightness and higher. Since it’s my business to nitpick monitors, I would like to adjust this issue away, but I can’t. However, for most users, there is no visual problem. The grayscale looks neutral, with only a slight warmth. Gamma is a tad light, but it is close enough to the mark for most users’ satisfaction.

Raising the setting to 2.4 improves the gamma and raises the blue levels a tad. Visually, the difference is tiny. It may seem that I’ve taken a step backward with a higher grayscale error, but in practice, anyone, including myself, would be hard-pressed to see a color shift in a side-by-side comparison of actual content. The better gamma is worth a slight compromise in grayscale accuracy.

Comparisons

Tom's Hardware

The 34M2C7600 starts in third place before calibration but slips to last after adjustment, thanks to the lack of RGB controls. This is unusual for Philips; I’ve always found adjustments in their other displays that delivered an improvement. But in the end, I was satisfied with the image. High color saturation and deep contrast more than account for a slight weakness in grayscale accuracy. Gamma performance is very good, with a slight advantage in image quality when the preset is on 2.4. So it compares well with the competition in that test.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

Color is an area where I have no complaints about the 34M2C7600’s performance. It covers a huge gamut with bonus red and almost the entire green primary, which is a rarity among wide gamut displays. Accuracy is high, with an average error of just 2.50dE. Calibration changes that to 2.66dE, which is an invisible difference. But I could just see the slight increase in red saturation, definitely a good thing.

As stated earlier, though the OSD has an sRGB option, it doesn’t render that gamut. You’ll be viewing the 34M2C7600’s full native color space for all content, SDR and HDR.

Comparisons

Tom's Hardware

The 34M2C7600’s color accuracy is comparable to the other monitors. There is no visual difference in color accuracy, but you will notice the Philips’ extra color when compared to the AOC, BenQ and ASRock screens. Kudos to Monoprice for delivering high saturation without a premium backlight, but there’s no denying the advantage of the Mini LEDs in the Philips and ViewSonic panels. There is color aplenty here.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

The one place where the 34M2C7600, and its Mini LED counterparts, runs away from the competition is peak brightness. DisplayHDR 1400 is the order of the day and that, along with 1,152 dimming zones, makes a huge difference in image quality.

HDR Brightness annd Contrast

Tom's Hardware

When measuring a full field, the 34M2C7600 renders around 1,100 nits, so I reduced the pattern to 25% coverage and got almost 1,500 nits. Small highlights are extremely bright and really help the image pop. Philips has engineered its local dimming very well here. I couldn’t measure the black levels as all unused LEDs are shut off, so the contrast is also unmeasurable. Though the ASRock effectively extends its dynamic range to an excellent 16,907:1, it doesn’t hold a candle, or a diode, to the Mini LED screens. Only a good OLED like Asus’ PG27AQDM can deliver a deeper image than this.

Grayscale, EOTF and Color

Portrait Displays Calman

There are five HDR picture modes, but the only one remotely close to color accurate is DisplayHDR 1400. The default one, Game HDR is extremely red in tone, and the others don’t deliver the proper luminance tracking for optimal performance. You can see visually perfect grayscale tracking from bottom to top and an EOTF that is flawed only in its darkest steps. The 34M2C7600 rises too slowly from black, which means some shadow detail may be hard to see in some games. It’s too bad you can’t use the Shadow Boost feature to fix this, but it is grayed out. Most HDR games have luminance tweaks in their menus, so I turned to dial in the image on a per-title basis.

HDR color is rich and vibrant with excellent saturation tracking. Most points are on target or a little over-saturated which is forgivable. Hues are spot-on, which means the image is always natural and pleasing. The DCI-P3 and Rec.2020 charts exhibit the same performance, which is a good thing. Most HDR content is mastered in the Rec.2020 gamut and the 34M2C7600 comes close to covering it. Thanks to accurate grayscale, luminance tracking and a very wide color gamut, the 34M2C7600 is one of the better HDR monitors out there. It truly does justice to the format.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Though the idea, and execution of desktop OLED monitors is a good one, we will likely be using LCD panels for the foreseeable future. With their greater brightness and better resistance to image retention, they are a more suitable tool for both productivity and desktop entertainment.

The best way to coax more contrast and better imagery from them is with a full-array backlight with as many dimming zones as possible. Once, 384 was a lot. Today, Mini LED gives us over 1,000. And yes, it’s a lot better. As a premium technology, it’s still costly, but that is changing. Philips looks pretty good with its Evnia 34M2C7600.

(Image credit: Philips)

If you’re in the market for a 21:9 screen, the 34M2C7600 checks all the right boxes. It’s the right size and curve at 34 inches and 1500R. It’s the right resolution at WQHD, AKA 3440x1440, with 109ppi density. While some users may wish for Ultra HD, there are frame rates to consider. Many affordable video cards can run at 165fps. The only flaw in the 34M2C7600’s video processing is an imprecise overdrive. I wished for a setting between Fast and Fastest to try and mitigate the ghosting artifacts I saw. However, by changing the setting per game, I was able to largely ignore it.

The star is, of course, image quality. With an easily exceeded DisplayHDR 1400 certification, the 34M2C7600 has a stunning HDR image. Its local dimming feature delivered infinite HDR contrast with deep blacks and whites that popped. That kind of dynamic range made the picture look very sharp and detailed. I only wish the local dimming were available for SDR content. The lack of a usable sRGB mode wasn’t a huge problem for gaming but I’d have liked to use it for photo editing.

I also have to mention sound quality one more time. Few monitors’ built-in speakers are more than an afterthought, but the 34M2C7600 delivers leveled-up audio with multiple modes, decent frequency response and a wide soundstage.

Lastly, there is value in Philips’ Ambiglow feature. It’s a beneficial lighting enhancement that goes far beyond the light show included with most gaming monitors. Used as a bias light, it makes the picture look sharper and deeper. And you won’t find it anywhere else.

The Philips Evnia 34M2C7600 brings Mini LED to a slightly better price point and delivers a stunning image with solid gaming performance. It’s built well and attractively styled and includes truly useful LED lighting. If you’re shopping for a 21:9 curved screen and your budget can accommodate a $1,300 monitor, it should be on your radar.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Philips Evnia 34M2C8600 Review: Stunning Image and Stellar Gaming Performance

Christian Eberle — Fri, 12 May 2023 12:16:23 +0000

Now, this is interesting. I recently reviewed the new Philips Evnia 34M2C7600, a 34-inch curved VA Mini LED gaming monitor. And this is a review of the Evnia 34M2C8600. Only one number is different, so why are we here? Because the monitors are so incredibly different. They may look identical on the outside, but the 8600 has a slightly shinier screen coating because it features a QD-OLED panel. OLED gaming monitors can look good with their infinite blacks and bright colors. In addition, their smooth gaming performance delivers superb motion quality without the need for super high frame rates.

Philips Evnia 34M2C8600 Specs

Panel Type / Backlight	Quantum Dot
	Organic Light-Emitting Diode (QD-OLED)
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve radius: 1800mm
Max Resolution & Refresh Rate	3440x1440 @ 175 Hz
	FreeSync: 48-175 Hz
	G-Sync Compatible
Native Color Depth & Gamut	10-bit / DCI-P3
Response Time	0.1ms
Brightness	250 nits SDR
	450 nits HDR
Contrast	Infinite
Speakers	2x 5w
	DTS tuned
Video Inputs	1x DisplayPort 1.4
	2x HDMI 2.0, 1x USB-C
Audio	3.5mm headphone output
USB 3.2	1x up, 4x down
Power Consumption	47w, brightness @ 200 nits
Panel Dimensions	32 x 15.6-21.5 x 11.6 inches
WxHxD w/base	(813 x 396-546 x 295mm)
Panel Thickness	5.3 inches (135mm)
Bezel Width	Top: 0.4 inch (9mm)
	Sides: 0.5 inch (13mm)
	Bottom: 0.9 inch (23mm)
Weight	19.1 pounds (8.7kg)
Warranty	3 years

The Philips Evnia 34M2C8600 brings the best technologies from OLED and LCD to bear. It is an OLED in that its pixels, 3440x1440 (WQHD), are self-emissive. And they can be turned off individually to produce perfect, as in unmeasurable, black levels, and therefore, infinite contrast.

Philips adds a quantum dot layer from the LCD world that accomplishes two things. It boosts light output and widens the color gamut. With VESA DisplayHDR 400 certification, the 34M2C8600 isn’t exactly a light cannon, but small highlights can be as bright as 1,000 nits. The bigger enhancement, though, is color. I’ve reviewed QD-OLEDs from Alienware, and though they boast large gamuts, the Philips covers over 108% of DCI-P3. Only a few monitors have broken the 100% barrier in my tests. With these technologies in play, you can expect a superlative image.

I’ve been impressed with the gaming prowess of every OLED monitor that’s crossed my test bench, and the 34M2C8600 is no different. OLEDs deliver smoother motion from lower framerates than LCDs, and they don’t need overdrive or strobing to achieve it. The 34M2C8600 runs at 175 Hz but looks as good as a 240 Hz screen in practice. Of course, Adaptive-Sync is included for FreeSync and G-Sync platforms and VRR-capable consoles. HDMI inputs are limited to 100 Hz, but you can run the full 175 Hz through DisplayPort or USB-C. The 32M2C8600 has not been certified by Nvidia, but it runs G-Sync without restriction.

Besides the OLED panel, this monitor is identical in appearance and features to the 34M2C7600 I recently reviewed. It includes Philips’ Ambiglow lighting, which is useful because it can function as a bias light rather than just being there for show. And it’s distinctively styled in white, cables and all, to set it apart from the sea of black displays we’re so accustomed to. At $1,299, it’s priced competitively. Let’s take a look.

Assembly and Accessories

The 34M2C8600 comes out of its crumbly foam packing in three pieces. The panel is heavy, so take care when removing it; you don’t want to mar that shiny screen coating. It doesn’t come with a peel-off film like most OLEDs, so be wary of fingerprints. The base bolts onto the upright then the stand snaps into a slim socket-like fitting. It’s the only weak point here, as it allows a bit of wobble. But it seems sturdy enough for the long haul, and the rest of the chassis is stout. The included cables are all white, and the power supply is internal, so, no brick to find a spot for.

Product 360

Philips

If you put the 34M2C8600 and the 34M2C7600 side-by-side, the only hint that something’s different is the 34M2C8600’s shinier screen coating. It isn’t as glossy as a typical OLED TV but will pick up more reflections than an LCD. Nevertheless, it isn’t too hard to find a good spot for the monitor unless you have it near a sunlit window.

The bezel is flush and relatively narrow, with the white plastic backing just visible in front. A silver trim strip on the bottom is faceted to create a chiseled look. If you turn on the Ambiglow lights underneath, they cast a soft glow on the desktop. More lights are in the back, where a multitude of effects and colors are possible. I like to use Ambiglow as a bias light by shining a white light on the wall behind the monitor. The glow around the screen increases the perception of sharpness and contrast. There is science behind this, and it truly does work. I use bias lights with a projection screen and the OLED TV in my living room.

The stand is very solid and made from cast aluminum. The base is also metal with a plastic covering. The package is well built except for the panel’s attachment point, which is a bit narrow for the weight it carries. That allows for some wobble when making adjustments. You get a 150mm (5.9 inches) height range plus 20 degrees swivel and 5/20 degrees tilt.

Philips hasn’t skimped on the 34M2C8600’s sound quality. A pair of five-watt speakers are integrated along with DTS sound modes. They alter phase and frequency response to create different effects. You can also adjust a five-band eq if you like. In practice, they sounded much larger than the confines of the screen, which almost suggest a surround feel. There isn’t a ton of bass, but they play loud without audible distortion.

Underneath, you’ll find two HDMI 2.0 inputs and one DisplayPort 1.4. A USB-C port supports peripherals, charging and provides an additional DisplayPort 1.4. One upstream and four downstream USB 3.2 ports enhance a KVM feature where you can bind USB and video ports together. That lets you control multiple sources with a single keyboard and mouse. It’s all programmable in the OSD. Finally, if you’d rather plug in headphones, there’s a 3.5mm jack.

OSD Features

The 34M2C8600’s OSD is summoned by clicking a tiny joystick, the only control, on the back right corner. The menu is graphically styled for gaming with seven sub-menus and status info across the bottom.

Tom's Hardware

The 34M2C8600 has 10 picture modes suited to different game types, but the best choice is the default, Standard. It comes close to the mark for grayscale, gamma and color. You can dial down the gamut by turning on the sRGB option. It’s reasonably accurate if you want the correct color values for SDR content. There are five gamma presets and eight color temp presets. Unusually, there are no RGB sliders for fine tweaking. But the Native, Preset and 6500K options are close to D65.

Gaming options include an Adaptive-Sync toggle, DarkBoost for shadow detail, a zoom window for sniping, and a cool adaptive crosshair feature. You can have a colored crosshair if you want, or turn on Smart Crosshair and watch it change color to keep it in contrast with the background. It is always visible, no matter what’s happening in the game. Dynamic DarkBoost will vary low-end gamma to help shadow detail remain visible. Since the 34M2C8600 has such deep black levels, some users may want to turn this on to avoid being surprised by enemies in dark places. Sharp Shooter creates a window in the center of the screen with extra magnification, like a sniper scope.

Ambiglow has enough options to keep one busy for hours. You can run the lights in every spectrum color and turn on different effects. Or run the show in concert with your on-screen content. It creates an extension of the image that is great for impressing your friends. You can also turn on a fixed white light at a low intensity to act as a bias light. This will improve the perception of sharpness and contrast if you have a neutral-colored wall about two or three feet behind the 34M2C8600.

The DTS-tuned audio plays from two five-watt internal speakers that are better than those typically integrated into gaming monitors. The sound modes vary phase and frequency response to create sound stages of varying size. For example, Shooting & Action creates a believable surround effect. If you’d rather tweak it yourself, a five-band eq is provided.

The USB ports can be bound to video inputs using the 34M2C8600’s KVM feature. That lets the monitor operate as a hub for a single set of peripherals.

OLED Panel Care has several options to keep burn-in at bay. All OLEDs are susceptible to it though not as acutely as the plasma TVs of old. The orbiter is invisible in operation and shifts the image minutely to prevent static pictures from using the same pixels for too long. Screen Saver dims the picture after a few minutes of inactivity. Pixel Refresh can be run in the 34M2C8600’s standby mode every few hours to condition the panel further. I use similar features with a two-and-a-half-year-old LG OLED TV and it shows no image retention artifacts.

Philips Evnia 34M2C8600 Calibration Settings

Like the 34M2C7600 VA monitor, the 34M2C8600 cannot be calibrated in the traditional manner. There are no RGB sliders, only fixed color temps and gamma presets. Fortunately, the monitor is accurate enough not to require fine adjustment. Three of the color temp options, 6500K, Preset and Native, all match the D65 standard. And the 2.2 gamma preset is indeed 2.2 with only slight variation. The native color gamut is large, over 105% of DCI-P3, and remains in play for both SDR and HDR content unless you use the sRGB option. It reduces saturation appropriately and is useful for photo editing or any other application that requires sRGB or Rec.709.

HDR signals unlock four additional picture modes. The default is HDR Game, but I found better quality using True Black. It also delivers the highest output and the most accurate color & luminance tracking. It is not adjustable but proved accurate in testing. My recommended settings are below.

Picture Mode	Standard
Brightness 200 nits	83
Brightness 120 nits	48
Brightness 100 nits	39
Brightness 80 nits	31
Brightness 50 nits	17 (min. 13 nits)
Contrast	50
Gamma	2.2
Color Temp	6500K
HDR Mode	True Black

Gaming and Hands-on

There are some monitors that just spoil you, 360 Hz for sure; even many 240 Hz screens make it hard to go back below 200 fps. But an OLED, even running at just 175 Hz, is a serious spoiler.

Of course, the benefits of infinite contrast to image quality cannot be overstated. Yes, Mini LED comes close. But OLED is the best, and the 34M2C8600 is a shining example. SDR games like Tomb Raider could almost pass for HDR. In fact, it looks better played here than HDR games played on an LCD with an edge backlight. I went back and forth with the sRGB option to give it due diligence. The extra color, though not strictly accurate, is a good thing for gaming. The 34M2C8600 doesn’t overblow its hues when using the full gamut for SDR content. And this remained true when watching a video. sRGB is there if you need it for photo editing or color grading tasks.

HDR is where the real fun begins. I spent hours playing Doom Eternal because the 34M2C8600 does everything well. It looks stunning, enough so that you’d swear it’s Ultra HD. The pixel density is 110ppi, the same as a 27-inch 16:9 QHD screen. Ultra HD is in the 130s for most desktop monitors, so yes, it is potentially sharper. But the 34M2C8600’s OLED contrast more than makes up for it.

Gaming feel is off-the-charts fun as well. 175 Hz won’t deliver this level of smoothness from any LCD panel. But OLED keeps the fastest motion tack-sharp at 175 fps. You won’t need a GeForce RTX 4090 here, as you would with an Ultra HD monitor. There’s no overdrive in play, so ghosting is absent. And you won’t have to give up Adaptive-Sync to turn on a backlight strobe either. The 34M2C8600 does its thing perfectly with no enhancements required.

I used Ambiglow as a bias light and tried the follow video/audio feature. Bias lighting is something I use in other viewing scenarios, so it is a familiar effect. The follow option varies the light and color according to what’s happening on the screen. I’ve used it with other Philips displays, and it seems to work better in the 16:9 aspect ratio. The ultra-wide format fills more of my peripheral vision, so I didn’t notice the LEDs as much unless I turned off all the room lights. It’s fun to play around with and you won’t find it on any other brand.

Productivity is entirely natural with the 34M2C8600. The panel curve is benign in that it neither enhances nor detracts from document editing. There is no image distortion in text-based apps like Word or Excel. Photos and videos look the same as they do on a flat screen. Except, of course, there’s that OLED contrast. It makes text pop and dials up the sharpness to where, again, you’d swear it’s 4K.

If you’re concerned about image retention, Philips has provided a complete kit of panel maintenance options in the OSD. I can’t speak to the 34M2C8600 long-term prospects as it would likely take many months of abuse to cause a problem. My LG OLED TV is about two-and-a-half years old and used for several hours daily. It has no burn-in of any kind.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

To compare the 34M2C8600’s performance, I’ve lined up an almost-all-OLED group that consists of Corsair’s Xeneon Flex, Asus’ PG27AQDM, Alienware’s AW3423DW and AW3423DWF, and as a control, the Philips 34M2C7600 which is a VA Mini LED with similar specs.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

Higher refresh rates mean higher frame rates and smoother motion. But when comparing OLEDs, there is little difference between 175 Hz and 240 Hz. Two LCDs running at those speeds are more obviously different. This is because OLED processes motion better and keeps objects sharp at lower speeds. I have observed this to be true of all the OLEDs I’ve tested.

If input lag is your most important metric, the PG27AQDM is the current king, but the 34M2C8600 isn’t far behind at 27ms total. This difference might be too much for professional gamers, but most players won’t be disappointed at the Philips’ feel or performance. It is very responsive and smooth in all types of gameplay. However, you’ll notice the other Philips is a bit lower in the ranking thanks to its 165 Hz refresh rate. And it is much less smooth than all the OLEDs.

Viewing Angles

(Image credit: Tom's Hardware)

Aside from “it’s awesome'' there isn’t much else one can say about the 34M2C8600’s off-axis image quality. This is one of OLED’s major advantages over LCD. The degree of light polarization is far lower, meaning you won’t see any reduction in brightness and just a minimal color shift. You can see a bit of red in both angle shots, horizontal and vertical. But this will be hard to spot in actual content. The 34M2C8600 is very shareable by two users.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

Screen uniformity doesn’t get much better than 2.10% deviation. The 34M2C8600 produced one of the lowest values I’ve ever recorded. None of the OLEDs here have any visible glow, bleed or variation, so as a technology, it is more consistent in this test than LCDs. In practice, any number below 10% is visually perfect.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

The one place where OLED lags behind LCD is in peak brightness. Some LCD monitors can render over 1,000 nits in a full-field white pattern, where OLEDs can show around 300-400 nits. But they get brighter when the white zone takes up less of the screen.

The 34M2C8600 peaks at 226 nits in SDR mode which is bright enough for any indoor environment. That’s a full-field white number. A 25% window pattern measures just over 400 nits. There’s enough light here for any application. With an unmeasurable black level, contrast is theoretically infinite. As impressive as the 34M2C7600 is, with almost 4,000:1, it can’t compare to any OLED.

After Calibration to 200 nits

Tom's Hardware

Since there are no RGB sliders, calibration of the 34M2C8600 is just setting brightness to 200 nits. I used a full-field pattern to create a fairly bright image. Some users may want to tone this down if their room is darker than mine. The 34M2C7600 maintains strong performance when compared to other LCD panels.

ANSI contrast cannot be determined for any OLED as the black squares are unmeasurable. The 34M2C7600 is a good performer but the OLEDs are on another level. This is a difference that can be seen in content during side-by-side comparisons.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

The 34M2C8600 ships in its Standard picture mode and it is close enough to spec that one can simply set brightness to taste. No RGB sliders are available, but three of the color temp presets render D65.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

By default, the color temp is set to 6500K with gamma at 2.2. Tiny errors at 60, 90 and 100% are nearly invisible in both test patterns and content. Gamma is slightly light at the 20% step and a bit dark at 90%, also a minor error. This is excellent out-of-box performance.

I’ve included the grayscale and gamma run as a post-calibration result, but the only adjustment is a reduction in the brightness slider. That tightens up gamma a bit, but no other changes have occurred.

Turning on the sRGB option shrinks the gamut and leaves gamma and grayscale the same. And that is how it should be.

Comparisons

Tom's Hardware

The other monitors, save the 34M2C7600, can be calibrated to a high standard. Visual differences here are tiny but nit-pickers may take issue with the 34M2C8600’s lack of RGB controls. However, in my experience, it didn’t lessen the gaming experience. Gamma, at any rate, is tight with a small 0.13 range of values and a minor 1.36% variation from the 2.2 reference value.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

Aside from a bit of red over-saturation, the 34M2C8600 renders all, and then some, of DCI-P3. Most importantly, it hits all the green points, which most wide-gamut monitors cannot do. The errors are tiny and not visually significant. You’ll see a bit of bonus red in some content but not enough to cause a complaint. You can see that changing the brightness value does not alter the gamut test result.

The sRGB gamut rendering is interesting. Red is quite over-saturated, but blue is under. This is unusual in my experience. The overall error level is low, but in content, you’ll see the extra red and blue will look a little pale. The 34M2C8600’s version of sRGB is superior to that of the 34M2C7600, but neither monitor is really qualified for color-critical work in the sRGB color space. If DCI-P3 is on the menu, you’re fine.

Comparisons

Tom's Hardware

The 34M2C8600’s 1.58dE color error is hard to beat by any monitor except an OLED. The screens I’ve tested so far are all more color-accurate than typical LCDs. At 2.66dE, the 34M2C7600 isn’t far behind though. I’m splitting hairs here.

One of the main promises of quantum dot OLEDs is greater color saturation. You can see that in play from both the 34M2C8600 and the Alienware screens which also have QD layers. But the Philips wins the day by a nose. It is extremely colorful, and that’s something that clearly translates to gaming and productivity. The image is stunning in every respect. Note that even the least colorful screen isn’t far below 100% coverage. That’s well above the norm, which is closer to 90%.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

If HDR brightness is important to you, a Mini LED screen is the better choice. Some of them can exceed 1,400 nits. But dynamic range is the most important thing to me and anyone else seeking maximum image depth. That’s where OLED is unchallenged.

HDR Brightness and Contrast

Tom's Hardware

The 34M2C8600 meets its DisplayHDR 400 certification when measuring a 25% window pattern. Philips specs it at 1,000 nits with a 3% window, but I could not verify this with my equipment. I have no complaints whatsoever. And like any OLED, black levels can’t be measured so the contrast is infinite. I observed the same behavior from the Mini LED 34M2C7600.

Grayscale, EOTF and Color

Portrait Displays Calman

I measured the 34M2C8600’s four HDR modes and settled on True Black as the best. The default setting, HDR Game, is just OK. It rises out of black too quickly, where True Black sticks closer to the reference. This provides a much more dramatic effect. HDR looks amazing here with flawless grayscale and near-perfect luminance tracking. It doesn’t get better than this.

HDR color is over-saturated in the red and green primaries, but the other colors follow their targets closely. The 34M2C8600 tracks better than many of the HDR monitors I’ve tested. This translates to sharp detail, natural hues and content that just looks right. Similar behavior can be seen in the Rec.2020 test, where the red primary almost hits 100%. There is a ton of color here and it shows in everything, games, video, still photos, even the Windows desktop.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

Philips has come out of the gate swinging with its new Evnia monitors. I was impressed with the Mini LED 34M2C7600, but the 34M2C8600’s QD-OLED panel is simply on another level from any LCD gaming monitor I’ve reviewed. OLED's look and feel will dominate the desktop monitor market as prices move downwards. If you can invest in bleeding-edge display technology, OLED is it.

(Image credit: Philips)

The 34M2C8600 delivers infinite contrast and a huge color gamut, one that covers more than 108% of DCI-P3, thanks to its Quantum Dot layer. That puts it among the most colorful monitors currently available. Like all OLEDs, its pixels can be turned off to create true blacks. Mini LED has up to 1,196 dimming zones, but a WQHD OLED panel has 4,953,600. So which do you think will look better? And with 1,000-nit highlights in HDR mode, there’s plenty of brightness to spare.

The gaming feel of OLED panels has spoiled me. After playing on many 240 and 360 Hz monitors and even a 500 Hz screen, I have observed that an OLED running at 165 or 175 Hz delivers a similar level of smoothness. The high refresh panels have lower input lag as their only true advantage.

It should be noted that the 34M2C7600 costs the same as the 34M2C8600 at this writing. With identical features and styling, the difference is simply OLED versus VA/Mini LED. Both monitors look amazing, but I’ll choose the OLED every time. Of course, if you need searing brightness, the Mini LED wins. But for the ultimate gaming experience, OLED is king. Those wanting to add a superlative monitor to their gaming system should check out the Philips Evnia 34M2C8600.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor

MORE: How to Choose the Best HDR Monitor

MSI 27-Inch 170 Hz Curved WQHD Monitor Now $220 at Newegg

Ash Hill — Thu, 11 May 2023 20:49:27 +0000

Today at Newegg, users can take home the 27-inch MSI G27CQ4 E2 gaming monitor for one of its best prices yet. This display usually goes for around $250 but today it’s marked down to $230. Using promo code SSCSAA27 at checkout will take the price down to $220. This code is limited and we’re not sure for how long the discount will be made available.

This monitor spans 27 inches across and has a curvature graded at 1500R. It has a WQHD resolution which measures up to 2560 x 1440. It features a VA panel which isn’t quite as enticing as an IPS but given the dense resolution and curved design, it’s a fair tradeoff at this price.

MSI 27-Inch G27CQ4 E2 Gaming Monitor: was $250, now $220 at Newegg
The MSI G27CQ4 E2 is a 27-inch curved gaming monitor. It has a WQHD resolution of 2560 x 1440 and a curvature of 1500R. To get the offer, be sure to use promo code SSCSAA27 at checkout.View Deal

The MSI G27CQ4 E2 is capable of reaching a maximum refresh rate of 170 Hz. It has a console mode that can run at 120Hz with an FHD resolution. The G27CQ4 E2 is illuminated with a brightness that caps out at 250 Nits. The response time is fairly short, measuring at 1ms MPRT.

Users have a couple of video input options to choose from which is handy if you plan to use it with multiple devices. There are two HDMI inputs as well as a Display Port input. It also has a 3.5mm audio jack for external audio peripherals.

To get a closer look at this deal, visit the MSI 27-inch G27CQ4 E2 product page at Newegg for more details and purchase options. It’s not clear how long the $230 price will be made available. Be sure to use promo code SSCSAA27 at checkout to redeem the full offer and take the price down to $220.

What Is 1440p? QHD/UWQHD Resolution Explained

brandon.hill@futurenet.com (Brandon Hill) — Wed, 26 Apr 2023 12:49:52 +0000

1440p is also called QHD (quad high definition) or WQHD (wide quad high definition) and is a display resolution that measures 2560 x 1440 pixels. This resolution is also commonly referred to as 2K.

Resolution explains how many pixels a display has in width x height format. The more pixels a display has, the sharper its image quality should be. QHD resolution gets its name for offering four times the definition of standard HD, aka 720p (1280 x 720 resolution).

QHD screens are noticeably sharper than Full HD (FHD), aka 1080p resolution (1920 x 1080) models, which are much more common and cheaper. This higher resolution also makes going to screens larger than 27 inches without seeing individual pixels more feasible when shopping for a PC monitor. However, a QHD screen will eat up more battery with laptops than an FHD display.

What About WQHD?

You may also see QHD resolution referred to as UWQHD, which stands for wide quad high definition. These two acronyms represent the same resolution; WQHD is a marketing technique to emphasize the wide-screen format of the resolution.

However, vendors will also label ultra-wide monitors as UWQHD even though they don't have 2560 horizontal pixels. This is because they still have 1440 vertical pixels but have more horizontal pixels for a wider aspect ratio than 2560 x 1440's 16:9 aspect ratio. An example would be the 3440 x 1440 resolution in the Corsair Xeneon Flex 45WQHD240.

Common Display Resolutions

5K	5120 x 2880
4K	3840 x 2160 (typical monitor resolution); 4096 x 2160 (official cinema resolution)
Ultra HD (UHD)	3840 x 2160
QHD aka WQHD aka 1440p	2560 x 1440
2K	2560 x 1440 (typical monitor resolution); 2048 x 1080 (official cinema resolution)
WUXGA	1920 x 1200
Full HD (FHD) aka 1080p aka HD	1920 x 1080
HD aka 720p	1280 x 720

This article is part of the Tom's Hardware Glossary.

Acer Debuts 44-inch DQHD Nitro, 34-inch 175 Hz OLED Predator Gaming Monitors

brandon.hill@futurenet.com (Brandon Hill) — Thu, 20 Apr 2023 13:30:39 +0000

Acer is amping up its gaming monitor portfolio today by announcing two interesting offerings: the Nitro XZ452CU V and the Predator X34 V.

We'll kick things off with the Nitro XZ452CU V, the larger of the two monitors. It measures 44.5 inches across and features a 1500R curvature for a more immersive gaming experience. In addition, the monitor has a Double QHD resolution, which is like having two 2560 x 1440 monitors sitting side-by-side.

Acer says that the Nitro XZ452CU V is rated for 165 Hz (and 1 ms response time) with backing from AMD's FreeSync Premium Pro technology to tackle screen tearing and reduce input lag. In addition, Acer says that the monitor maintains that 165 Hz refresh rate at DQHD resolution over HDMI, DisplayPort, or a USB-C connection.

The Nitro XZ452CU V uses an 8-bit VA panel, so you can expect excellent contrast (and narrower veiewing angles) compared to a typical IPS panel. Acer doesn't list the native contrast ratio, but the dynamic contrast ratio is listed at 100,000,000:1. Brightness is rated at a native 450 nits (VESA DisplayHDR 400 certified), while Acer says that the Nitro XZ452CU V can hit 90 percent of the DCI-P3 color gamut.

Regarding ports, the Nitro XZ452CU V is configured with two HDMI 2.1, one DisplayPort 1.4, one USB-C with 90-watt Power Delivery, an RJ45 network port, a three-port USB 3.2 hub, and a built-in KVM switch. You'll also find dual 3-watt speakers onboard if you don't already have a set of speakers to hook up to your gaming rig.

(Image credit: Acer)

Moving on, we come to the Predator X34 V, Acer's latest OLED gaming monitor, measuring 34 inches across (as its name suggests) with an 1800R curvature. The monitor features an Ultra-Wide QHD (3440x1440) resolution with a 175 Hz refresh rate and a fast 0.1ms response time (AMD FreeSync Premium is supported).

Other niceties include 250 nits typical (1,000 nits peak) with VESA DisplayHDR TrueBlack 400 certification, a 1,000,000:1 contrast ratio, and 99 percent coverage of the DCI-P3 color space. The Predator X34 V has two HDMI ports, one DisplayPort 1.4, and a USB-C port capable of 65-watt power delivery. The maximum 175 Hz refresh rate is only achievable over USB-C or DisplayPort. If you opt for the HDMI interface, you're limited to a maximum of 100 Hz. There's also a built-in two-port USB 3.2 hub and integrated 5-watt speakers.

According to Acer, the Nitro XZ452CU V will launch in Q4 2023, priced at $999. The Predator X34 V will arrive during the same quarter with a $1,299 price tag.

ViewSonic Elite XG341C-2K Review: Elite Color and Image Quality

Christian Eberle — Wed, 01 Mar 2023 13:00:58 +0000

If you’re looking for a high-contrast computer monitor, there are two technologies that deliver maximum dynamic range: OLED and Mini LED. I’ve covered OLED screens before, and while they have the deepest blacks of any flat panel, they can’t get as bright as some LCDs. For peak ratings over 1,000 nits, only full-array local dimming (FALD) models can compete. And OLED burn-in is still a concern for many users looking for the best gaming monitors.

ViewSonic already impressed me with the XG321UG 32-inch flat screen, and now, I have a curved example of its Mini LED Elite line, the XG341C-2K. This 34-inch VA panel with WQHD (3440x1440) resolution and 1500R curvature promises peaks of 1,400 nits in HDR mode along with 200 Hz operation, Adaptive-Sync and a wide color gamut. Let’s take a look.

ViewSonic Elite XG341C-2K Specs

Panel Type / Backlight	VA / Mini-LED
	Full array - 1,152 dimming zones
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve radius: 1,500mm
Max Resolution & Refresh Rate	3440x1440 @ 165 Hz
	200 Hz w/overclock
	FreeSync: 48-165 Hz
	G-Sync Compatible
Native Color Depth & Gamut	8-bit / DCI-P3
	DisplayHDR 1400, HDR10
Response Time (MPRT)	1ms
Brightness (mfr)	750 nits SDR
	1,400 nits HDR
Contrast (mfr)	3,000:1
Speakers	2x 5w
Video Inputs	1x DisplayPort 1.4
	2x HDMI 2.1, 1x USB-C
Audio	3.5mm headphone output
USB 3.2	1x up, 3x down
Power Consumption	68.7w, brightness @ 200 nits
Panel Dimensions	31.8 x 18.9-23.7 x 15.1 inches
WxHxD w/base	(807 x 481-601 x 384mm)
Panel Thickness	5.2 inches (132mm)
Bezel Width	Top/sides: 0.3 inch (8mm)
	Bottom: 0.8 inch (20mm)
Weight	25 pounds (11.4kg)
Warranty	3 years

It’s easy to surmise that high brightness ranks as Mini LED’s chief advantage, but the more important aspect is its greater number of dimming zones. A traditional 21:9 aspect FALD display might have 384 zones, but the XG341C-2K has 1,152. When it comes to high contrast and HDR, the more addressable zones, the better. Self-emitting panels like OLED can dim every pixel, creating millions of zones, but Mini LED is the next best thing. And don’t think it’s a distant second. In my experience so far, the gap in image quality is small. The XG341C-2K also ups the ante with a VA panel, starting with 3,000:1 native contrast before applying dynamic dimming.

In addition to high brightness, the color gamut is extensive. In my tests, I measured only a hair under 100% coverage of DCI-P3. That puts the XG341C-2K in a small group of more colorful monitors than most wide-gamut screens, which cover around 90%. The only thing missing on that front is an sRGB mode. Though most users won’t have an issue, you’ll be using the full gamut for all content, SDR and HDR alike.

The XG341C-2K also delivers gaming performance with a 200 Hz overclock mode, significantly improving from the native rate of 165 Hz. You also get Adaptive-Sync and blur reduction, which ViewSonic calls Pure XP. It’s a backlight strobe with multiple settings, so you can find the right balance between smoothness and brightness. A five-level overdrive also works with AMD FreeSync or Nvidia G-Sync to reduce blur. The monitor carries FreeSync Premium Pro certification and I verified G-Sync operation in my tests. The XG341C-2K has not been certified by Nvidia.

Contrast is the XG341C-2K’s forte, and with dimming disengaged, it hit nearly 4,000:1 in testing. With dimming turned on, the dynamic range is infinite for both SDR and HDR content. The dimming has five levels of aggressiveness to find just the right setting for your environment. This feature really ups every image's depth and pop, whether moving or static, SDR or HDR.

The XG341C-2K is a premium product, but it isn’t quite as expensive as its predecessors. The closest example is Acer’s Predator X35 which sells for over $2,000. The ViewSonic comes in at around $1,500. Interestingly, that’s the same price as Samsung’s Neo G8, which offers similar brightness and contrast with 240 Hz operation. The choice will come down to resolution and size. The ViewSonic’s ultra-wide screen is hard to ignore.

Assembly and Accessories

The Elite XG341C-2K ships in a large clamshell carton with lots of protective material inside. Unfortunately, it’s the crumbly stuff, so keep a vacuum handy when unpacking. The upright and large base are solid metal and mated with a captive bolt. The panel then snaps in place. If you’d rather use a monitor arm, there’s a 100mm VESA mount with fasteners included. The power supply is internal, so you’ll find an IEC power cord in the box. You also get USB-A/B, USB-C, DisplayPort and HDMI cables.

Product 360

ViewSonic

Tom's Hardware

The XG341C-2K sports a slim flush bezel of 8mm around the top and sides. At the bottom is a wider trim strip with Elite silk-screened in the center. On the right is a tiny power LED that glows blue when the power is on and orange in standby mode. ViewSonic is printed on the base in small letters, and there are no other graphics or physical features to distract from the gameplay experience.

You’ll find a single joystick control that covers all monitor functions in the back. It works a little differently than others I’ve used. Pressing it toggles the power, but once on, pressing it again turns it off rather than displaying the OSD (you click up or down to access the OSD). Once in the menu, don’t press the joystick since it will power off. I made that mistake a few times before adapting to these peculiarities. Also in the back is the Elite RGB lighting feature with its four diffused strips that glow in all colors of the spectrum with four different effects available.

The stand is beautifully styled and finished in a matte black powder coat. The base and upright are slender but rock solid. The base is quite deep, with the panel set well forward. On a typical desk, you’ll find yourself about two feet from the screen if you push the base all the way back. The panel sits high enough that I could make it perfectly vertical and center my eyepoint. That is my preferred way to play on a curved monitor because it keeps more of the image focused at any given time.

In the last photo above, you can see the XG341C-2K’s curve of 1500R. This is a good balance between immersion and image distortion. You can expect a normal computer monitor experience when working on spreadsheets or writing tasks. And it’s fine for photo editing and web browsing too.

The input panel is fully stocked with two HDMI 2.1, a DisplayPort 1.4 and USB-C, which can support peripherals or emulate DisplayPort. Additionally, there are three downstream USB-A and a single upstream USB-B port. A 3.5mm headphone jack supports audio from either DisplayPort or HDMI streams and there are two internal speakers that play with reasonable volume before sounding distorted.

OSD Features

The XG341C-2K’s OSD has a business-like appearance that is free of graphics. An almost retro-styled font delivers all the information necessary for use. To open it, click the joystick up or down. Don’t press it, or the power will turn off. Ask me how I know.

Tom's Hardware

There are six sub-menus that are well organized, though a lot of convenience features have been grouped into the setup menu at the end.

We start with Game Modes, of which there are 10. I only needed the default, Custom 1, to run my tests and use the XG341C-2K for both work and entertainment. What you won’t find is an sRGB mode. All picture modes use the full native gamut, which covers nearly 100% of DCI-P3. That’s colorful to be sure, but not entirely accurate for SDR content. Custom 1 makes all other picture controls available.

The Display menu has gaming options like a FreeSync (Adaptive-Sync) toggle, HDR modes, local dimming, Pure XP (blur reduction) overclocking to 200 Hz, overdrive, and color controls. There are a few caveats to note here. If you want to run at 200 Hz, you can’t have Adaptive-Sync or Pure XP. To use these, 165 Hz is the limit. And Pure XP works instead of Adaptive-Sync. In practice, the XG341C-2K is a 165 Hz monitor, which isn’t necessarily a bad thing. 200 Hz doesn’t provide a huge bump in speed, but I’ll cover that in the response and lag tests. Further details on video processing options can be found in the Gaming & Hands-on section below.

You can choose from four color temp presets or adjust the RGB values for picture tweaks. Six gamma options range from 1.8 (light) to 2.8 (dark). Color saturation is also adjustable, and you can raise the black level if shadow detail is obscured. Image Adjust is where the brightness and contrast controls are, and there’s a sharpness option that should be reduced, as the default setting creates noticeable edge enhancement.

Three HDR modes engage automatically when an HDR10 signal is present. DisplayHDR is the best choice, providing a superb image with deep blacks and bright punchy highlights. HDR is clearly the XG341C-2K’s forte.

The next menu, ViewMode, alters the picture further depending on the Game Mode selected. I recommend leaving that one alone because if you start tweaking it, there are hundreds of possible combinations, most of them poor. Custom 1 and Standard are the best options.

The Setup Menu has four screens of options like aiming points (three shapes in three colors), RGB lighting, USB power, and OSD settings. The joystick can have its left and right clicks set to several functions for quick access. Here, you’ll find a PIP and PBP option that lets you view two video sources simultaneously. On the last screen, the Memory Recall option resets the XG341C-2K to its factory defaults.

ViewSonic Elite XG341C-2K Calibration Settings

The XG341C-2K showed me a cool grayscale and dark gamma during initial testing, indicating that it needs calibration for the best image. This is easily accomplished by tweaking the RGB values and changing the gamma preset to 2.0. The color gamut is not adjustable, so you’ll always see around 100% of DCI-P3 (over 140% of sRGB), even in SDR mode. There is no sRGB setting. In HDR mode, there are no picture options save the three preset picture modes that look very similar. I recommend the default, DisplayHDR. The only other nitpick is that you’ll need to switch the local dimming on and off manually. You’ll want it for HDR but not always for SDR as it makes the picture very bright. My recommended SDR settings are below.

Picture Mode	Standard
Brightness 200 nits	17
Brightness 120 nits	7
Brightness 100 nits	4
Brightness 80 nits	2 (min. 72 nits)
Contrast	70
Gamma	2
Color Temp User	Red 97, Green 99, Blue 100

Gaming and Hands-on

With its 1500R curvature, the XG341C-2K is well suited for work and productivity. There is no visible image distortion, even when sitting closer than three feet away. And the 109ppi pixel density is perfect for detail and fine lines. I never saw any jaggies or pixelation in graphics or when rendering small fonts. In practice, a 34-inch 21:9 monitor is nearly the size of two 27-inch 16:9 screens, and you don’t have a line down the middle.

Though the color gamut is larger than SDR’s sRGB standard, the extra saturation isn’t a problem unless you need accuracy for photo work. The picture has a nice glow with deep blacks and plenty of depth for typical tasks. The text is easy to read against white backgrounds, and if you turn on the local dimming in SDR mode, the picture becomes very bright. It might be too much for long work sessions, but your experience may vary from mine.

Switching back and forth between HDR and SDR revealed a few quirks. The XG341C-2K goes to HDR without an issue. But returning to SDR, the monitor remained stuck in HDR mode, which distorted the color palette significantly. I had to manually turn off HDR, meaning the next time I wanted to view HDR content, I had to re-engage it in the OSD. So, in its current form, it does not switch back and forth automatically.

The same is true of the local dimming. If you want to use it for SDR, you’re good. It will remain engaged for SDR and HDR all the time. But if you’d rather switch it off for SDR, you must turn it on after switching to HDR mode and back off when returning to SDR.

Another thing I noticed is that turning on Adaptive-Sync grays out the brightness control, which is unusual. The set white level is higher than 200 nits, settling in around 275. If you work in a dark room, the XG341C-2K will be quite bright with Adaptive-Sync engaged.

Those experiments took me to gaming, where I tried a few different video processing options. My experience has shown that below 200fps, you need Adaptive-Sync. That isn’t a problem since the XG341C-2K runs it up to 165 Hz. However, at 200 Hz, Adaptive-Sync is off the table. In practice, if you can keep frame rates close to 200, it isn’t essential. But you’ll need a fast video card to run 200fps at 3440x1440. I was able to do this with a GeForce RTX 3090. I chose to forego Adaptive-Sync since motion is a bit smoother at 200 Hz vs 165 Hz. In either case, the overdrive did a decent job keeping artifacts at bay. Though I saw some black ghosting in test patterns, it didn’t come up during gameplay.

If you’re tempted to try Pure XP, you’ll find that its phasing artifact is prominent enough to be a distraction. In fairness, very few monitors have a good backlight strobe. Nearly all show extra lines behind moving objects. I didn’t use it after my initial trial.

Playing Doom Eternal, I looked for accuracy in aiming and response when clicking the mouse. I got ample quantities of both. I had no trouble working through familiar maps quickly and dispatching enemies in large numbers. The XG341C-2K is a very accurate monitor for moving and shooting. It also presented a superb HDR image with rich, bold color and super-low black levels. The Mini LED and its 1152 dimming zones help this monitor impressively impersonate an OLED panel. HDR contrast here is among the best I’ve seen.

I also observed better-than-average audio. The internal speakers are distortion-free up to a reasonably loud volume and clearly present ambient sound and dialog. Though I prefer headphones for the best experience, these would do well in a pinch.

Despite a few extra steps in switching between HDR and SDR, the XG341C-2K proved to be an excellent gaming tool that will suit gamers of all skill levels up to competing professionals. Here are my recommended settings for SDR and HDR gaming.

FreeSync Premium Pro – on for 165 Hz, off for 200 Hz (dependent on video card speed)
Local Dimming – off for SDR, level 2 for HDR
HDR mode – DisplayHDR
Overdrive – Fast (setting 3 of 5)

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

I’ve lined the XG341C-2K up against similar screens, 34-inch ultra-wide 165 Hz refresh rate monitors with WQHD resolution. The Acer X35 Mini LED, AOC CU34G3S, MSI MPG343CQR and ASRock PG34WQ are VA panels, while the Alienware AW3423DWF is an OLED.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

I tested the XG341C-2K at 165 and 200 Hz. Remember that overclocking means you can’t run Adaptive-Sync or the backlight strobe; however, you get overdrive in all cases.

The Acer is a costly monitor, but it’s worth including here for its excellent performance. It doesn’t have the limitations of the XG341C-2K; you can run it at 200 Hz with Adaptive-Sync for a $1,000 premium.

The difference between 165 and 200 Hz is clearly small, too small to give up Adaptive-Sync. In both tests, the XG341C-2K came out on top for total input lag, which is good. This a very responsive monitor, and overdrive quality is about average for the category. On its Fast setting, it showed slight black ghosting, but in practice, gaming was smooth and free of tearing or stutter. Motion resolution clarity was also average for the category.

Viewing Angles

(Image credit: Tom's Hardware)

The XG341C-2K has better off-axis image quality than most of the VA panels I’ve reviewed. It isn’t entirely up to the best IPS panels in this test, but it comes close. You’ll see a 20% light reduction and a slight green shift at 45 degrees to the sides. Gamma remains constant, so no detail is obscured in highlight or shadow areas. The vertical plane shows a washed-out picture with a shift to red and green.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

My XG341C-2K review sample showed uniformity befitting a premium monitor with just a 3.83% variation in brightness from the center, which is well below the visible threshold. No glow or bleed could be seen. The image is free of grain or variation, and all patterns I checked were perfectly toned from edge to edge.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

The XG341C-2K boasts a very bright 656 nits peak at its default settings, which is too bright for any indoor setting. Fatigue will set in quickly at this level. The downside is that the minimum level is 72 nits which is a little hot for a darkened room. It also means each click of the brightness control changes the level by 4-6 nits, making it harder to find a precise setting.

With local dimming turned off, the black level is respectable and results in a native contrast ratio of 3,742.1:1, above average for a VA panel. If you engage the dimming, the black level can’t be measured, and contrast is infinite.

After Calibration to 200 nits

Tom's Hardware

With peak white set to 200 nits, the XG341C-2K displays the deepest blacks of the VA panels in the group. A native contrast ratio of over 4,000:1 means you can see a very high-quality image without resorting to local dimming. If you engage it, the black level can’t be measured. And you’ll definitely want it on for HDR content.

ANSI contrast is much the same at almost 3,900:1. This is one of the better VA monitors I’ve tested. Even without a dimming feature, it would look better than most of its competition. With dimming on, ANSI contrast is infinite. The XG341C-2K is well-engineered and built with excellent quality control. Only the Alienware OLED monitor can claim picture quality this good.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

The XG341C-2K doesn’t ship with a factory-certified calibration. In its default mode, I found it needed some tweaking to achieve the best possible image.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

This is the XG341C-2K’s Custom 1 gaming mode and Standard view mode, the default settings. Grayscale tracks visibly blue and gamma is quite dark. This gives the image a murky appearance and negates much of the monitor’s contrast advantage.

After adjusting the RGB values and changing the gamma preset from 2.2 to 2.0, the measurements and image quality are greatly improved. This is what’s expected from a premium monitor sporting the latest Mini LED technology. Aside from a slight dip at 90% brightness, this is perfect grayscale and gamma tracking.

Comparisons

Tom's Hardware

The XG341C-2K is firmly in the “needs-calibration” category. While you can turn up the brightness or engage local dimming to make the picture less murky, the blue grayscale still makes it look flat. Once adjusted, it looks much better.

The gamma presets are off by one click, as the default 2.2 option yields 2.4. This is too dark, and it robs the XG341C-2K of some of its contrast advantage. Luckily, changing the setting to 2.0 solves the issue neatly. With a 0.14 range of values and just 1.36% deviation, it ranks among the best in the gamma test.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

The default color gamut run shows hue errors consistent with the blue grayscale I noted earlier. Red and cyan are off hue. Red and magenta are also a bit over-saturated though most users won’t mind the extra punch of color that affords.

Calibration mostly takes care of the hue errors, but red is still a bit off. Again, this won’t bother most users as it makes the picture extremely vivid. It isn’t entirely accurate, but it will pump up the look of all content, SDR and HDR. My only complaint is that there’s no sRGB mode. You have to use the full gamut for all content.

Comparisons

Tom's Hardware

Calibration brings the XG341C-2K’s color gamut error from 4.35dE to 2.38dE, a visible gain in quality. Though reds are a bit over-saturated, the picture is not unnaturally vivid. When compared to other extended color monitors, it delivers just a little bit more vibrance.

That is explained by its near 100% coverage of DCI-P3. Most currently available wide-gamut monitors have less color volume than the XG341C-2K. The over-saturated red primary means you’ll need a software profile for color-critical work, but this monitor can be used as a professional tool. An sRGB mode would be welcome, but that omission can also be solved with software.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

The XG341C-2K, like other Mini LED monitors, can display very bright highlights in HDR mode. When an HDR10 signal is applied, it switches automatically and opens up three HDR-specific picture presets. I found them very similar in look and measurement, so I did my tests in the default DisplayHDR mode.

HDR Brightness and Contrast

Tom's Hardware

The XG341C-2K is certified DisplayHDR 1400, and it manages that feat when measuring a 25% window pattern. This shows that it has more than enough power to deliver super-bright highlights in HDR mode. Most LCD panels with traditional LED backlights struggle to provide this much light from any onscreen object bigger than a few pixels. To achieve this, I had to engage local dimming. Any level from 1 to 5 will engage the full dynamic range. That means when a 0% black pattern is displayed, the backlight is turned off, rendering contrast infinite. Even displaying a small white object like an info bug won’t turn on the LEDs in the surrounding zones. ViewSonic has implemented its Mini LED technology extremely well here.

Grayscale, EOTF and Color

Portrait Displays Calman

The XG341C-2K’s HDR grayscale tracking runs a bit warm in brightness steps above 55%. This is a more excusable error than blue or green because red is less visible in practice. All three HDR modes exhibit the same behavior. The EOTF runs slightly dark but not enough so that detail is obscured. The tone-map transition point is 75% which means more of the content meta-data can be used to determine luminance levels. This always bodes well for picture quality, which is excellent.

The XG341C-2K shows some over-saturation in HDR mode in the red, magenta and blue areas of the gamut. This warms up the image in a good way. Though not completely accurate, the picture is pleasing and natural, with vivid color and depth. With such low black levels, well-mastered content looks three-dimensional. You can see in the Rec.2020 chart that the XG341C-2K covers a good portion of that large gamut, coming up short only in green and cyan.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

There is no doubt that Mini LED is fast becoming the go-to tech for high-contrast monitors. Though OLED will always have the advantage with its self-emissive pixel structure, LCD, in the minds of most users, is the more practical screen type. Add in wide color gamuts and high brightness, and the fact that a good Mini LED screen isn’t vastly different from an OLED in quality, and you have something truly compelling.

(Image credit: ViewSonic)

Following in the footsteps of the stunning XG321UG Ultra HD monitor, the XG341C-2K brings the goods to the curved ultra-wide category. Gamers like curved screens, and this is one of the best. The picture is stunning in both SDR and HDR modes. With 1,400 nits available, highlights always pop and black levels are deep thanks to 1,152 dimming zones and well-implemented local dimming.

Large color gamuts are a must in the premium gaming monitor genre and the XG341C-2K delivers there too. It covers nearly 100% of DCI-P3, putting it in an elite group. Appropriate then that ViewSonic calls it “Elite.” Though I noted a few initial inaccuracies and a missing sRGB mode, color is rich and vibrant, and I doubt anyone will complain about the picture.

The XG341C-2K is a gamer’s tool as well. With low input lag and smooth operation, I found it very accurate for moving and shooting. Its generous width and 1500R curve deliver immersive play with a picture that wraps around the user’s eyepoint. The only flaws here are the inability to run Adaptive-Sync at 200 Hz and the lack of brightness control when Adaptive-Sync is turned on. These are unusual quirks but not deal-breakers. I enjoyed every minute of gaming on this monitor.

Premium ultra-wide screens like the XG341C-2K are still expensive, but progress is being made. At $1,500, it costs the same as a Samsung Neo G8 and undercuts the Acer X35. And it offers almost as much contrast as the Alienware AW3423DWF with higher brightness than that OLED monitor. Operational quirks aside, this is an excellent gaming monitor with a stunning picture. Users seeking a high-performance 21:9 screen should definitely check it out.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

ASRock PG34WQ15R2B Review: Efficient With Balanced Performance at an Attractive Price

Christian Eberle — Fri, 17 Feb 2023 13:00:47 +0000

When new technologies saturate the marketplace, prices inevitably go down. It took a few years, but some of the best gaming monitors feature curved ultra-wide panels at reasonable prices. 34-inch WQHD (3440x1440) gaming screens run fast and deliver solid gaming performance for less than $500.

Known mainly for its PC hardware, ASRock introduced a line of monitors branded Phantom Gaming in 2022. The curved entry, and my review subject, is the PG34WQ15R2B, hereafter known as the PG34WQ. It’s a WQHD VA panel with a 1500R curve, 165 Hz, Adaptive-Sync, HDR 400, and extended color.

Specifications

Panel Type / Backlight	VA / W-LED, edge array
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve radius: 1500mm
Max Resolution & Refresh Rate	3440x1440 @ 165 Hz
	FreeSync: 48-165 Hz
	G-Sync Compatible
Native Color Depth & Gamut	8-bit / DCI-P3
	HDR10, DisplayHDR 400
Response Time (MPRT)	1ms
Brightness (mfr)	550 nits
Contrast (mfr)	3,000:1
Speakers	2x 2w
Video Inputs	1x DisplayPort 1.4
	2x HDMI 2.0
Audio	3.5mm headphone output
USB 3.0	None
Power Consumption	34.1w, brightness @ 200 nits
Panel Dimensions	31.9 x 18.4-22.4 x 11.1 inches
WxHxD w/base	(809 x 467-569 x 283mm)
Panel Thickness	4.7 inches (120mm)
Bezel Width	Top/sides: 0.3 inch (8mm)
	Bottom: 0.8 inch (21mm)
Weight	19.4 pounds (8.8kg)
Warranty	3 years

The PG34WQ gets off to a great start with a VA panel boasting a native contrast ratio of 3,000:1. The LED backlight has a field dimming feature that extends dynamic range for SDR and HDR content. In HDR mode, it’s always active and, in my tests, delivered nearly 17,000:1. There’s plenty of light output, with just shy of 500 nits peak. SDR mode tops out at just over 300 nits.

A wide color gamut covers about 85% of DCI-P3, which is average for the category. ASRock engineered the gamut to strike a good compromise between sRGB and P3. This makes it well suited for SDR content mastered in the smaller color space. You can see the extra color without going too far past the mark.

The PG32WQ is a great value at $430 with just about everything a gamer could want without added bells and whistles. You get Adaptive-Sync which works equally well on Nvidia and AMD platforms. The 165 Hz refresh rate is achieved without overclocking. And tweakers will appreciate the inclusion of MPRT, also known as a backlight strobe, to reduce motion blur.

You won’t find things like aiming points, timers or frame counters. And there’s no LED lighting, so you’ll have to relegate any pyrotechnics to your PC and other peripherals. But there are a few interesting and unique things here that set the PG34WQ apart.

Assembly and Accessories

The first thing that caught my attention when unpacking the PG34WQ were two slim coax cables. After turning to the quick start guide, I discovered that ASRock integrated Wi-Fi antennae into the stand. The cables run between the monitor and the coax connections on your PC. That’s a first, in my experience. You also get HDMI and DisplayPort cables with an IEC cord for the internal power supply. The stand and base couple with a captive bolt, and the panel snaps in place for a solid fit.

Product 360

ASRock

The PG34WQ’s 1500R curve is neither subtle nor overt. It hits the balance point between immersion and image distortion, with a good deal of the former and none of the latter. The anti-glare layer is aggressive but not grainy, and the image is sharp without any edge enhancement to reduce resolution. Pixel density is 109ppi, the same as a 27-inch 16:9 flat panel. The bezel is thin at 8mm and flush; you’ll barely notice it when viewing content.

The bottom trim strip features a Phantom Gaming logo and little else save a tiny blue LED to indicate power status. You’ll find an OSD joystick in the back, two control keys and a power toggle. ASRock announces itself in polished lettering set under a thin grill that vents heat near the top of the panel.

The two Wi-Fi antenna ports are at the bottom of the upright so that the cables won’t intrude once connected. The stand is solid with firm movements that include -7/20 degrees tilt, 20 degrees swivel and a 100mm height adjustment. The Phantom Gaming logo is featured in the front and in the back. A small hole helps tidy any wiring. Under the panel mount is a 100mm VESA pattern with fasteners included.

Inputs are sparse, with just two HDMI 2.0 and one DisplayPort 1.4. For 165 Hz operation, you must use DisplayPort. The HDMI inputs only go up to 100 Hz. If you’d like to use headphones instead of listening to the tiny two-watt internal speakers, a 3.5mm jack is provided.

OSD Features

The PG34WQ’s OSD is one of the most efficient I’ve ever seen, with just four sub-menus and only the most necessary features needed for high-performance gaming. Pressing the joystick brings it up. The keys take the user straight to the brightness slider or picture modes. Click the joystick left to change inputs or right to adjust the audio volume.

Tom's Hardware

The PG34WQ has six picture modes, all of which are fixed except the default Standard preset. That one allows adjustment of luminance and color temperature. The only thing missing from the calibration suite is gamma, which is unfortunate because this monitor looks and measures too light. Gamma is off by almost 10%, which makes the picture a bit washed out and lacking in saturation. DCR is an effective dynamic contrast option that enhances picture quality and has no apparent downside. I recommend using it for SDR content. It’s locked on for HDR. MPRT delivers a backlight strobe that reduces blur but causes a very visible phasing artifact.

The Image Setup menu lets you change aspect ratios, toggle the overdrive & Adaptive-Sync, and set HDR to Auto mode. The overdrive has just one setting, which didn’t make a difference. I saw slight black ghosting in test patterns, but most gaming content ran smoothly with minimal blur.

The Color Temp menu has four fixed options plus an adjustable user mode with RGB sliders. They can be used to dial in the PG34WQ precisely with accurate grayscale tracking. You can improve the image by selecting the sRGB setting if you don't calibrate. I’ll explain why below.

The final menu has an auto setting for the input selector, DDC/CI toggle, and a factory reset option. At the bottom is input signal information.

ASRock PG34WQ15R2B Calibration Settings

I discovered a few interesting things when calibrating the PG34WQ. In the default mode, the picture is cool, and gamma is light, reducing depth and color saturation. I calibrated the user color temp and saw a significant improvement without gamma presets. However, turning down the contrast slider from 50 to 35 increased static contrast, which shouldn’t happen, but my test results don’t lie. ASRock should add gamma options in a future firmware update for sure; this monitor sorely needs them. Here are the settings I used.

Picture Mode	Standard
Brightness 200 nits	51
Brightness 120 nits	18
Brightness 100 nits	11
Brightness 80 nits	3 (min. 73 nits)
Contrast	35
Color Temp User	Red 65, Green 54, Blue 43

If you don’t calibrate, I recommend setting the color temp to sRGB. This fixes the grayscale errors and improves gamma slightly. You can improve the image further by turning on DCR. Unlike most monitors, the PG34WQ makes good use of its field-dimming feature in SDR mode. The only downside to this approach is that the brightness slider is grayed out. Without DCR, peak brightness is around 150 nits. With DCR, it’s 210 nits.

HDR mode comes up automatically when an HDR10 signal is applied. Color accuracy is excellent there, with dynamic contrast of nearly 17,000:1. HDR content looks excellent here, better than most sub-$500 screens I’ve tested.

Gaming and Hands-on

Right off the bat, I enjoyed the PG34WQ’s ideal curvature. I’ve tried monitors ranging from 2300R to 1300R and in the 34-inch 21:9 size, 1500R is my favorite. There was no image distortion in apps like spreadsheets or word processors, but I felt a sense of immersion in games because I didn’t have to turn my head quite as far to keep peripheral objects in view.

I tried out a few different configurations to get the best possible SDR picture from the PG34WQ. The Standard picture mode out of the box is not the best choice. The light gamma and cool color temp put a damper on any sense of dimension. The detail was less sharp, and the color was less saturated.

My tests revealed a couple of fixes. The easy one is to set sRGB in the color temp menu and turn on DCR. That makes a huge difference with better detail and more color. The only downside is that brightness is fixed. You’ll see around 150 nits with DCR off and 210 nits with it on. I went for the latter in games but turned it off in Windows to quell the extra brightness when browsing the web.

The best choice is calibration, and if you don’t have the means, try my settings shown above. That allows you to dial in brightness to taste and delivers the best color of all. The gamut compromises between sRGB and DCI-P3 for all content, and ASRock did a good job here.

The PG34WQ’s strongest attribute is its HDR image quality. The DCR option is locked, which ups the contrast ratio to almost 17,000:1. Highlights are much brighter, almost 500 nits, which in turn pumps up color saturation and depth. In the sub-$500 category, this is one of the best HDR monitors I’ve seen.

Video processing options are basic, which is fine because they work. Overdrive can be on or off, but I didn’t see a difference either way. Blur is minimal, and on par with most other 165 Hz monitors I’ve tested. I saw some slight phasing in vertical lines, not frame tears since Adaptive-Sync works just fine. But there was an occasional doubling of thin lines as I panned quickly from side to side. It wasn’t a distraction, and my success in familiar games like Doom Eternal and Tomb Raider was equal to monitors with better overdrives.

MPRT, or backlight strobing, does not work well here. It cancels out Adaptive-Sync, which at 165 Hz is a questionable choice. It also causes phasing, like most monitors with the feature. I found it distracting, though it doesn’t reduce brightness too much. I still preferred to stick with AS and overdrive. And I had equal success with both FreeSync and G-Sync platforms.

Over my time with the PG34WQ, I found it capable in all areas, work and play. It performed comfortably above its price class with excellent HDR and a solid gaming experience.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To compare the PG34WQ’s performance, I’ve created a group that includes Monoprice’s 42772, AOC’s CU34G3S and MSI’s MPG343CQR to represent 165 Hz. BenQ’s EX3415R and EX3410R are here to cover 144 Hz, but you’ll soon see that 144 Hz isn’t necessarily a disadvantage.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

The BenQ EX3415R manages to draw a full white field in 6ms despite running at 144 Hz instead of 165 Hz. And it takes first place in the overall lag contest with 27ms. But the PG34WQ is close behind at 7 and 30ms. For all but a world-class player, that’s an imperceptible difference. The ASRock is quick to be sure. Its overdrive isn’t the best I’ve seen, but it delivers smoothness that’s on par with the competition. Gamers of average skill will see little difference in video processing performance between any of the six screens.

Viewing Angles

The PG34WQ looks better than most VA panels I’ve photographed at 45 degrees off-center. The image is dimmer and more washed out, but the color shift is only slightly to red. The vertical plane shows much of the same behavior with slightly less light output. Few people would want to share a 34-inch ultra-wide monitor, but if you do, an IPS model will serve better.

(Image credit: Tom's Hardware)

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

In general, VA panels have slightly weaker uniformity than IPS. You’ll see the occasional glow in one corner or a center hotspot. My PG34WQ sample had the former with a bit of extra light in the upper right. I could only see it in a full black field, not in actual content. There were no aberrations in color field patterns or neutral patterns of higher intensity.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

The PG34WQ hits about 305 nits in SDR mode, which is plenty of light for any work or gaming application in an indoor environment. There’s more output available for HDR content, nearly 500 nits, so the headroom is there.

The default black level is great compared to an IPS monitor but a bit below average among VA panels. That limits contrast to 2,219.3:1.

After Calibration to 200 nits

Tom's Hardware

Calibrating the RGB sliders and turning down the contrast slider from 50 to 35 makes a huge difference in image quality. I still wished for darker gamma, but the contrast increases to almost 3,100:1, which helps with depth and color saturation.

ANSI contrast stays consistent at 2,886.4:1, a solid result. Though the other VA monitors score higher in the contrast tests, the PG34WQ delivers decent quality. A darker gamma would move it up the rankings.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

The PG34WQ comes from the box in its Standard mode, which looks too cool and is a bit washed out overall. Luckily, it only takes a few tweaks to make things better.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

The PG34WQ’s white point is cool with visible blue errors from 30% and higher. It isn’t a huge problem, but there is room for improvement. Some adjustment is needed. Gamma is light at around 2.00, making the image a bit hazy.

Changing the color temp to sRGB makes a big difference. Now, there are no visible errors, while gamma remains the same. You can enjoy the PG34WQ this way, with the only limitation being that the brightness slider is grayed out. Peak output is around 150 nits, or 210 if you turn on DCR, which I recommend doing.

If you’d rather have finer control of brightness, calibrate the user color temp as I did. Then, you can set any output level you want and have the best possible grayscale tracking. There’s still no help for gamma, though. Regardless of your path, turn on DCR; you’ll be glad you did.

Comparisons

Tom's Hardware

The PG34WQ starts a bit down the order, but with calibration, it takes second place for grayscale accuracy. If you just select sRGB from the color temp options, it would finish fourth, still respectable.

In the gamma test, it tracks straight with a very narrow value range which is a good thing. But with an actual value of 1.99, it’s off the spec by almost 10%. ASRock, please add gamma presets to the OSD. It would make such a difference.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

When testing a monitor, I usually know going in its intended color gamut. Most of the latest screens use DCI-P3 and often advertise their coverage of that gamut on the box. The PG34WQ makes no such claims, but I can see that it is a DCI-P3 monitor. It takes a different approach than most to provide balanced color that works well for SDR content while still adding saturation.

The first chart above shows the default gamut when graphed against DCI-P3. Notice that inner points (20-80%) are under-saturated while the 100% target almost gets there. There’s a broader gap between 80 and 100% than the other points.

The second chart shows the same test graphed against sRGB. The inner points are closer to the targets now and indeed, the Delta E error is lower.

The third chart shows what happens when you select the sRGB color temp. The PG34WQ still hits most of DCI-P3, but the inner points are right on the sRGB spec (and the error is lower). This is the right choice for most users, as further calibration isn’t required.

The last chart shows the result of a grayscale calibration. It’s nearly identical to the sRGB-only chart. So, you get the same accuracy level but with adjustable brightness if you change the RGB sliders. Use my settings if you want to do this without instruments.

Comparisons

Tom's Hardware

The PG34WQ compares well in either sRGB mode or with calibration. With only the AOC showing slightly better numbers, this is excellent performance. I can’t fault the color accuracy here. And I like the concept of balance between sRGB and DCI-P3. It looks great with all types of content. The light gamma is a bummer but other than that, ASRock has done well.

The PG34WQ is about average for the category in the gamut volume calculation. For less than $500, you won’t find much more color than this. You’ll need a software profile to use any of these screens for color-critical applications. But for gaming, they all provide plenty of color.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

HDR is where the PG34WQ truly shines. It has effective dynamic contrast and accurate color that hits most targets in the DCI-P3 and Rec.2020 gamuts. Switching between SDR and HDR signals is automatic. You won’t find any adjustments for HDR content but as I discovered, they aren’t necessary.

HDR Brightness and Contrast

Tom's Hardware

ASRock’s website claims 550 nits peak, but the PG34WQ is rated for VESA DisplayHDR 400, and it comfortably exceeds that metric. At just under 500 nits, it’s plenty bright. With a best-in-group black level, it goes well beyond the HDR contrast capabilities of most budget screens with nearly 17,000:1. Only the MSI shows better. The Monoprice, BenQ and AOC monitors have no dynamic option, and it shows. ASRock has put its efforts into HDR here and it clearly pays off.

Grayscale, EOTF and Color

Portrait Displays Calman

The PG34WQ’s excellent HDR performance extends to color too. Grayscale tracking is without visual error. That’s a good thing since there are no adjustments available. The field dimming feature is a little too aggressive at the dark end of the scale, as you can see in the EOTF chart. Though shadow detail is still visible, it’s hard to see in the heat of battle. Users should tweak their in-game settings to compensate for this. In most areas of the picture, detail is solid and pops well. The tone-map transition point is spot-on at 65%.

In the color tests, the PG34WQ is reasonably close to the targets for DCI-P3 and Rec.2020. Saturation is very good and better than SDR, with no visible hue errors. This is an HDR monitor for sure and looks its best when showing that material.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Now that curved ultra-wide monitors have become a de facto standard for gaming, there are many product choices and that has translated to lower prices. What used to be a $1,000 purchase is now easy to find for less than $500, and that’s progress.

Another thing that is commonplace among budget screens is high refresh rates. While I am spoiled enough to consider 240 Hz a starting point, there is a lot of fun gaming to be had at 144 and 165 Hz. A wide variety of affordable hardware is available to power a monitor to 165fps at QHD and WQHD resolutions.

(Image credit: ASRock)

In this crowded market, the PG34WQ15R2B is an excellent first effort from ASRock. It delivers on its promises with solid performance, low input lag and accurate color. There is the light gamma issue which is something that could be fixed with a firmware update. But if you engage the sRGB color temp, or calibrate, and turn on DCR (dynamic contrast), the SDR image is pretty good. And its 1500R curve is ideal for any application.

HDR is the star with bright highlights approaching 500 nits and well-saturated color. HDR black levels are low, meaning almost 17,000:1 contrast, one of the best in class. The PG34WQ looks better in HDR mode than most of its budget-friendly competition.

Video processing is solid as well. Though the overdrive is a bit weak, it reduces blur enough for decent motion resolution. Adaptive-Sync works perfectly with either Nvidia or AMD hardware. And input lag is lower than average, making the PG34WQ a very capable gaming display.

At less than $500, it’s hard to find fault. I enjoyed my time playing and working with the PG34WQ. If you have a mid-tier gaming PC or console, it’s a great choice. Definitely check it out.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Corsair Xeneon Flex 45WQHD240 Bendable OLED Review: Curved or Flat, Your Choice

Christian Eberle — Tue, 07 Feb 2023 15:00:50 +0000

When OLED panels first arrived, bendability was one of their promised features. Theoretically, one could have a TV or monitor that could bend or roll up. LG demoed a rollable television at CES in 2020 that rises from a cabinet. It’s available today in a 65-inch size for an eye-watering $100,000. And, of course, we have foldable phones available for sale.

However, Corsair is the first company to introduce a bendable computer monitor. It eliminates the issue of choosing between a flat or curved panel. With the Xeneon Flex 45WQHD240, you can have both. At 45 inches wide, 21:9 aspect ratio, it’s the largest ultra-wide I’ve seen yet among the best gaming monitors. The bend goes to 800R, which is a very small radius. It also has serious gaming cred with 240 Hz, Adaptive-Sync, HDR and wide gamut color. Let’s take a look.

Corsair Xeneon Flex 45WQHD240 Specs

Panel Type / Backlight	OLED
Screen Size / Aspect Ratio	45 inches / 21:9
	Curve radius: flat to 800R
Max Resolution & Refresh Rate	3440x1440 @ 240 Hz
	G-Sync & FreeSync Certified
	48-240 Hz
Native Color Depth & Gamut	10-bit / DCI-P3
	HDR10
Response Time (GTG)	0.3ms
Brightness (mfr)	450 nits SDR
	1,000 nits HDR
Contrast (mfr)	1,500,000:1
Speakers	None
Video Inputs	1x DisplayPort 1.4
	2x HDMI 2.1, 1x USB-C
Audio	3.5mm headphone output
USB 3.1	1x up (type C), 4x down
Power Consumption	61.5w, brightness @ maximum
Panel Dimensions (flat)	41.7 x 22.5 x 12.4 inches
WxHxD w/base	(1059 x 572 x 315mm)
Panel Thickness	0.2 inches (6mm)
Bezel Width	0.4 inch (10mm)
Weight	13.9 pounds (6.3kg)
Warranty	3 years zero dead pixel
	3 years zero burn-in

In the world of unique computer monitors, the Xeneon Flex is a standout. As an OLED, it joins a small and elite group of displays with fantastic contrast and rich color. The Flex has the same infinite dynamic range as other OLEDs I’ve reviewed and covers slightly under 100% of the DCI-P3 color gamut. With a few tweaks, it delivers reference-level accuracy and also offers a usable sRGB mode.

Though OLEDs aren’t known for high brightness, the Flex can hit 1,000 nits in HDR mode when showing small highlights. SDR brightness is lower, as is appropriate. In my tests, a 25% window measured around 437 nits, which is respectable.

Gaming cred comes courtesy of a 240 Hz refresh rate with Adaptive Sync. The Flex is certified by Nvidia and AMD for both G-Sync and FreeSync Premium operating over a 48-240 Hz range. It also has extremely low input lag. In my tests, it proved to be quicker than other 240 Hz monitors by a comfortable margin.

The big story is the bend, of course. The Flex is the first, and for the moment only, bendable computer monitor available. You can leave it flat and enjoy a vast screen perfect for productivity. Or you can bend it as tightly as 800R for immersive gaming. You can leave it anywhere between those extremes or just bend one side. It is, effectively, several monitors in one. The bend is accomplished manually with two handles that extend from the sides.

According to Corsair, the life cycle of the Flex is at least 10,000 bends, which in theory, would take many years to achieve. The warranty is three years for both zero dead pixels and zero burn-in. Pixel orbiting and refresh features are included to maintain the panel’s health while in standby mode.

There’s a lot to see here, so let’s get unpacking.

Assembly and Accessories

The Flex is a one-unit display with an integrated stand. There’s no assembly required, nor can you remove the stand since it incorporates both inputs and controls. The box is a lift-off style, like a TV, that protects the contents with blocks of crumbly foam. A beefy 240-watt power supply and DisplayPort, HDMI, USB A-C and USB C-C are included.

Product 360

Corsair

Tom's Hardware

Corsair

The Flex is an impressive sight once you find a spot big enough for it. Some room on the sides is required to fit the handles that slide out when you want to bend or unbend. My initial reaction was a bit fearful because it’s hard to wrap one’s mind around bending a computer monitor. The panel is only 6mm thick, but it has a prominent component bulge in the back and two stabilizing arms that manage the bending action. To bend, simply pull the handles. You can bend only one side if you wish. An audible click sounds when you’ve reached the limit of 800R. The Flex is so large that its maximum bend is just about right for gaming from a three- to four-foot viewing distance.

The build quality is certainly premium, with a solid metal base over a foot deep. Stability is not an issue. A bit of texturing adorns the back of the upright, which is quite wide. A metal handle sits at the bottom center, which is handy for tilting the screen. It comes forward seven degrees or back 15. There is no swivel or height adjustment.

WQHD resolution, or 3440x1440, is more commonly seen in 34-inch screens. At 45 inches diagonal, the Flex gives up some pixel density. The 83ppi is less than the more familiar 109ppi one sees in a 34-inch ultra-wide or a 27-inch 16:9 QHD panel. This means you don’t want to sit too close lest you see the pixel structure. The screen surface is also unusual for an OLED because it’s matte. Most are very shiny and easily show reflections, but the Flex bucks this trend.

The Flex’s panel and stand are a single unit that cannot be disassembled. The controls are on the front beneath the screen and include an input selector, power toggle with LED, and a joystick for menu control. Two USB ports and a headphone jack are also provided, which is very convenient. There are no built-in speakers. In the back, there are two HDMI 2.1 inputs, a DisplayPort 1.4, a USB-C video and a second USB-C for peripherals. The screen sits a little low for me to get it perfectly vertical without a small stand underneath.

OSD Features

The OSD is completely text-based, with just a small Corsair graphic in the upper left corner. Pressing the joystick summons the menu. You can also go right to the input selector with a press of the Input key or a right click. Up selects brightness, Left adjusts volume, Down is image mode and Right is input.

Tom's Hardware

The Flex has six image presets, including Standard, which can be calibrated using the DCI-P3 gamut and sRGB, which employs the smaller color space. Unlike most monitors, the Flex’s sRGB mode can be independently calibrated, which is great for professionals who need reference quality for both color standards. You also get three color temperature presets, a custom mode, and three gamma options. Refresh Overlay is a frame counter, and you can create your own aiming point with different shape combinations shown in the second photo above.

A monitor this large is perfect for PIP and PBP functions, which allow viewing two sources at once. The Flex can easily replace two monitors with its vast screen area.

System Setting lets you toggle Adaptive-Sync on and off and manage the panel maintenance options. A pixel orbiter shifts the image up and down to prevent burn-in. You’ll never notice it in action. I stared at the screen for quite a while and could barely see anything happening. The Refresh option works while the Flex is in standby mode. Corsair warrants the Flex for three years against burn-in, so it is confident in these features. In my own experience, I have seen no burn-in on my two-year-old LG OLED TV.

Corsair Xeneon Flex 45WQHD240 Calibration Settings

The Flex has a factory-certified calibration, but I found some improvement with adjustments. The RGB sliders work precisely and allowed me to calibrate the Standard and sRGB modes separately. I could then switch back and forth between them at will. Gamma and color tracking were very good out of the box. I’ve provided my settings below.

There are no adjustments in HDR mode, but I found solid grayscale tracking there with good color saturation.

Picture Mode	Standard - sRGB
Brightness 180 nits (Full field)	100
Contrast	50
Gamma	2.2
Color Temp User	Standard - Red 100, Green 98, Blue 85
	sRGB - Red 92, Green 94, Blue 100

Gaming and Hands-on

It’s hard to experience a monitor like the Flex and not lapse into an adjective stream where I spend hours coming up with ways to describe it in as many words as possible. Rather than bore you with that, I’ll just say that there’s absolutely nothing like it.

First is the size. I’ve reviewed lots of ultra-wide monitors. Most are 34 inches diagonal and provide a decent wrap around the viewpoint. 49-inch mega wides wrap more but lack height which can take the user a bit out of the experience. The Flex, with its 45-inch screen and 800R curve at full bend, takes immersion to another level. Nothing else can compare, nothing.

As far as bend versus flat, I found myself going back and forth a few times, then settling on bent. Most of my work happens in the center of the screen, so the bend isn’t distracting when editing a Word document. For spreadsheet tasks, it’s nice to see all the numbers without too much scrolling. Graphics editing is best with a flat screen. Then you can properly judge proportion and perspective. The Windows desktop was bright and vivid in the Standard picture mode with true blacks and bright but not harsh highlights. I turned down the brightness to 75% at night, but l left it at 100% during the day.

The Flex’s gaming prowess is tremendous. Input lag is low enough to be imperceptible. Screen response is free of any visible blur. Precision movement is this monitor’s forte. Wading through monsters in Doom Eternal’s horde mode was an addictive experience. I literally could not stop playing until my chihuahua finally demanded her dinner. The Flex drew me in completely. You will need to keep a timer or alarm clock handy to remind you when it’s time to eat.

And like other OLED panels, it plays more smoothly at lesser frame rates. I saw around 160fps in Call of Duty WWII, but it was as good or better than an LCD running over 200fps. Of course, the image was stunning with its rich color, true blacks and deep contrast. Though pixel density is relatively low, the picture’s dynamic range erases any perception of pixel structure.

The Flex is one of the very best gaming monitors I’ve experienced. It fits my skill level and style of play which is casual at best. It will appeal to a wide variety of players of all abilities right up to competition professionals.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To compare the Flex’s performance, I’ve included two OLEDs, the Alienware AW3423DWF and Aorus FO48U. The remaining screens are VA panels, AOC CU34G3S, Samsung G8 and Monoprice 42772.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

I included the G8 because it is one of the few speedy VA panels available, and it has contrast and performance on par with the Flex. It and the Corsair can draw a full white field in 4ms thanks to their 240 Hz refresh rates. Observing BlurBusters test patterns show equal smoothness in horizontal movement. The Flex doesn’t need an overdrive to accomplish this and the G8 has a perfectly implemented one. The gaming feel will be equivalent between these two monitors.

In the input lag test, the Alienware sneaks into second place thanks to its snappy OLED screen. The Flex, however, is one of the fastest monitors I’ve tested. Only a 360 Hz screen will be quicker. In practice, it is incredibly responsive and smooth. No matter how rapidly I moved the mouse, the picture never blurred, nor were there any artifacts. The Flex is easily qualified for esports or competitive gameplay.

Viewing Angles

(Image credit: Tom's Hardware)

OLEDs have a considerable advantage over LCDs because their polarizing layer is much thinner when viewed off-axis. The Flex looks the same at 45 degrees horizontal as it does head-on. This is a very shareable monitor, especially if you employ the PBP function. It is almost equal to two 32-inch 16:9 panels in total area. From the top, the image looks a bit green and washed out.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

I have no complaints about the Flex’s screen uniformity. I had to display a 10% brightness pattern to measure it properly. Black field patterns are too dark to be detected by my instruments. The Flex’s uniformity is visually and measurably perfect in every way.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

The Flex varies its brightness depending on the average luminance of the image. That means a full white field will measure around 180 nits. As the window gets smaller, the brightness goes up. I measured a 25% window to get 437 nits. At 3%, the Flex tops 1,000 nits.

Since the black level can’t be measured, OLED contrast is theoretically infinite. The G8 has a zone-dimming backlight that can’t be turned off, hence its high contrast score.

After Calibration to 200 nits

Tom's Hardware

Deciding on a peak output level for the Flex required some trial and error. On the maximum setting, a full field was only 180 nits, as I stated earlier. Setting a 25% window to 200 nits made the image too dark. My room is sunlit, so I can run high brightness without visual fatigue. I eventually settled on the maximum brightness setting as my preference. Your mileage will vary depending on your viewing environment.

With unmeasurable black levels still in play, the Flex’s static and ANSI contrast ratios cannot be determined.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

The Flex ships with a calibration data sheet for each sample. I noticed that mine was calibrated to 8500K, which is cooler than the typical standard of 6500K. It is simple to adjust the Standard and sRGB picture modes to the correct specs.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

Standard is the mode to pick if you want the Flex’s full-color capability. It covers almost 100% of DCI-P3, so I expect most users will go that route. The default grayscale is visibly cool with blue errors from 40 to 100% brightness. Gamma tracks almost perfectly except for a tiny rise at 90%, which only the meter can see. Calibration sets the white point to the correct 6500K with all errors below 1dE.

In sRGB mode, the white point is warm in tone with visible errors between 40 and 100% brightness. Gamma tracks well except for the 10% step, which is slightly light in tone. Calibration gets the error below 1dE and lightens gamma a bit across the range. In practice, shadow areas occasionally look a tad light, but this is a minor issue.

Overall grayscale and gamma performance in both Standard and sRGB modes is excellent.

Tom's Hardware

The Flex’s default grayscale error of 4.62dE is due to its factory calibration to 8500K rather than 6500K. The other monitors can be used without calibration, but the Flex should be adjusted for the best possible picture. Once completed, it rises to second place here and is equal in quality to any professional screen.

In all cases, gamma tracking is nearly perfect, with a miniscule 0.07 range of values and average tracking just 0.45% off the 2.2 standard. The actual value was 2.19. It doesn’t get much better than that.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

The Flex has superb color coverage in Standard mode and out of the box; it just needs some tweaking to its secondary hues. This is accomplished by grayscale calibration, which takes color gamut accuracy to the reference level. Unlike most wide-gamut LCDs, the Flex has a fully saturated green primary.

sRGB mode exhibits similar behavior but is closer to the mark before calibration. After grayscale calibration, it’s even better, with one of the lowest error levels I’ve recorded for any monitor’s sRGB mode. This is excellent performance.

Comparisons

Tom's Hardware

Clearly, the OLEDs here have a color accuracy advantage. This is partly due to their superior gamut volume, which covers the entire green primary in all three cases. That the Flex is in third place with a volume score of almost 100% speaks volumes about the technology. The bit of extra volume in the sRGB test is from some bonus green. The Flex can easily be used for color-critical applications without a software profile.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

The Flex supports HDR10 signals with an automatic switchover into HDR mode. There are no picture adjustments available, but I found decent grayscale accuracy.

HDR Brightness and Contrast

Tom's Hardware

I had to measure a 3% window to see a peak number over 1,000 nits that Corsair promises. I had to do the same thing when measuring the Samsung. The other two OLEDs don’t vary brightness with picture level and therefore top out at around 400 nits. The Flex has superb HDR contrast with the expected unmeasurable black level and infinite contrast ratio.

Grayscale, EOTF and Color

Portrait Displays Calman

In the HDR grayscale test, I observed no visible errors with all values under 2dE. This is well above average performance for HDR monitors as a whole. The EOTF tracks too light until its tone-map transition point at 55%. I measured both window and field patterns and got the same result.

In the color tests, red measured a bit over-saturated but hit the 100% mark for DCI-P3 color, which many wide gamut monitors cannot do. Green and blue also filled their volume targets with linear saturation tracking. Hues are slightly off the mark for some colors. Red looks slightly orange, as does yellow. Cyan drifts toward green, while magenta is a bit too red. In practice, this makes colors look somewhat muted. There’s plenty of vibrance, but warm tones look slightly unnatural. The Rec.2020 chart shows similar behavior, but since saturation targets track evenly, you’ll see more vivid hues until the display runs out of color at around 80%.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

OLED technology has come a long way since it was first introduced. Early panels suffered from various teething problems and were very expensive. But today, there are some truly compelling choices available at more affordable prices.

A bendable screen could be considered the answer to an unasked question, but many thought the same thing when curved displays first appeared. Now, curved monitors are everywhere and are a top choice for gaming enthusiasts and professionals. Corsair has combined the best parts of flat and curved panels into a single monitor.

(Image credit: Corsair)

The Xeneon Flex 45WQHD240 represents multiple displays in a single chassis. For graphics work and productivity, it’s a huge flat panel with nearly the same area as two 32-inch 16:9 screens. High color accuracy and contrast make it ideal for creatives and number-crunchers alike.

Gamers can grab the handles and bend the screen to an ideal 800R curvature. With so much width and height available, the image truly envelopes the user. Video processing is equal to the very best screens with 240 Hz, perfect Adaptive-Sync and smoother motion than an equivalent LCD monitor. It also has lower input lag than nearly every 240 Hz display I’ve reviewed. The Flex is equally well-suited for casual gamers or esports pros. The only flaw here is HDR color which was a little off-hue mark in both real-world content and in testing.

The Corsair Xeneon Flex is one of the very best gaming monitors I’ve ever reviewed. At an initial price of $1,999, it’s a premium purchase, but once you’ve tried it, you won’t care about that. Its addictive gameplay and gorgeous screen are simply unmatched by anything else.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

AOC CU34G3S 34-inch Curved Gaming Monitor Review: High Contrast, Colorful and Capable

Christian Eberle — Sat, 19 Nov 2022 13:00:03 +0000

There are plenty of gently curved monitors available for people who don’t want an extreme wraparound effect. Since radii tighter than about 1300R can produce image distortion, that’s understandable. But for hardcore gamers who want to replicate VR goggles without hanging a bunch of bulky tech on their heads, 1000R ultra-wide screens do an excellent job of filling one’s peripheral vision and surrounding the player with the virtual environment.

The AOC CU34G3S is one such monitor. It features a 34 inches diagonal with a VA panel that delivers over 3,000:1 contrast. It has HDR and wide gamut color for a punchy and realistic image. In addition, gaming performance is enhanced with Adaptive-Sync and a 165 Hz refresh rate. The best part is the price – just $430 at this writing – makes it a great contender to join the ranks of the best gaming monitors.

AOC CU34G3S Specs

Panel Type / Backlight	VA / W-LED, edge array
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve radius: 1000mm
Max Resolution & Refresh Rate	3440x1440 @ 165 Hz
	FreeSync: 48-165 Hz
	G-Sync Compatible
Native Color Depth & Gamut	8-bit / DCI-P3
Response Time (GTG)	4ms
Brightness (mfr)	300 nits
Contrast (mfr)	3,000:1
Speakers	2x 5w
Video Inputs	2x DisplayPort 1.2
	2x HDMI 2.0
Audio	3.5mm headphone output
USB 3.2	1x up, 4x down
Power Consumption	48w, brightness @ 200 nits
Panel Dimensions WxHxD w/base	31.3 x 15.8-20.9 x 13.4 inches (795 x 402-532 x 340mm)
Panel Thickness	5.2 inches (133mm)
Bezel Width	Top/sides: 0.3 inch (8mm)
	Bottom: 0.9 inch (22mm)
Weight	18.3 pounds (8.3kg)
Warranty	3 years

With a high contrast VA panel, the CU34G3S brings plenty of dynamic range to the party. Though it doesn’t have a dimming feature for HDR, it still has more image depth than any IPS panel can boast. Vivid color is assured by a wide gamut that covers nearly 87% of DCI-P3. And for purists, there’s an accurate sRGB mode hidden in the color temp options. The color is quite accurate, and I found no need for calibration in either mode.

To keep games running smoothly, AOC includes both flavors of Adaptive-Sync. AMD FreeSync is the native tech, operating over a 48 to 165 Hz range. Nvidia G-Sync works fine, as confirmed by my tests, although the CU34G3S has not been certified by Nvidia. For play aids, you get an aiming point, frame counter and a backlight strobe for blur reduction if you prefer that instead of Adaptive-Sync. Also included is an effective three-level overdrive.

AOC has left out LED lighting, which doesn’t detract from the CU34G3S’s functionality. There are internal speakers and a plethora of USB 3.2 ports, one upstream and four down, to support your peripherals. With a solid and adjustable stand completing the package, this looks like a good deal for users looking to curve their images to the max.

Assembly and Accessories

The CU34G3S comes well-protected in a large carton with its three pieces surrounded by crumbly foam. After mating the base and upright using a captive bolt, the panel snaps in place. Under the attachment point is a 100 mm VESA mount that works with aftermarket arms and brackets. Bundled cables include HDMI and DisplayPort but not USB. The power supply is internal though unusually, the interface is IEC C5-6, commonly seen in power bricks. This is a first for me; I’m more accustomed to seeing IEC C13-14. No matter, with everything hooked up, the CU34G3S worked just fine.

Product 360

AOC

A thin flush bezel surrounds the image with an eight-millimeter border around the top and sides and 22 mm across the bottom. Red trim is featured here and on the base’s cable hole. There’s more red on the back where they offset the stand and the small grills on either side. The AOC logo is displayed on the front and back in silver. The base is also silver in color with a matte finish. It looks like solid metal but is actually a plastic shell over a cast metal core.

The stand is a solid piece with -5/22 degrees tilt, 30 degrees swivel and a 130 mm height adjustment. Movements are firm, but there is some wobble where the panel attaches to the stand. The screen may shake a bit if you pound on your desk while playing.

The side view shows how the component bulge is angled upwards so you can easily access the USB ports. They’re on the side opposite the one in the photo above. The inputs are closer to center and include two DisplayPort 1.4 and two HDMI 2.0. You also get a 3.5 mm headphone jack. The control buttons are also visible here, a power key plus four controls for menu navigation. The internal speakers boast five watts of power and do indeed play loudly. Distortion is minimal, but there isn’t much in the way of bass or lower midrange frequencies. Players who want good sound are better served by headphones plugged into the 3.5 mm audio jack.

OSD Features

The CU34G3S has four buttons to navigate the OSD rather than a joystick. It’s a bit old-school by today’s standards, but it gets the job done. The menu is AOC’s familiar ribbon-style graphic that appears in the bottom center of the screen.

Tom's Hardware

The seven sub-menus begin with Luminance, including brightness & contrast, plus gamma, dynamic contrast (SDR only) and the HDR modes. There are also eight picture modes, called Eco, focused on specific tasks or game types. Standard is the best place to be and is also the default mode. Coupled with the Game modes detailed below, changing Eco modes can be confusing. And as it turns out, there’s no benefit to tweaking the CU34G3S’s image settings. There is no improvement to be found by calibration, but luckily, the default image is quite accurate.

In Color Setup, you can choose between five presets, one of which is sRGB. This is the way to go if you prefer the correct setting for SDR content. Other options use the monitor’s full native gamut, which covers 87% of DCI-P3. The default option, Warm, is very accurate and cannot be improved.

Picture Boost is unique to AOC monitors. It lets the user create a frame in the center of the screen that’s brighter or dimmer than the surrounding image. Within the frame, you can adjust brightness and contrast along with size and position. Hidden in the OSD Setting menu, you’ll find a DisplayPort version option and a break reminder setting.

Ultra-wide displays are great for viewing multiple sources, and the CU34G3S lets you have two images up simultaneously. It’s picture-in-picture, so you can size the secondary window and change its position.

In Game Setting, you can choose between multiple game modes which alter image and video processing parameters. They get confusing when combined with the Eco modes. I suggest leaving Game Mode off and setting the overdrive to your preference. Strong works fine with no ghosting, but I saw a slight black trail behind moving objects in test patterns, a symptom of undershoot. You can turn on a frame counter here and set up a backlight strobe too. It has 20 levels which provide more blur reduction as the picture darkens.

AOC CU34G3S Setup and Calibration

The CU34G3S is quite accurate out of the box in its Standard mode and Warm color temp with Game Mode turned off. Trying various settings, including the User color temp, produced no gains in performance. It is best to leave the monitor on its default settings and set brightness to taste. I’ve provided the settings for commonly used levels below. If you want the sRGB color gamut, there’s an option for SDR content among the color temp settings. It renders that smaller gamut to near perfection.

In HDR mode, the default option is DisplayHDR which comes closest to the mark. Other settings include Game, Picture and Movie. Those three add edge enhancement which reduces picture quality. Stick with DisplayHDR for the best image with HDR content.

Brightness Settings

200 – 91
120 – 45
100 – 31
80 – 18 (min. 54 nits)

Gaming and Hands-on

If you’ve never used a curved monitor, or the one you’ve been using is gently curved, it would be wise for you to check out a 1000R ultra-wide screen before committing. This is the tightest curve currently available, and it is extreme. Thanks to that tight curve, spreadsheets and text documents will have a pincushion effect. It’s unavoidable, but it isn’t necessarily a problem. Once you get used to it, you’ll barely notice it unless you have flat screens nearby. And that’s another consideration. If you plan to have multiple monitors, they all should have the same curve and size. Three CU34G3S’s make an excellent cockpit for driving and flight simulators. Two screens are ideal for first-person shooters.

Shape aside, the CU34G3S provides plenty of screen area for work. Putting windows side by side is a natural state of affairs, as you’re essentially looking at two 27-inch QHD monitors. Pixel density is the same at 109 ppi, so the image will have the same sharpness.

Color and contrast are pleasing, with true blacks and sharp delineation of dark objects against light backgrounds. Black text on a white field renders cleanly without visible jaggies or anti-aliasing. Just avoid the additional HDR modes if you use HDR in Windows. Only DisplayHDR shows without edge enhancement.

Gaming proved to be an extreme pleasure. The CU34G3S has balanced performance with smooth motion and very low input lag. Though it didn’t blow my tests away (it was solidly average in response and lag scores), it matched my play rhythm with no perceivable lag and no loss of detail in fast-moving sequences. I always go straight to Doom Eternal’s Horde Mode and in this case, I ripped through the first few arenas in seemingly record time. The extra peripheral information certainly helped, and having it closer to my eye was a plus.

Games where I had more time to explore the environment, like Tomb Raider, further showed the value of a 21:9 screen. There is no better way to game than with an ultra-wide. The best 16:9 panel can’t match the extra width and the AOC’s tight curve accentuates the effect.

If you’re willing to accommodate some image distortion in workday tasks, it’s hard to top the gameplay experience offered by a monitor like the CU34G3S.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

All monitors in this comparison group are 34-inch ultra-wide screens, mostly VA, with one IPS panel. In addition to the CU34G3S, we have Cooler Master’s GM34-CW, BenQ’s EX3415R and EX3410R, and the Monoprice 42772. Speeds are either 144 or 165 Hz.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

Higher refresh rates deliver smoother motion and lower input lag. But for most players, smoothness is the thing that most impacts the experience. 144 and 165 Hz deliver roughly the same look to the moving image. The top two panels will be slightly better at keeping motion resolution high. But all the displays look solid as long as frame rates stay high. The AOC has the same panel response as most 144 Hz monitors.

In the input lag test, the CU34G3S is in last place with a 32 ms total score. This performance is by no means poor, as anyone with moderate to good skills will find the monitor snappy and eager to play. The top three monitors are over-achievers with low lag despite their 144 Hz maximums. However, the 165 Hz screens aren’t far behind. Again, it comes down to frame rates. If your system can keep the action at 140 fps or higher, you’ll enjoy a great play experience. Professional players may prefer the lower input lag, however.

Viewing Angles

(Image credit: Tom's Hardware)

The CU34G3S’s viewing angles are weakened by its extreme curve and VA panel. The green shift I usually see from VA monitors is there and brightness drops by around 40%. Though there is plenty of width here, I don’t recommend sharing. The curve would distort the image for anyone not sitting at the center. The top view is equally poor, with the same green shift and light reduction. On the upside, detail remains visible in the brightest and darkest parts of the image.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

My CU34G3S sample showed very good uniformity except for slightly visible hotspots in the upper left and lower right corners. These issues couldn’t be seen in anything but a black field pattern. Shadowed areas in graphical content looked smooth-toned. Color and white uniformity were visually perfect.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

AOC rates the CU34G3S at 300 nits, but I could not find that value in any of the Eco or game modes. This isn’t the brightest monitor out there, but it is bright enough. Large screens like this don’t need a ton of light output for SDR content. The only bummer is that there isn’t any more brightness for HDR material.

With deep blacks, the CU34G3S delivers excellent contrast of over 3,300:1. That’s good enough for third place here though, in the larger picture, it is higher than average among all the VA panels I’ve tested.

After Calibration to 200 nits

Tom's Hardware

I didn’t calibrate the CU34G3S; a change in brightness to 200 nits was the only adjustment I made. The other monitors had their RGB sliders tweaked to remove grayscale errors. That slightly levels the playing field but still puts the AOC in a strong position. Obviously, the IPS-based BenQ is at a disadvantage here.

The CU34G3S’s ANSI contrast score stays over 3,100:1, which is excellent performance. Though it is a value-priced display, it doesn’t skimp on component selection or quality control. The image has lots of depth, true blacks with strong highlight and shadow detail, and well-saturated color.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

The CU34G3S is one of the few monitors I could not improve with calibration. That is of little matter because it’s spot-on out of the box.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Portrait Displays Calman

The default Eco mode is Standard with Game mode turned off. That delivers grayscale tracking that’s nearly perfect. Only two tiny errors at 90 and 100% can be seen in test patterns. You’re unlikely to see an issue in actual content. Gamma is also a tad dark at the 80 and 90% levels, but this too is a tiny error. I attempted to calibrate the User color temp but had no success. It’s best to just leave the preset on Warm with Gamma 1 and set brightness to your preference.

The CU34G3S is a rare gaming monitor with an accurate sRGB mode. You’ll find it hidden in the color temp options. It leaves the Brightness control available, which is also a rarity. If you’re a color purist and want the correct gamut for SDR content, that is the option to choose. It has no visual errors and only a dip in gamma at 10% brightness to mar an otherwise perfect chart.

Comparisons

(Image credit: Tom's Hardware)

The CU34G3S wins the out-of-box contest with a 1.73dE score. That’s definitely above average for the category. Since I couldn’t improve that performance, it slipped to fifth place. However, none of the displays have visual grayscale errors, so the comparison is a wash. All the screens perform well.

Gamma tracking is mid-pack with a reasonably small 0.18 range of values and a 2.27% deviation from spec. The actual gamma value is 2.25.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

The CU34G3S’s color gamut accuracy is exemplary. It’s visually without error and only shows a slight red under-saturation in the chart. Green is also a tad under, typical of all wide gamut screens. While the monitor doesn’t cover the entire DCI-P3 gamut, it comes close.

The sRGB gamut is worthy of a professional display. There are no visual errors, and every point is no more than 1.5dE off its target. With a 1.35dE average, it doesn’t get much better. Remember that to use the sRGB option, select it in the color temp menu.

Comparisons

Tom's Hardware

Noting that all the other monitors are calibrated makes the CU34G3S’s performance more impressive. Plenty of displays can’t hit 2.10dE with adjustment. That AOC delivers it out of the box just adds to its value quotient.

In the volume calculation, the CU34G3S is about average for the category, covering almost 87% of DCI-P3. Green is the main weakness, typical of the genre. The Cooler Master and Monoprice definitely have more visible color, but they don’t have sRGB modes. The AOC covers both equally well.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

The CU34G3S supports HDR10 content with four HDR modes. The default is DisplayHDR, which follows the standard more closely than the others. The remaining ones are Movie, Game and Picture. However, they were a non-starter for me because they added edge enhancement. All this does is reduce resolution; it does not make the image sharper.

HDR Brightness and Contrast

Tom's Hardware

The CU34G3S leaves some performance under the table in two areas. First, there is no more brightness available in HDR mode. It tops out at around the same 234-241 nits. Second, there is no dynamic dimming feature. SDR content gets a dynamic contrast option, but that setting is grayed out in HDR mode. Though the VA panel manages almost 3,400:1 contrast, it could be much better with a dimming option. Though I found that HDR content looked vivid and saturated, it didn’t look much different than SDR.

Grayscale, EOTF and Color

Portrait Displays Calman

The CU34G3S retains its color accuracy in HDR mode. There are slight blue errors in the brighter steps, but these issues don’t impact actual content much at all. The EOTF curve shows a gradual transition to tone mapping, meaning some highlights will be a tad muted. Again, this is a minor error. The other HDR modes aren’t as precise with their luminance tracking which in practice, obscures some detail. DisplayHDR is the best choice.

HDR color tracking is quite good with just a slight under-saturation in red and magenta. The saturation points are arranged linearly so the picture is loaded with detail. For Rec.2020 mastered content, the CU34G3S tries to match the saturation points but comes up a bit short. This contributes to the observation that SDR and HDR look similar. There is some untapped potential here, but HDR performance is adequate.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

With so many different kinds of gaming monitors available, it can be hard to choose. There is no single category that gets everything right. And there is user preference to consider. What works for one player may not work for another.

After trying monitors in every conceivable shape, size, speed and resolution, I can say that curved screens are the most fun for me. They provide a great view of the action, and most have balanced performance and quick response. So, if you’ve decided you want a curved display, the question becomes, "how curved should it be?"

(Image credit: Tom's Hardware)

The curviest screens are 1000R or 1000 mm radius like the AOC CU34G3S. In the 21:9 aspect ratio, this gives you the most impactful wraparound effect. Aside from VR goggles, you’re not going to find a more immersive experience. Luckily, the CU34G3S delivers a lot of features and performance for a relatively low price.

With color that’s visually perfect out of the box, no tweaking is needed. That is good since I could not improve the picture with calibration. The VA panel delivers over 3,100:1 contrast which is about triple that of the average IPS screen. That’s a lot of dynamic range with really deep and realistic blacks. The wide color gamut is a great asset as well. You can use the CU34G3S’s nearly 87% coverage of DCI-P3 for all content or switch on the very accurate sRGB mode if you wish.

I found the video processing to be equally impressive. With WQHD resolution and 165 Hz, I was able to max the frame rates and enjoy super smooth movement with no blur and very fast control response. Though there are some monitors that are slightly quicker like the Cooler Master GM34-CW, the visual difference is pretty small. I spent many hours playing games on the CU34G3S and enjoyed every minute.

At this writing, the AOC CU34G3S is selling for around $430. That’s a great value considering its feature set and performance. And those things are wrapped up in a great-looking screen with an immersive feel. If you’re looking to take your curve to the max, definitely check it out.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Alienware AW3423DWF QD-OLED Gaming Monitor Review: Contrast and Color for Days

Christian Eberle — Mon, 14 Nov 2022 22:51:14 +0000

When they first arrived on the scene, OLED panels were something of a unicorn. The technology was proven, but low manufacturing yields kept them from entering the consumer mainstream. OLED panels are still a premium product today, but prices have come down to a more approachable level. OLED phones are commonplace, but desktop monitors are not. You can buy a 48-inch screen like Aorus’ FO48U, but is that truly a desktop display?

Alienware has fulfilled a need with its AW3423DFW 34-inch ultra-wide curved OLED monitor. In addition to a 1800R curvature, it sports 3440x1440 (WQHD) resolution, 165 Hz, Adaptive-Sync, HDR with 1,000 nits peak and a wide color gamut. At this writing, it’s selling for around $1,100 but you might be able to get it for less with an Alienware coupon.

Alienware AW3423DWF Specs

Panel Type / Backlight	Quantum Dot
	Organic Light-Emitting Diode (QD-OLED)
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve radius: 1800mm
Max Resolution & Refresh Rate	3440x1440 @ 165 Hz
	FreeSync: 48-165 Hz
	G-Sync Compatible
Native Color Depth & Gamut	10-bit / DCI-P3
	HDR10, DisplayHDR 400
Response Time (GTG)	0.5ms
Brightness (mfr)	250 nits SDR
	1,000 nits HDR
Contrast (mfr)	1,000,000:1
Speakers	None
Video Inputs	2x DisplayPort 1.4
	1x HDMI 2.0
Audio	3.5mm headphone output
USB 3.2	1x up, 4x down
Power Consumption	40.7w, brightness @ 200 nits
Panel Dimensions	32.1 x 16.4-20.7 x 14.3 inches
WxHxD w/base	(815 x 417-527 x 240mm)
Panel Thickness	5 inches (127mm)
Bezel Width	Top/sides: 0.4 inch (9mm)
	Bottom: 0.7 inch (17mm)
Weight	20.5 pounds (9.3kg)
Warranty	3 years

The AW3423DFW introduces a new OLED variant to the mix, QD-OLED, where the QD stands for Quantum Dot. You’ve likely heard of that tech associated with LCD panels. Quantum Dots are dots made from a light-emitting substance printed on a layer of film. It can be placed over the backlight of an LCD or sandwiched in front of an OLED array. When the dots are excited by light energy, they emit their own colors. This widens the display’s color gamut and increases its total light output. The result is a good thing for OLED, because it has lagged behind LCD in the peak output metric for years.

The AW3423DFW has a bit more color than the average OLED panel. Where most cover between 90 and 95% of DCI-P3, the Alienware AW3423DFW fills over 107%. It also delivers plenty of brightness. In HDR mode, it can hit 1,000 nits when rendering small highlights. It’s far brighter than the 55-inch AW5520QF I reviewed in 2019. More light means greater dynamic range. OLED panels already deliver the blackest blacks of any display technology. A higher peak number just means an even better picture.

The AW3423DWF’s gaming performance received equal attention. The max refresh rate is 165 Hz, and both AMD FreeSync and Nvidia G-Sync are supported. It also sports a claimed 0.1 ms response time. My measurements showed the same performance as other 165 Hz screens, but during practical observation, I noted that it looked smoother than an LCD panel running at the same speed. It’s visually comparable to a 240 Hz display, which means it’s making more of the same frame rate.

Of course, the curvature and the 21:9 aspect ratio also enhance the gaming experience. An 1800R radius strikes a good balance between immersion, of which there is plenty, and image distortion, of which there is none. The AW3423DWF is as well suited for work as it is for entertainment. Some gamers will appreciate the AlienVision feature that highlights the center of the screen for sniping. In addition, photographers will appreciate its color accuracy, which is factory certified. During my tests, I found no need for calibration. And there is a Creator mode, which lets the user choose between DCI-P3 and sRGB color gamuts.

Assembly and Accessories

Alienware, like its parent company Dell, ships its monitors in sustainable packaging where most of it is recyclable. Rather than crumbly foam, the contents are protected by molded cardboard pulp with bits of flexible foam placed in just a few important spots. The stand and base bolt together, then the panel snaps to it. Two DisplayPort cables are included, one DP-to-DP and one DP-to-USB-C. You also get USB and an IEC power cord for the internal power supply. A large cover snaps onto the back of the panel to hide the inputs. Cables can be routed through the stand and out the back of the base.

Product 360

Dell

From the front, the AW3423DWF is all screen with a very thin bezel that’s flush-mounted. Alienware is printed at the bottom, and you can see the power button/LED at the lower right. The color and effect can be controlled in the OSD, along with two logos on the back. You can choose any color of the rainbow or cycle through the full spectrum. Or turn everything off for a stealth look.

The stand is very deep and rock solid. You’ll need nearly 15 inches of desktop space to accommodate the base. Ergonomics include -5/21 degrees tilt, 20 degrees swivel and a 110mm height adjustment. You can’t rotate the panel to portrait mode, but 5 degrees of slant is built-in, ostensibly to accommodate desktops that aren’t level.

You can see a component bulge in the back surrounded by a grill that effectively vents the small amount of heat generated by the AW3423DWF. The Alien head and size designator, 34 in this case, are lit up to let your opponents know what display you’re using to defeat them. Under the input panel cover, you’ll find two DisplayPort 1.4 inputs and a single HDMI 2.0. Those decrying the lack of 2.1 will note that 2.0 accommodates gaming consoles that support the 16:9 aspect ratio at 120 Hz, which means only 2560x1440 pixels. Console users will see black bars on either side of the image while playing, and you'll need to use DisplayPort for the full 3440x1440 at 165 Hz. Peripherals are supported by five USB 3.2 ports, one upstream and four down. Two of them are underneath the front bezel, which is a nice convenience. The headphone jack is also found there near the OSD joystick.

OSD Features

The AW3423DWF’s menu system will be familiar to any Dell or Alienware user. It’s controlled solely by the joystick mounted at the bottom center of the panel.

Tom's Hardware

Pressing the joystick once brings up a quick menu at the bottom and a status bar at the top of the screen. The panel health meter shows green, yellow or red based on how long it’s been since the panel or pixel refresh functions were last used. The quick menu gives access to picture mode AlienVision options, inputs, dark stabilizer and brightness/contrast.

There are 12 total SDR presets, of which Standard is the default. It’s very accurate and doesn’t need further adjustment if you’re OK with the full color gamut. For sRGB, engage the Creator mode, where you can choose a gamut and change the gamma. The Game modes add RGB sliders and game presets to the mix. Or scroll to the end for Custom Color where you can adjust RGB gain and bias controls plus hue and saturation sliders for all six colors.

Turning on Console mode lets one adjust hue & saturation plus gamma. In HDR mode, those options are grayed out, and you can toggle Source Tone Map, which uses the source signal’s metadata to set the tone-map transition point. This serves to enhance highlight detail.

AlienVision is a gaming aid that highlights the center of the screen. Or you can display the largest crosshair ever if you need help aiming. It’s a green cross that’s nearly four inches square.

AlienFX Lighting refers to the power LED, Alien head and number logo on the back of the panel. You can light them individually in any color or intensity. Choosing Spectrum cycles through all colors in a mesmerizing display.

In HDR mode, you can pick from six modes. For the best accuracy and greatest dynamic range, choose True Black. If you want the brightest possible highlights, go for HDR Peak 1000. The other presets are less impactful. My preference was True Black, as it shows off OLED’s capabilities to the fullest. And it’s plenty bright enough even in my sunlit office.

The joystick directions can be customized to provide quick access to the AlienVision options. You can also specify the functions of the quick menu.

To maintain a healthy panel, the AW3423DWF includes both pixel and panel refresh options. Both can run when the monitor is on standby. Once you’ve set these options, they’ll run only when you’re not using the display. I’ve used a similar routine with my two-year-old LG television, and I can attest to its effectiveness. There is no burn-in whatsoever.

Alienware AW3423DWF Calibration Settings

In the AW3423DWF’s Standard mode, calibration is unnecessary. Grayscale tracks perfectly to the 6500K color temp with gamma near 2.2 and no visible color errors when referenced to the DCI-P3 gamut. I found tiny improvements when I tweaked the RGB sliders in Custom Color mode, but this was more to satisfy my tests than anything else. If you want or need the sRGB gamut, it is available in the Creator mode, which also includes gamma presets. My recommended settings for SDR content are below.

In HDR mode, both HDR 1000 and True Black modes render with excellent color accuracy. They only differ in their luminance tracking. For the best possible HDR image, choose True Black. Overall brightness is the same, but the smallest highlights are slightly dimmer. Visually, I prefer True Black because its shadow detail and black levels are much better. I’ll talk more about these two HDR modes on page five.

Picture Mode	Custom Color
Brightness 200 nits	83
Brightness 120 nits	47
Brightness 100 nits	38
Brightness 80 nits	29
Brightness 50 nits	15 (min. 18 nits)
Contrast	75
Color Temp User	Gain - Red 97, Green 99, Blue 99
	Bias - Red 50, Green 50, Blue 50

Gaming and Hands-on

As a computer monitor, the AW3423DWF has few, if any, equals. The picture quality is simply on another level from any LCD panel I’ve experienced. It’s truly addictive, and once you’ve seen it, you won’t want to go back. Depth and dimension are so realistic, it is, to use the old cliché, like looking out a window. And that feeling includes high-res renderings too. Even when looking at monsters and fantasy environments, the texture is so convincing you’ll find yourself reaching out to touch things like stone or metal.

I saw a perfect example when playing Doom Eternal. Looking down at a stack of shotgun shells, I was struck by the metal end caps, which had just a bit of corrosion. Then I looked up at the gun barrel and marveled at how its shiny surface reflected the environment around me. Parts of it were like a mirror, and I saw every detail.

That detail stayed sharp when moving as well. Though I’ve had many positive experiences playing on 240 and 360 Hz monitors, the AW3423DWF’s 165 Hz is nearly equal in its motion processing. Fast side-to-side camera pans stayed in focus no matter how quickly I moved the mouse. This made it far easier to maintain my aim and to keep my viewpoint locked on where it needed to be. I saw frame rates between 150 and 165 from a GeForce RTX 3090-equipped PC. Even the best LCD with perfect overdrive can’t duplicate this look.

The curvature certainly contributed to the fun I had. You can get a lot of immersion from a large flat panel like the Aorus FO48U, but a curved ultra-wide, especially one with the contrast and color saturation of the AW3423DWF, conforms better to one’s peripheral vision. The curve keeps the entire image in focus with almost no head-turning required.

You’ll want to seek out HDR games whenever possible because that is what this monitor does best. Its SDR image looks great for older titles like Tomb Raider, but once HDR is turned on, you won’t want to turn it off. There was no performance hit or penalty for playing in HDR versus SDR. Adaptive-Sync always worked perfectly, and control lag was perceptually non-existent.

As a workday tool, the AW3423DWF serves well. The curve doesn’t distract when editing documents, and there is no image distortion. Spreadsheets are easier to deal with as you don’t have to scroll side to side as much. Word processing benefits from the easy ability to place two documents next to each other in full-page view. Photoshop can be set up to keep the graphic centered with tool palettes on either side. Or use the PBP function to view two sources at once.

The AW3423DFW is an absolute pleasure to use for work or play. It excelled at everything I did and is a completely addictive gaming display.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To compare the AW3423DWF’s performance, I’ve included two other OLEDs in the group, the Alienware AW3423DW and Gigabyte Aorus FO48U. The AW3423DW is nearly identical to the review subject but has a 175 Hz refresh rate and G-Sync certification. Functionally though, it is the same monitor. The FO48U is a 48-inch flat panel. The other displays are 34-inch ultra-wides – Monoprice 42772, AOC CU34G3S and BenQ EX3410R.

Pixel Response and Input Lag

Click here to read up on our pixel response and input lag testing procedures.

Tom's Hardware

The AW3423DW has a slight advantage in response time with its 5ms result. The DWF refreshes in 6ms, which makes only a subtle difference. Compared side-by-side with a 165 Hz LCD, the AW3423DWF looks smoother to the eye. This is due to its method of refresh, which is faster at a sub-field level. So, you’ll get a better experience from a 165 Hz OLED versus a 165 Hz LCD.

The AW3423DWF takes the win for overall input lag with an impressive 27ms result, 4ms quicker than the next-best Monoprice. This monitor is quick with a capital Q. It kept up with everything I could throw at it during fast battle sequences. Motion resolution was always exemplary, with no hint of stutter, and Adaptive-Sync worked flawlessly.

Viewing Angles

(Image credit: Tom's Hardware)

OLED panels have superb viewing angles where the image changes little at 45 degrees to the sides. You can see only a tiny reduction in brightness, maybe five percent, and no difference in color or gamma. The top view is slightly washed out but still free of color shift. The AW3423DWF is very shareable.

Screen Uniformity

To learn how we measure screen uniformity, click here.

(Image credit: Tom's Hardware)

My AW3423DWF sample had visually perfect dark field uniformity. Since OLED black levels are too low to measure, I used a 10% brightness pattern. No anomalies were visible, and color was equally perfect from edge to edge. White fields were free of artifacts and had no variation in brightness or color.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

To read about our monitor tests in-depth, please check out Display Testing Explained: How We Test PC Monitors. We cover brightness and contrast testing on page two.

Uncalibrated – Maximum Backlight Level

Tom's Hardware

The AW3423DWF hits its claimed SDR peak of 250 nits with a score of 253.0470. The Aorus can match most other monitors if you need a brighter OLED. While the average LCD is brighter, only an OLED has black levels that can genuinely be called infinite. To use the scientific vernacular, they are unmeasurable by any instruments available today. That means contrast is also infinite. There are better choices than an OLED if you need a lot of output outdoors or in a bright room. But for ultimate picture quality in most environments, it doesn’t get better.

After Calibration to 200 nits

Tom's Hardware

The story doesn’t change after calibration. The AW3423DWF was tweaked slightly, but that did not change the black level or contrast performance. The other monitors fare well with their VA technology and look great, but they pale compared to an OLED.

Since I am unable to measure black levels, I cannot determine an OLED monitor’s ANSI contrast; however, it is theoretically infinite. The impact of this cannot be overstated. In terms of picture depth, realism and color saturation, an OLED stands well above the best LCDs, including those with FALD and Mini LED backlights.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

The AW3423DWF ships with a factory calibration data sheet for each monitor. My sample matched those numbers in testing. It does not need adjustment in the Standard picture mode.

Grayscale and Gamma Tracking

Our grayscale and gamma tests use Calman calibration software from Portrait Displays. We describe our grayscale and gamma tests in detail here.

Tom's Hardware

Credit: Portrait Displays Calman

Out of the box, the AW3423DWF has no visible grayscale errors. All values are under 3dE which is widely considered to be the visible threshold. Gamma runs fairly tight to the 2.2 reference except for 10 and 20 percent which are slightly light. In the context of an OLED panel though, you cannot see this error.

In the Custom Color mode, I was able to improve the average error but visually, there is no difference. Gamma remains the same.

Using the Creator mode, I could select the sRGB gamut. You can also change the gamma value here, but I had no need as luminance tracking is nearly the same as Standard. Grayscale is almost perfect which is a good thing since it cannot be adjusted in this mode.

Comparisons

Tom's Hardware

Aside from the BenQ, all the monitors have excellent out-of-box performance and do not need to be calibrated. The AW3423DWF finishes a close second to the excellent Aorus FO48U. After calibration, it cruised to a first-place finish with its stablemate AW3423DW right behind.

The AW3423DWF’s gamma tracking is tight, with a small 0.17 range of values. It and the other top three screens have very similar performance in this test. The 1.82% deviation (actual value 2.16) is also similar to the best displays of the bunch. I saw that the gamma anomaly I observed in the AW3423DW is fixed for the newer model. Overall, this is excellent performance.

Color Gamut Accuracy

Our color gamut and volume testing use Portrait Displays’ Calman software. For details on our color gamut testing and volume calculations, click here.

Portrait Displays Calman

Not only is the AW3423DWF’s default color gamut on-point, but it’s also very large. It meets the full saturation target for green, a rarity among wide gamut displays. It over-achieves in red a bit but not so much that color looks overblown. Near-perfect hue tracking and linear saturation points mean the image always looks balanced and natural.

Calibration barely makes a difference, with just a 0.3dE improvement. Visually, there is no change. Clearly, the Custom Color mode is not necessary for an accurate picture.

Graphics pros and photographers will appreciate the Creator mode, which serves up a perfect sRGB gamut. All saturation and hue points are on target, with an average of 0.89dE.

Comparisons

Tom's Hardware

The AW3423DWF’s color accuracy is exemplary. As a DCI-P3 or sRGB display, it is in the top tier of all the monitors I’ve tested and is as accurate as any professional screen. You could pay more for a pro OLED or Mini LED screen, but why would you? Even without calibration, it would finish third here.

The Quantum Dot layer expands the AW3423DWF’s color gamut to over 107% of DCI-P3. That equates to 76.41% of Rec.2020. Interestingly, the FO48U does not have a QD layer but can match color volume with the Alienware screens. You can also see the ideal coverage of sRGB at 99.98%.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Our HDR benchmarking uses Portrait Displays’ Calman software. To learn about our HDR testing, see our breakdown of how we test PC monitors.

OLED panels look great in SDR mode, but HDR is where they truly shine. The AW3423DWF can produce bright highlights, expanding its dynamic range and making the picture pop even more.

HDR Brightness and Contrast

Tom's Hardware

OLED panels vary their brightness depending on the total picture level. Though the AW3423DWF can hit 1,000 nits, I had to measure a tiny white window to achieve this result. A full-field white pattern is closer to 450 nits. This is where the two Alienware monitors have an advantage over the Aorus. It can’t go beyond 400 nits regardless of content. The AW twins deliver super bright highlights. A starfield is the best example of this. The stars really twinkle against an inky black background. It’s something no LCD can match, no matter how many dimming zones it has.

With unmeasurable black levels, contrast is theoretically infinite. It certainly is to the eye. Blacks really are black, yet shadow detail is clearly visible. The other monitors do a good job with their VA panels, but OLED is on another level in HDR mode.

Grayscale, EOTF and Color

Portrait Displays Calman

I spoke earlier about the AW3423DWF’s various HDR modes. You must select the True Black mode to get the most accurate luminance tracking and widest dynamic range. HDR 1000 will get you the bright peaks, but its low and mid-tone areas are too light. If you only view bright content, that’s fine, but the presentation is mostly a murky gray in darker scenes. The EOTF tracking result supports this. Between zero and 40%, it’s well above the reference line. In True Black mode, it’s nearly perfect. In either case, the tone-map transition point is at 60%. And grayscale tracking has no visible errors.

Color is different in the two modes as well. In HDR 1000, red and blue come up a bit short of full saturation. True Black is over-saturated linearly, so color looks balanced, and all detail is sharply rendered. The Rec.2020 charts are closer to each other, but True Black is still the best choice for image fidelity.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

It's likely that LCD will remain the dominant flat panel technology for the foreseeable future. However, OLED will always have a picture quality advantage thanks to its higher contrast. The ability to produce a true black, as in a pixel that’s completely extinguished, is something LCD cannot do. Its light valve operation means that the backlight will always be a factor.

OLED is a rare thing in computer monitors, but unless you need a lot of light output, it is the best choice for gaming and entertainment. It doesn’t require overdrive to achieve smooth motion processing. And the latest QD-OLED panels boast very large color gamuts. Those concerned with burn-in can trust the panel maintenance features built into displays like the Alienware AW3423DWF.

(Image credit: Tom's Hardware)

As a gaming monitor, the AW3423DWF is unparalleled. The picture is beyond stunning for both SDR and HDR content. Color is richly saturated and vivid. Contrast is phenomenal and the clarity is fantastic. Accuracy proved to be a non-issue, with no calibration required. With the available Creator mode, I could call up an equally accurate sRGB mode when needed. And the gamma issues I noted in my review of the AW3423DW have been rectified. The monitor excelled in every color test with results that rival any professional display.

Motion processing is also above the norm. Though it runs at 165 Hz, the AW3423DWF delivers the smoothness of a faster monitor. It will easily have you thinking it runs at 200 or 240 Hz. There’s no tweaking of overdrive necessary either. It just does its thing without fuss. And it eliminates frame tears with equal precision for both FreeSync and G-Sync systems. I also noted that it had lower input lag than its stablemate AW3423DW, beating the other 165 Hz screens for overall quickness.

At $1,100, the AW3423DWF is undoubtedly a premium display. But it’s a good value considering the superb picture quality and gaming performance. Unless you need even more speed, it’s hard to imagine a better gaming monitor. I’ll have a hard time sending this one back.

MORE: Best Gaming Monitors

MORE: How We Test PC Monitors

MORE: How to Buy a PC Monitor: A 2022 Guide

MORE: How to Choose the Best HDR Monitor

Alienware Rolls Out More Affordable 34-inch QD-OLED WQHD Gaming Monitor

brandon.hill@futurenet.com (Brandon Hill) — Tue, 27 Sep 2022 16:20:36 +0000

Dell made quite the splash in the gaming monitor realm with the release of the Alienware AW3423DW earlier this year. We were impressed with the gorgeous QD-OLED display, large color gamut, excellent contrast, and 175Hz panel in our hands-on review of the AW3423DW. However, the $1,299 price is probably beyond the budget range of many gamers. So today, Alienware announced a new member to the family, the similarly named AW3423DWF, which is priced slightly lower at $1,099.

The AW3423DWF still features a 34-inch WQHD (3440 x 1440) QD-OLED panel with a 0.1ms GtG response time and a 1800R curve. That means color uniformity, the wide color gamut and inky blacks are still here in full effect. However, the maximum refresh rate has decreased just a smidge from 175Hz to 165Hz.

(Image credit: Alienware)

In addition, the white and black design of the AW3423DW has given way to an all-black motif with the AW3423DWF (Alienware calls the color Dark Side of the Moon). Likewise, the overall footprint is slimmer to better accommodate those with limited desk space.

Alienware AW3423DWF Specs

Panel Type / Backlight	Quantum Dot
	Organic Light Emitting Diode
Screen Size / Aspect Ratio	34 inches / 21:9
	Curve Radius: 1800mm
Max Resolution & Refresh Rate	3440x1440 @ 165 Hz
	FreeSync Premium Pro
Native Color Depth & Gamut	10-bit / DCI-P3
Response Time (GTG)	0.1ms
Brightness (mfr)	250 nits SDR
	1,000 nits HDR
Contrast	Infinite
Speakers	None
Video Inputs	2x DisplayPort 1.4
	1x HDMI 2.0
Audio	2x 3.5mm output
USB 3.2	1x up, 4x down
Power Consumption	51w, brightness @ 200 nits
Panel Dimensions WxHxD w/base	32.1 x 16.36-20.69 x 12.04 inches
	(815.25 x 415.57-525.57 x 305.71mm)
Weight	13.82 pounds (6.9kg)
Warranty	3 years

There are some other noticeable hardware changes regarding port layout. Whereas the AW3423DWF came with two HDMI 2.0 ports and one DisplayPort 1.4 connector, the AW3423DWF flips that arrangement, offering one HDMI 2.0 port and two DisplayPort 1.4s. However, you'll still find two 3.5mm audio-out ports and four downstream USB 3.2 ports.

(Image credit: Alienware)

But Alienware didn't stop there; the joystick mounted under the center of the AW3423DWF has been revised to provide quick access to preset game modes. The joystick can also be used to jump to an all-new Creator mode that Alienware added. Alienware adds that the AW3423DWF's ComfortView Plus low blue light mode is TUV-certified and that Variable Refresh Rate is supported at up to 120Hz refresh rates on PlayStation 5 and Xbox Series X consoles.

As we mentioned at the onset, Alienware has priced the AW3423DWF at $1,099, representing a $200 price cut compared to the AW3423DW. In addition, the monitor is backed by a 3-year hardware warranty, and Alienware says it will ship in the United States and Canada later this fall. We’ll greet the AW3423DWF in our lab soon to see if it has what it takes to join the ranks of the best gaming monitors.

LG Debuts UltraGear 45-Inch 240Hz Curved OLED Gaming Monitor

Mark Tyson — Fri, 26 Aug 2022 18:11:51 +0000

LG showcased a huge ultra-wide gaming monitor at IFA 2022 in Berlin today. The new LG UltarGear OLED gaming monitor (model 45GR95QE) features a 45-inch diagonal 3440 x 1440 pixels display with a 240 Hz max refresh rate and 0.1 ms response time. It is designed to fully immerse gamers with its accurate and wide color gamut and its viewer-encapsulating 800R curvature.

(Image credit: LG)

The new LG UltraGear 45GR95QE is the company’s first monitor to be released using a 45-inch OLED display panel and the first featuring 800R curvature. However, if you are feeling some déjà vu, LG’s monitor appears to be employing the same ‘LG Display’ flexible OLED panel that enabled the physically flexing Corsair Xeneon Flex 45WQHD240 OLED gaming monitor we reported on yesterday. The critical difference is LG has decided on a fixed 800R curvature, and the Corsair leaves the degree of screen curve up to the user (between totally flat and approx 800R). Perhaps LG wasn’t happy with the creaky Corsair flexing mechanism, which doesn’t create a true arc, but rather a display with two flat sides plus a bend in the middle.

Like the Corsair, this ultra-wide LG OLED gaming monitor has excellent gaming performance and punchy color reproduction. In addition to sustaining the headlining 240 Hz max refresh rate, this monitor can sync with your graphics card (VRR) for smooth action as frame rates dip. Check the table at the bottom of this article for a complete set of essential specs.

Another interesting monitor LG had on display at IFA 2022 was the UltraFine Display Ergo AI (model 32UQ890), pictured below. This is a high quality 31.5-inch 4K (3840 x 2160) IPS display with 95% coverage of DCI-P3. However, its party trick is hinted at by the ‘AI’ in its name.

(Image credit: LG)

This monitor supports three AI-driven ergonomic enhancement modes: AI Motion, Continuous Motion and Periodic Motion. AI Motion, which was demonstrated at LG’s booth during IFA, tracks the user’s eye level and adjusts screen height and tilt via its powered articulated desk-mounted arm whenever a change is detected.

	UltraGear OLED Gaming Monitor (45GR95QE)	UltraFine Display Ergo AI (32UQ890)
Display Type	OLED (AGLR)	IPS
Screen Size	45-inch	31.5-inch
Resolution	WQHD (3,440 x 1,440)	UHD (3,840 x 2,160)
Color Gamut	DCI-P3 98.5%	DCI-P3 95%
Contrast Ratio	1,000,000:1	1,000:1
Refresh Rate	240Hz	60Hz
Response Time	0.1ms GTG	5ms GTG
Curvature	800R	N/A
HDR	HDR10	HDR10
Connectivity	HDMI 2.1 x 2 DisplayPort 1.4 x 1USB 3.0 x 1 Upstream x 2 Downstream 4pole H/P out (DTS HP:X)	HDMI x 1 DisplayPort 1.4 x 1 USB 3.0 x 1 Upstream x 2 Downstream 3 pole H/P out
Speaker	N/A	5W x 2 (MaxxAudio)
Remote Controller	Yes	Yes
Stand	Tilt: -2º to +15º (Manual) Height: 110mm (Auto) Swivel: ±10º Pivot: Not Available	Tilt: -20º to 20º (Auto/Manual) Height: 160mm (Auto/Manual) Swivel: ±270º (Manual) Pivot: Not Available Extend/Retract: 300mm

LG hasn’t shared pricing or availability dates for the UltraGear 45GR95QE or UltraFine 32UQ890 monitors, but we're pretty sure you'll be able to find an LG promo code to help with the cost.

Grab the ViewSonic VX2718 27-Inch WQHD Gaming Monitor for Only £209: Real Deals

Stewart Bendle — Mon, 14 Mar 2022 15:10:40 +0000

If you're in need of a new gaming monitor, but the current financial climate has left you with only a small budget, then today's deal is great news. The ViewSonic VX2718 2KPC MHD 27-inch WQHD Curved Gaming Monitor is on sale at CCL Computers for an insanely low price of £209. For a monitor with these specs, that's a whole lot of bang for the buck.

The ViewSonic VX2718 has some rather impressive specifications for its price. First off, the screen is a VA panel (2560 x 1440 pixels) with a 1500R curve, Adaptive Sync capabilities, and a refresh rate of 165Hz covering 102% sRGB colour gamut. Connectivity-wise the VX2718 comes with two HDMI 2.0 ports and one DisplayPort 1.2, and even a 3.5mm headphone jack. The VX2718 also includes some small stereo speakers and of course, a 100 x 100 mm VESA mount option should you want to mount the monitor to an arm.

This is one of the cheapest 27-inch WQHD monitors you can buy, currently, it's on sale with a £47 reduction off of its normal asking price.

ViewSonic VX2718 2KPC MHD 27-inch WQHD Curved Gaming Monitor: was £257, now £209 at CCL Computers
The ViewSonic VX2718 screen is a VA panel (2560 x 1440 pixels) with a 1500R curve, Adaptive-Sync capabilities, and a refresh rate of 165Hz covering 102% sRGB colour gamut. Connectivity-wise, the VX2718 comes with two HDMI 2.0 ports and one DisplayPort 1.2.View Deal

When gaming on a monitor that has a quad HD resolution and a high refresh rate, you will need a fairly powerful graphics card to power the screen if you are looking to max out graphical settings in games or programs. Have a look at our best GPU guide for an idea on a graphical solution that fits your needs.

If you want to see how this screen compares to our top picks for monitors then have a look over our best monitors guide.

More Intel ViewSonic VX2718 2KPC MHD Deals

Intel Core i7-10700K vs AMD Ryzen 7 3700X: Eight-Core CPUs Fight for Prime Day Supremacy

palcorn@outlook.com (Paul Alcorn) — Mon, 21 Jun 2021 17:55:35 +0000

You know things are tough in the CPU world when the best Intel and AMD chips deals for Amazon's Prime Day are for previous-gen chips, but that's the situation this year. We spotted dueling deals for previous-gen eight-core Intel and AMD chips, all of which have vied for spots on our Best CPUs list in the past. That sets up a Prime Day battle between the $259 Core i7-10700K ($239 for the graphics-less 10700KF) and the $279 Ryzen 7 3700X.

We typically don't recommend buying previous-gen chips, but all three of these chips are available at (or near) all-time low pricing while we're in the unforgiving grip of a silicon shortage. That makes them solid alternatives if you're looking to upgrade a current system, or even build out a new platform with previous-gen gear.

For comparison, both the current-gen eight-core AMD Ryzen 7 5800X and the eight-core Intel Core i7-11700K weigh in at $399 when you can find them in stock near MSRP, meaning that the three chips in today's Amazon Prime Day deal are ~$150 cheaper for the same number of cores. That means you'll pay roughly $34 per core for the previous-gen chips while the more modern chips weigh in at $50 per core.

Naturally, the previous-gen eight-core chips aren't as fast as the newer models, but you can reference our CPU Benchmark hierarchy for a crystal-clear view of the performance deltas between the newer and older chips. Here's a snippet of how that breaks down for each chip, with the scores in each category being relative to the fastest chip on the market in each category (higher is better):

	Price	Gaming 1080p / 1440p	Multi-Threaded Performance	Single-Threaded Performance
Intel Core i7-10700K/F	$259 / $239	86% / 90%	28%	82%
Ryzen 7 3700X	$279	77% / 81%	27%	76%
Core i7-11700K/F	$399 / $389	92% / 95%	34%	94%
Ryzen 7 5800X	$399	97% / 97%	33%	93%

Intel Core i7-10700K: was $320, now $260 at Amazon
The Core i7-10700K's $260 price tag marks a new low for the eight-core 16-thread processor that operates with a 5.1 GHz boost and 3.8 GHz base clock. This chip makes a cost-effective upgrade if you already have a 10th-gen processor, but be sure to check pricing on newer alternatives before pulling the trigger. View Deal

Intel Core i7-10700KF: was $301, now $240 at Amazon
The Core i7-10700KF's $240 price tag marks a new low for the eight-core 16-thread processor that operates with a 5.1 GHz boost and 3.8 GHz base clock. This model comes without integrated graphics and makes a cost-effective upgrade if you already have a 10th-gen processor, but be sure to check pricing on newer alternatives before pulling the trigger.View Deal

AMD Ryzen 7 3700X: was $307, now $279 at Amazon
AMD's eight-core 16-thread Ryzen 7 3700X is at near all-time low pricing for Prime Day, marking the only AMD chip we can find with a substantial discount. This chip ticks at 3.8 GHz under heavy load and boosts to 4.6 GHz. It also comes with full support for PCIe 4.0. View Deal

Overall, the Core i7-10700K looks to be the better pick based purely on performance alone. However, remember, this chip doesn't come with a bundled cooler, whereas the Ryzen 7 3700X does. Additionally, the Ryzen 7 3700X supports PCIe 4.0 while the 10700K uses the slower PCIe 3.0 spec.

For more Prime Day savings, check out our Prime Day live blog and lists of the best Prime Day gaming PC and laptop deals, best Prime Day SSD deals, best Prime Day Monitor Deals, Best Prime Day Dell Gaming deals and the best Prime Day hardware deals overall. Our sister site, TechRadar, has a broader list of Amazon Prime Day deals that includes product categories we don't typically cover, such as smart home devices, TVs and phones.

This 34-Inch WQHD 144 Hz Lenovo Monitor Is Just $335 for Prime Day

Matt Safford — Mon, 21 Jun 2021 11:43:48 +0000

Close your eyes for a few seconds and thinking about a typical budget gaming monitor. Chances are, you little monitor daydream didn't include a 34-inch curved ultrawide panel with 3,440 x 1,440 resolution, 144 Hz refresh rate VA panel (for great contrast) and FreeSync.

But that's what Lenovo's G34w-10 brings to the table, for a surprisingly affordable price of just $335 for Prime Day. That's $100 off its recent price. And while the monitor often fluctuates between around $460 and $375, today's price is slightly cheaper than any previous price we could find via CamelCamelCamel.

Lenovo G34w-10: was $405, now $335 at Amazon
With its 21:9 curved display, WQHD resolution, 144 Hz refresh and adjustable stand, Lenovo's G34w-10 is feature-packed.View Deal

Aside from the above features, the G34w-10 has slim bezels on three of its four sides, which should help -- along with its 1500R curve and deep blacks thanks to the VA panel -- the monitor deliver a seriously immersive gaming experience. FreeSync should also keep screen tearing at bay for those with AMD GPUs. You could also try using variable refresh with an Nvidia graphics card with this monitor, but some who have tried didn't seem happy with the results.

A couple other nice features of the Lenovo G34w-10, given its budget-friendly pricing: The stand features both height and tilt adjustment, and the brightness rating is a solid 350 cd/m2. Don't expect to enjoy HDR content here, but it should be a bit brighter than many budget panels in this price range. If you're after a monitor with higher-end gaming features at a budget friendly price, this might be your best option at today's low price.

AMD Ryzen 7 3700X Drops to $269 at Walmart

Ash Hill — Mon, 05 Oct 2020 14:29:45 +0000

With RTX 3000 GPUs finally getting into the hands of the public, you'll want to make sure you have one of the best CPUs to go alongside yours, so you can take full advantage of its power. Lucky for you, the Walmart website is currently selling the AMD Ryzen 7 3700X at just $269 (down from $307). The offer also includes three 32GB SanDisk flash drives with printed patterns on them.

AMD Ryzen 7 3700X w/ three 32GB flash drives: was $307, now $269 @Walmart

This offer includes the AMD Ryzen 7 3700X CPU, which can reach speeds as high as 4.4GHz when boosted. It also comes with three 32GB SanDisk flash drives.View Deal

This particular CPU has 8 cores and 16 threads. Its base operating speed is around 3.6GHz and it can reach 4.4GHz when boosted. It supports DDR4 memory with speeds up to 3200MHz.

Cooling-wise, the Ryzen 7 3700X comes with AMD's Wraith Prism cooler. This might not be one of the best cpu coolers, but it gets the job done and features RGB LEDs for a flashy look.

Check out this offer for yourself at the AMD Ryzen7 3700X product page on Walmart. There is no expiration listed on the website and it’s not clear how long the offer will be made available.

Installing a Fluid Temperature Sensor: The Best $10 Upgrade for a Custom Loop

Niels Broekhuijsen — Sat, 12 Sep 2020 12:00:39 +0000

When we built the Mirror Maze system, one of the things we overlooked was installing a sensor to monitor the fluid temperature. Without knowing how warm the loop was really running, I delved into a paranoia-induced adventure with the fan controls. And though I got the system running quietly at a level I felt was safe and kept thermals well under control, I knew it was hardly optimal.

So, I did what any sensible obsessed enthusiast would do: Within one week of finishing the build, I busted off the drain port, painstakingly drained most of the fluid out -- with some heavy two-man acrobatic lifting to get all the fluid where I needed it to be -- ripped out the radiator tubes and chucked a temperature sensor into the loop. While I was at it, I also swapped the AMD Ryzen 7 3700X for a 3900X as the dent I put in the 3700X’s heatspreader during the build wasn’t doing thermals any favors, either.

I was a man on a mission: This system had to run acoustically and thermally perfectly. After all, we did sacrifice the best looks in favor of acoustics by using nine brown Noctua NF-A12x25 PWM fans (even though, I personally dig the Noctua brown-and-beige color scheme), so it would be a shame to have them spinning any faster than is absolutely necessary.

This system had to run acoustically and thermally perfectly.

(Image credit: Tom's Hardware)

The temperature sensor I opted for was the Alphacool Eiszapfen G1/4” female to female sensor, which paired with a 7mm male-to-male EK-Quantum Torque Extender fit perfectly between an angled fitting, leaving the distribution plate and a fitting connecting to a run of acrylic tubing. I placed it right at the bottom of the system by the pump, as there was already a GPU power cable running here, cables for the fans, and cables for the pump, making it easy to hide the sensor’s cable in the wire highway.

This was at the first fluid outlet of the EK-Quantum Reflection O11D distro plate, meaning the sensor was placed between the two radiators in the loop order – but anyone familiar with watercooling will tell you that the temperature is pretty much equal everywhere throughout the loop, unless you’re running absurdly low pump speed. And even then, the differences are so minor that you’re still more likely to get different temperature readings from multiple sensors due to variances in their readout than actual temperature differences throughout the loop.

No, one sensor was plenty, and it didn’t matter where it went. I might want perfection, but there really is no point in populating all three sensor headers on the Asus Crosshair VIII Formula Motherboard.

Tuning to Perfection

(Image credit: Tom's Hardware)

I then set all the fans to stop spinning when the fluid temperature is below 30 °C, which meant I couldn’t connect any of the fans to the CPU fan header, as Asus doesn’t allow CPU fans to stop entirely. At 30 °C they could start spinning, and by a fluid temperature of 50 °C I wanted them to run at full speed, though they should never need to reach this point. But he, just in case, you know?

After all that, a little more finetuning was required.

The first thing I noticed was that the Noctua fans ran much quieter on radiators than as a free intake at the bottom of the case, so I dropped the intake fans’ speed by 10 percent across the board, which seemed to match the radiator’s fans for noise levels. I also set the side intake to always spin, as I found that totally passive, the loop would still warm up to 30 degrees idle, making the system swing back and forth between passive and idle quite often. Turning the side intake to always run kept the loop a hair under 30 degrees most of the time during normal desktop use. Its a bit of a shame that we didn't achieve fully passive desktop use, but the Noctua NF-A12x25’s are totally inaudible at 750 RPM on a radiator anyway, especially when pointed away from the user.

(Image credit: Tom's Hardware)

Under load, when running Destiny 2 or Horizon Zero Dawn, the highest fluid temperature I ever observed was 38 °C, but that was after hours of gaming in a small, closed room with no airflow -- it was getting warm in here. The internet also told me that the highest Delta-T you want the fluid at over ambient is around 15 degrees, and while higher isn’t necessarily a direct cause for concern until you reach the pump's temperature limit (usually at about 60 degrees Celsius), at this point I was within that norm for a 25 degrees C room and happy with the noise levels, so I decided that was that and saved the fan profile.

So, just how quiet was the Mirror Maze PC then?

With the set fan curves, in-game, the fluid temperature hovered somewhere around 36 to 37 degrees C, with the 3900X's temperature at 62 °C and the RTX 2080 Super graphics card running at just 55 degrees C. The following chart details the noise levels in different scenarios.

(Image credit: Tom's Hardware)

As you can see, the system is extremely quiet. Idle, it isn’t audible over the noise floor of the room, unless you get very intimate with the case. Putting all 12 cores of the Ryzen 9 3900X under full load does practically nothing to raise noise levels, even though the fans for the top radiator and intake enter duty. It's so quiet that when my friend entered the room and saw the system, he commented on how quiet it runs, and he wouldn't believe me when I told him that Prime 95 was running for the past hour at smallest FFTs (maximum heat generation).

It’s only when you game for extended sessions that the fluid warms up enough to warrant higher fan speeds and consequently noise, and even then, the noise levels are still extremely low.

For laughs, I also measured the noise level of the coil whine the GPU produces under load in a cold loop before the fans spin up, and it measured 35.2 dB -- right in between the CPU full load measurement and the noise level of an extended gaming load.

To give a point of reference, I set the fans to full speed and measured how much noise the system is capable of producing with the cooling loop running at maximum capacity, and it's safe to say that the noise level there is an order of magnitude higher. The system can get extremely loud. With everything at full blast it's uncomfortably loud, but there is no reason to ever run it like this unless your only goal is pushing overclocks.

(Image credit: Tom's Hardware)

To shed some more light on the cooling capacity, the above chart details the fan speeds in the different scenarios. it's clear that the cooling loop, despite using 28-mm thin radiators, is running nowhere near its capacity. Because it's so over-dimensioned, the quiet Noctua spinners hardly need to put any effort in to keep the system cool.

Oh, and in case you were wondering, the CPU is running with AMD Precision Boost Overdrive enabled, and the GPU is overclocked with the power limit at 116% (it won't go higher), a core offset of +100 MHz and its memory at +1000 MHz.

(Image credit: Tom's Hardware)

Basing the fan curves on the coolant temperature is a much better method of controlling the fans in a liquid loop than with a fixed fan speed, or based on the CPU temperature. When I was running it off the CPU temperature, the fans would spin up significantly at the slightest CPU load spikes, which the loop can absorb anyway. Before the mod they also wouldn’t spin up at all when the GPU was spitting well around 250 watts into the loop – because for some ridiculous reason, it’s still not possible to set motherboard-controlled fan curves based off of the GPU temperature. So before installing the sensor, the only way to have the fans speed up because of the GPU was to set a curve based on the CPU temperature, and then wait for the CPU to warm up from the GPU warming the loop up. Sounds stupid, right? It is. Nobody should control a liquid loop like that.

So long story short: If you’re running a custom loop and your motherboard supports a standard two-pin thermal sensor, do yourself a favor and spend the $10 for a sensor, $10 for fresh coolant, and the afternoon it takes to set up a control mechanism based on what really matters, the fluid temperature. If your motherboard doesn't have this header, you might need to spend a little extra to get a controller that can do this for you, but I reckon it'll still be well worth the effort and expense.

The Mirror Maze PC: Building an Ultra-Quiet, Liquid-Cooled PC to Get Lost In

Niels Broekhuijsen — Fri, 28 Aug 2020 11:00:07 +0000

There are a couple approaches you can take to building a PC. By far the most common is a rather pragmatic one, where you build a machine that’s solely meant as a means to a specific end (say, for gaming, or some other specific task, or within a set budget), keeping looks in the back of your head, but mostly as a side concern. But with this build we decided to take a whole different approach.

Today we’re not building a PC that’s not meant to squeeze as much power out of each dollar spent, but rather one that tries to offer the most refined experience -- not just beautiful looks or record-breaking performance. Naturally, when tackling a build like this, custom liquid cooling is a must, as this will help keep the components cool and quiet.

But the whole idea for this build started when Lian Li announced the PC-O11 Dynamic in the special Space Gray Edition. We knew this chassis could be the start of something great, and thus was born what we're calling the Mirror Maze build, a system with tons of reflective, shiny components designed to pump out frames and churn though productivity tasks, but be quiet enough so that you'd barely notice its presence, even when running at peak performance.

Component Selection

To start off with, we’ll guide you through the component selection of this system, detailing the reasoning that went into the choices made for this build, starting with the initial inspiration.

Case: Lian Li PC-O11 Dynamic, Space Gray Special Edition

Lian Li PC-O11 Dynamic (Image credit: Tom's Hardware)

The choice for the PC-O11 Dynamic was an easy one. This chassis is among the most popular water-cooling cases out there, and it brings with it a robust platform of third-party hardware that you can pack into it. But the standard model is common and a little plain, so we’re spicing it up with the special Space Gray edition, a chassis built in collaboration with the PCMR community. It comes with mirrored tempered glass panels that, while making it a major pain to photograph, also make it perfect for the mirror maze theme we’re going for.

CPU: AMD Ryzen 7 3700X

AMD Ryzen 7 3700X (Image credit: Tom's Hardware)

You would think that for a system of this caliber, we would opt for the most expensive CPU, packing it with either the latest Intel Core i9-10900K or AMD’s stunning 16-core Ryzen 9 3950X. But, we don’t need that kind of CPU power for gaming or most productivity tasks. AMD’s 8-core Ryzen 7 3700X, on the other hand, offers all the performance you really need for high-end mainstream computing. It comes in at about $300, making it a very approachable starting point for this system. Besides, AMD promises support for Zen 3 CPUs on the X570 platform, so there will be plenty of upgrade options in the future.

Motherboard: Asus Crosshair VIII Formula

Asus Crosshair VIII Formula (Image credit: Tom's Hardware)

The roughly $600 price will make this an unpopular option for some, but the VIII Formula is among the top X570 motherboards money can buy, and it comes with an integrated EKWB waterblock for the VRM circuitry. This block isn’t something you expressly need. And yes, I’m aware that this is going to make my cooling runs much more complicated and difficult, but I’m ready to take on that challenge -- or at least I thought I was at the beginning. Note: If you’re considering a build like this, do yourself a favor and skip including the VRMs in the loop. Other than aesthetics, it doesn’t add much value.

What really makes this board great for a build like this is that it’s absolutely smothered in fan headers, RGB headers, sensor headers, and just about every case accessory you could need. It even has a dedicated header for the water pump – though we’ll only be using that header for the PWM signal and RPM readout.

Memory: G.Skill Trident Z Royal, 4x 8GB, 3600 MHz, CL18

G.Skill Trident Z Royal, 4x 8 GB, 3600 MHz, CL18 (Image credit: Tom's Hardware)

Given the theme of this build, logically we went with some very, very shiny memory modules to match. Arguably, it would have made more sense to go for two 16 GB modules for a 32 GB memory configuration, both from a cost and performance perspective, but four modules simply looks better and more complete. At 3600 MHz and CL18 timings, these DIMMs are speedy, too.

Graphics Card: EVGA Nvidia GeForce RTX 2080 Super Gaming Black

EVGA Nvidia GeForce RTX 2080 Super Gaming Black (Image credit: Tom's Hardware)

We decided not to mount the GPU vertically in this build, which meant that we needed a reference-design GPU, since the PC-O11 Dynamic doesn’t support wide cards horizontally. But, Nvidia’s Founders Edition cards are pricey with their fancy coolers, so we’re turning to EVGA for its RTX 2080 Super Gaming Black.

This card still has a great cooler on it already, but it isn’t as costly, and with no fancy PCB design with elaborate VRM circuitry or RGB flashiness, you’re not paying for any goodies on this card that you don’t need. Features like a fancy cooler or RGB can’t be appreciated here since we’re replacing the cooler anyway, so no point in paying for them.

Although the RTX 2080 Super doesn’t make total sense from a value perspective over the RTX 2070 Super when looking at the GPUs alone, the added 10 percent performance it offers (give or take) is in-line with the added 10% of budget spent on the system cost as a whole, so all in all we figured this was the sweet spot: The most GPU without any bells or whistles. Sure, Nvidia’s Ampere GPUs are around the corner, but for now this is what we have to work with.

Fans: 9x Noctua NF-A12x25

Noctua NF-A12x25 (Image credit: Tom's Hardware)

You may not be a fan of the classic Noctua brown-and-beige color scheme, but from a pure performance perspective, the NF-A12x25 is one of best fans currently on the market. It’s coming out in black next year, but for now brown is what you get, and we're fine with that.

Before you worry that the fans are going to overpower the system's looks, let me entertain you with my theory: Three of the fans are in a spot where you won’t see them, and the remaining six will have Phanteks Halos Lux light rings installed on them for some wicked RGB. For the other fans, the case has panels with mirrored glass, so what isn’t lit up you won’t see it anyway. Read on to see how this theory pans out.

Fan Accessory: Phanteks Halos Lux

We’re using Phanteks’ Halos Lux to turn the Noctua fans into killer RGB spinners.

Storage: Samsung 970 Evo Plus 1TB

Samsung 970 EVO Plus 1TB (Image credit: Tom's Hardware)

Although you could argue it’s a shame not to use the PCI-Express 4.0 that the Ryzen 7 3700X and X570 motherboard supports, the speed gains for PCIe 4.0 in games are negligible, making price and reliability the winning factor here. I needed a drive that I can trust for many years and builds to come, and the 970 EVO Plus is plenty fast at 3500 MB/s read and 3300 MB/s write.

Power Supply: be quiet! Straight Power 11 850W Platinum

be quiet! Straight Power 11 850W Platinum (Image credit: Tom's Hardware)

It’s German, it’s quiet, it’s modular, and it’s efficient. The Straight Power 11 850W Platinum is a PSU that simply does the job without drawing too much attention to itself, and its modular connectivity is perfect for pairing with our custom cables.

Cables: CableMod ModMesh Pro

CableMod ModMesh Pro (Image credit: Tom's Hardware)

We’re using CableMod’s ModMesh custom cables with Carbon-colored sleeving and black, anodized aluminum combs. This combo yields a cable that looks strong and industrial, which fits the theme perfectly. The combs keep everything tidy, and the sleeving is quite strong, making these cables very good at staying in the exact position you want them in – but you’ll want to measure the exact lengths carefully, as excess length can get difficult to manage.

Water-cooling Components: All-EKWB

EKWB (Image credit: Tom's Hardware)

To match the clean, simplistic, and reflective aesthetic we’re going for, EKWB makes some of the most fitting (no pun intended) waterblocks and fittings. These parts match the styling of the Asus motherboard and the case very well.

Best of all, EKWB just released a distribution plate, the EK-Quantum Reflection PC-011D D5 PWM D-RGB, and we’re using it for this build. This is a distribution plate that is custom-made for the Lian Li PC-011D, and it acts as the reservoir and pump, and has fitting ports at all the right spots to make tubing runs a breeze (unless you’re stubborn like me and decide to deviate from the intended layout).

To go with this, we chose the Velocity CPU block with a nickel-plated top finish, an acrylic GPU block with a matching backplate that is nickel-plated, and a huge number of -- you guessed it -- nickel-plated fittings.

In this loop we’ll be using clear fluid by simply mixing EK-CryoFuel with distilled water. Boring? Perhaps, but it’s part of the reflective theme as far as I’m concerned, and doesn’t define a set color theme, allowing you to take the RGB goodness in any direction you fancy.

Water-cooling Components
Qty	Part
1	EK-Quantum Reflection PC-O11D D5 PWM D-RGB - Plexi
1	EK-Velocity RGB - AMD Full Nickel
1	EK-Quantum Vector RTX RE D-RGB - Nickel + Plexi
1	EK-Quantum Vector RTX Backplate - Nickel
18	EK-Torque HTC-14 - Nickel
8	EK-Torque Angled 90° - Nickel
7	EK-Torque Angled 45° - Nickel
3	EK-Cable Y-Splitter 3-Fan PWM (10cm)
2	EK-CoolStream SE 360 (Slim Triple)
1	EK-Loop Modulus Hard Tube Bending Tool - 14mm
5	EK-HD Tube 10/14mm 500mm (2pcs)
1	EK-HD Tube Reamer
1	EK-HD Tube D.I.Y. Kit 10&12mm
1	Filling Bottle (1000mL)
2	EK-Quantum Torque Extender Static MF 28 - Nickel
1	EK-Quantum Torque Extender Static MF 7 - Nickel
4	EK-Quantum Torque Extender Static MF 14 - Nickel
1	EK-CryoFuel Clear (Concentrate 100mL)

1. Side Radiator Install

Normally in a build, you’d start with chucking the motherboard in, but we’re starting in a different place. Because the top radiator can only go in once the distribution panel is installed, and the side radiator (which isn’t strictly supposed to be used with this distro panel) only fits if the distro panel isn’t installed yet, we’re starting there. A 360mm radiator doesn’t neatly fit in the bottom of the chassis without modification, and much like leaving empty RAM slots, I don’t like the 'incomplete' look that would result from a 240mm rad in this case.

(Image credit: Tom's Hardware)

We measured it out carefully and though we'd prefer the ports at the bottom, that wasn’t going to work. But with a bit of a squeeze, the EKWB 360mm SE radiator fit in just fine with the ports at the top.

(Image credit: Tom's Hardware)

We then installed the Noctua fans with their included radiator gaskets, which ensure no air leaks between the fan housing and the radiator. Believe it or not, the side panel still goes on smoothly, even with the filter, but there’s hardly any room to spare.

2. Distribution Panel Installation

Tom's Hardware

First, we had to drill some holes in the chassis where screws need to go through to secure the distro panel. A 4mm metal bit did the job nicely. I did immediately reach for the vacuum, as I didn’t want any of the metal filings getting to places where they don’t belong.

After this, the distribution panel slid in smoothly, fitting perfectly into place – as if it was made for it (because it was).

At this point, I could sense incoming issues, so I decided it might be best to install two 90-degree angled fittings on the side radiator early. The top radiator would make this extremely difficult once in place.

3. Top Radiator Installation

(Image credit: Tom's Hardware)

First, we prepared the top radiator by installing the fans onto it, along with the Phanteks Halo light rings. The long screws that came with the radiator were… too short. But, Phanteks knew this was going to happen, which is why the Halos come with slightly longer screws that were a perfect for reaching a radiator.

(Image credit: Tom's Hardware)

The top radiator then went in smoothly, and all the cables were tucked away to the rear to deal with later.

4. Motherboard Preparation

(Image credit: Tom's Hardware)

To make the installation easier, we installed the 3700X, Samsung 970 Evo Plus M.2 SSD, G.Skill Trident Z Royal memory, CPU, and EKWB EK-Velocity CPU block all before installing the motherboard. The memory drops right in, and so does the M.2 SSD, below the cover.

Installing the EKWB Quantum Velocity waterblock was also a breeze. First, we removed the stock AMD mounting bracket, including its backplate. The EKWB backplate together with its rubber gasket was then installed at the rear. Then, four thumbscrews are placed at the front end, a dab of Thermal Grizzly paste was applied to the CPU, the block dropped on, and secured with more thumbscrews. EKWB’s Precision Mount system really makes the CPU block installation a breeze – I’d go as far as saying this step is easier than installing many big air-coolers.

However, during this installation process, my cat decided to pick the moment I was lowering the CPU block into place to jump up from my lap, causing me to drop it, denting the heatspreader. Next to the dent is also a small outward bump. It’s not major, but I doubt it will do us any favors for thermals later on in the build. Fingers crossed.

5. Placing the Motherboard

Tom's Hardware

As much as it’s easier to install things onto the motherboard before installing it in the system, it does lead to one issue: the board becomes quite heavy. So be sure your cat is nowhere to be found before hefting the whole setup into place. After checking in all the usual hiding spots, I carefully placed the board and its components into place, secured it, and finally the system was starting to look like something.

However, at this point I noticed another issue: The CPU block's water ports sat about 1 cm lower than the ports on the distribution panel -- I would have to get creative to solve this.

Fortunately, I had some extra 45-degree fittings, so I grabbed four of these, along with one 14mm extender. This allowed me to get the ports at the correct height for lining up with the CPU block, making sure that the tubes would only need a single 90-degree bend later along in the build.

6. Waterblocking the Graphics Card

Tom's Hardware

Installing the waterblock on the graphics card was less precarious than you would think. It’s certainly a task to sit down and take your time with, but as long as you’re patient with your tweezers while placing the thermal pads and you're carefully with each step of the disassembly, cleaning, and re-assembly with the waterblock on, it’s really not all that scary. For more on this process, see our How to Install a Waterblock on a GPU feature.

About an hour and a half after starting, the EVGA RTX 2080 Super Gaming Black was converted into a shiny, thin, water-cooled GPU. We routed the D-RGB cable that leads to the lit-up ‘GeForce RTX’ on the side terminal under the acrylic part of the block that doesn’t actually cool. If you look carefully, you can spot its connector, but we doubt anyone will spot it once it’s installed, face-down in the system.

7. Figuring out the loop runs

Tom's Hardware

At this stage, we’re almost ready to begin our tubing runs, but because some of the parts didn’t fit quite as we had planned, we needed to spend some time thinking about future steps. This build has taught me that no matter how much you plan ahead when configuring your system, you’re still going to run into issues along the way and you’ll have to adapt.

At EKWB’s advice, we got more fittings than we thought we needed, and thank goodness for that. The adjustment for the CPU’s ports already ate up four 45-degree angled fittings, and incorporating our VRM block used up another two 90-degree angled fittings and a 45-degree fitting on the radiator at the top. Not counting the 14 mm extenders to line the ports up nicely. The GPU also didn’t line up nicely with the distro plate, despite being a reference card, so we used two more 45-degree angled fittings, along with two 90-degree fittings to line these up well.

To reach the side radiator’s ports at the top, we had to use the lower ports on the distribution panel. There is one port that's the outlet from the pump, which you naturally have to use. We chucked two 28-mm extenders on this one, along with a 90-degree angled fitting, which lined it up precisely with the angled fitting we had placed on the side radiator earlier, albeit with a long tubing run with one 90-degree bend in it. We placed the return line on the distribution panel at the top of a channel that would lead to the inlet of the GPU block, relying on another long tubing run with a 90-degree bend.

All in all, while it was certainly complicated, we’d call this stage a big success: With enough fittings, everything lined up such that each tubing run would require only one 90 degree or 45-degree bend, which is key to a successful hard-tube build if you’re a beginner.

8. Tubing

It might come as a surprise, but bending the tubing and fitting it into place was much easier than we expected. The GPU’s tubes were the easiest, requiring no bends at all, and the remaining tubes all required a maximum of one bend. These bends were also exactly 45 degrees or 90 degrees, meaning we could use the EK-Modulus tool to get them exactly right.

So we wet the silicon noodle insert, inserted it into the tubes, and warmed them up using a heat gun. Once they started giving way, we gave them a little extra time to soften up, careful to keep rotating them as we went along. For the side radiator, we bent the tubes too soon, which lead to light kinking, but those corners aren’t visible anyway – so they were good to learn on.

Once bent, we simply cut the ends off the tubes where needed, de-burred and sanded them down so they wouldn’t damage the o-rings, wet them with some soapy water, and test-fit them. In the end, it took a full day to get all the bits of tubing right, but we didn’t ruin a single piece –- it was easy enough, but required lots of patience.

9. Pressure testing, Installing Remaining Bits and Filling

Tom's Hardware

The genius/crazy person in me thought it would be a good idea to pressure test while I installed the last fans and took care of cable management on the other side, but I couldn’t have been more wrong. It turns out, the pressure tester works, but it’s an extremely finicky device. The needle will move at the slightest bump on the desk, which led me to believe my loop was leaky -- It wasn’t, though.

The trick to the pressure tester is to pump up the loop, close the valve, remove the pump, tap the pressure tester a few times to make the needle drop as much as it was going to by external force, and note down where it is on the dial. Then, close the door to the room, and leave. Do not touch the system. Don’t even breathe near it.

We checked on it periodically, and once it hadn’t dropped after two hours under pressure I was confident my loop was good. So, I unplugged all the cables on the PSU but the pump, jumped the ATX connector, and in the fluid went.

10. All done!

Tom's Hardware

Now that the system is up and running, I have a confession to make: This is the first time I’ve successfully built a custom loop with hard tubing. I attempted this before in 2015 when I did my first ever custom loop, but due to a lack of experience planning my bends, I ended up having to resort to soft-tubing to complete that build.

The Mirror Maze build, on the other hand, actually went quite well. The PC-O11 Dynamic is obviously an excellent foundation for a liquid build, and EKWB’s Quantum-Reflection distribution plate, paired with enough fittings, ensured I wouldn’t need more than one bend per tube. Sure, I ran into a few unforeseen hiccups during the build process, but these were easily sorted out. Even incorporating the Asus Crosshair VIII Formula’s VRM block into the loop went without a hitch.

Fan Curves, Overclocking and Thermals

Not everything went smoothly, though. Remember that I dropped the CPU block onto the Ryzen 3700X’s heatspreader during installation. And, as predicted, the tiny bump didn’t do thermals any favors. We didn’t need to run the chip at stock settings, but enabling AMD’s PBO (Precision Boost Overdrive) was the most I was comfortable with. With this, a Prime95 Smallest FFT’s load translated to a CPU temperature of 84.5 degrees, and the CPU boosted to 4002 MHz on all cores. That’s warmer than the CPU should run at under water, but it’s within norms and no cause for concern. So long as you get a CPU that's amenably to high clocks and you don't drop any of the key components, you should see better results here.

(Image credit: Tom's Hardware)

Next, I overclocked the EVGA RTX 2080 Super Gaming Black. Using MSI Afterburner we maxed out the card’s power limits (116%), and offset the core clock by +150 MHz and the memory by +1000 MHz. The GPU boosted to a stunning 2100 MHz under load, and under extended tests, the temperatures did not exceed 49 degrees in a 25 Celsius room. I was able to push the chip a little further to boost to 2115 MHz, and though it ran stable and temperatures were still in check, I saw some minor artifacting, so I backed off and kept it at the 150 MHz offset.

(Image credit: Tom's Hardware)

For cooling, I quickly found out a mistake in my loop: It lacked a sensor for coolant temperature. The pump speed we were able to fix at 35 percent, as this made it barely audible, and higher flow doesn’t help temperatures anyway. However, the fan speeds were driven by the CPU’s temperature, which isn’t helpful when the GPU is able to dump 250 watts (or more) of heat into the loop, but the loop isn’t instructed to dissipate this heat. This led the fans to ramp up far too quickly when the CPU briefly spiked in temperature. With some testing, I found that running the Noctua NF-A12x25 fans at 40 to 50 percent duty was more than enough to keep the system cooled well, with a solid safety margin, while remaining incredibly quiet. For reference, the coil whine produced by the graphics card isn’t loud, but it was audibly louder than the system’s cooling loop.

A future upgrade would therefore be to add a coolant temperature sensor to the loop, so that you'd be able to set a fan curve based off this reading and push the system to run even quieter. This would remove the noise spikes and only cool the fluid when it actually gets warm due to extended loads.

Nevertheless, we slapped on all the panels and dust filters and ran our usual 15 runs of Metro Exodus to simulate half an hour of gaming. This resulted in an average CPU temperature of 63.2 degrees Celsius, with an average GPU temperature of 46 degrees C. Those are good figures if you consider that both are overclocked. I also pulled out the dB meter and recorded a figure no louder than 38.8 dBA. If you’re familiar with my case reviews, you’ll know that that’s extremely quiet.

Gaming Performance

Tom's Hardware

Performance in gaming is also good. That’s no surprise of course given that this system packs a more powerful GPU than our comparison builds, the Disco Pixel and RGBaby, not to mention the Mirror Maze build is liquid cooled and overclocked.

Performance in Shadow of the Tomb Raider and Metro Exodus appears to scale the way it should, though in Red Dead Redemption 2 and especially GTA 5 we saw performance increases that cannot be explained. Trust me, I set all the graphic setting sliders to the highest level possible in order to get performance to go down, closer to my colleagues systems, but the Mirror Maze has an inexplicable, very significant lead in these titles. I honestly don’t know why – liquid cooling and overclocking helps, as do game updates, but not normally that much.

Conclusion

(Image credit: Tom's Hardware)

If you were to ask me what tips I could give you when doing your first hard tubing build, I would tell you to ensure you need no more than one bend per tube, get plenty of angled fittings, use a pressure tester -- and no, a distribution plate isn’t cheating (but it does make your life so much easier). Other than that, there’s no more to it than customizing the parts to your liking and taking lots and lots of time to do the build right. Because doing it wrong can be an expensive mistake.

The Mirror Maze build ended up roughly as I had expected it would. In terms of looks, the system means business by day with all the RGB lighting off. But at night, when it’s time to play, it’ll put on quite a show – either customized to your liking or going full-on rainbow.

Performance is impressive as well, with a lofty GPU overclock, and even so, the RTX 2080 Super’s core remained at a maximum temperature of 49 degrees C. Chuck a synthetic load on the CPU and GPU at the same time to maximize heat output, and the Noctua NF-A12x25’s easily manage to quietly keep thermals under control without even approaching what experienced gamers and enthusiasts would consider 'loud.'

The primary hurdle with a system like this -- and it's a big one, particularly in times like these -- is cost. The primary components (sans cooling) in our build will set you back ~$2,905, but with all liquid cooling and related bits, you'll looking at a price tag of about $4,350.

No one ever said custom, near-silent cooling on a high-end PC was going to be cheap. If you want to save yourself some time and money (OK, a lot of money) and don't mind taking a step down in the aesthetics department, you could opt instead for a good AIO cooler and and a premium headset to drown out the extra fan noise. But if you have the cash and time to spend on a custom loop, a build like our Mirror Maze will serve you well for several years to come, while standing out as a show piece wherever you decide to put it.

AMD Ryzen 7 3700X Drops to Record-Low $260, Includes Free Assassin's Creed Valhalla

Niels Broekhuijsen — Mon, 13 Jul 2020 16:19:30 +0000

While retailers are busy gauging prices on Intel CPUs, AMD is rearing its head with a mighty sweet, burning hot deal. The AMD Ryzen 7 3700X just hit an all-time low price of $259 on Newegg, and it comes with a free copy of Assassin's Creed Valhalla, the latest murderous title set to land November 17.

AMD Ryzen 7 3700X: now $260 with free Assassin's Creed Valhalla
AMD's Ryzen 7 3700X was already a chip we happily recommended to anyone building a gaming PC today, but this new deal makes the 8-core 16-thread chip an absolute steal.

This deal follows rumors that AMD would bundle Assasin's Creed Valhalla with the 3700X and above. And at this price, this CPU's just plain unbeatable for value shoppers. With the current 3700X pricing, you'd be silly to buy a Ryzen 5 3600XT for $249, and the Ryzen 7 3800X and 3800XT don't offer nearly the same value as the 3700X.

AMD's Ryzen 7 3700X comes loaded with eight of its new Zen2 CPU cores and 16 threads running at a base clock of 3.6 GHz and boosting up to 4.4 GHz with good CPU cooling. Now that AMD B550 motherboards are finally making their way onto the market too, it's a great time to build a new AMD-based gaming PC.

Acer Predator XB273U GS Hands-On: Strong IPS Colors Meet 1440p at 165 Hz

Scharon Harding — Tue, 23 Jun 2020 13:45:13 +0000

(Image credit: Tom's Hardware)

It seems like it was just yesterday that 144 Hz was the most speed you needed from a gaming monitor. But with the market offering ample 240 Hz screens and preparing to launch into 360 Hz territory, a screen with a 165 Hz refresh almost seems modest. But the Acer Predator XB273U GS I’ve been using for the past few days is far from modest.

With a 165 Hz refresh rate, a 1ms GTG response time that can drop to 0.5ms with overdrive, HDR support and an RGB strip along the bottom you can actually see while gaming, the Predator XB273U GS announced today is a premium 27-incher designed for professional gamers and available to the masses in August for $500.

Acer Predator XB273U GS Specs

Screen Size / Aspect Ratio	27 inches / 16:9
Max Resolution & Refresh Rate	2560 x 1440 @ 165 Hz
Panel Type / Backlight	IPS / LED
Native Color Depth / Gamut	8-bit / DCI-P3: 95%, VESA DIsplayHDR 400
Response Time (GTG)	1ms, 0.5ms with overdrive
Max Brightness	400 nits;
Contrast	1,000,000:1 dynamic
Speakers	2x 2W (optional)
Video Inputs	2x HDMI 2.0, DisplayPort 1.2a, 2x USB 3.0 (Type-A), 2x USB Type-A for light strip connection only
Power Consumption	30.06W

Acer Predator XB273U GS Design

Tom's Hardware

The Predator XB273U GS makes a showy addition to your setup. Very slim bezels frame three sizes, while the bottom bezel pops with a textured and gray design, although a more consistent color with the rest of the bezels would’ve fit my style better.

The RGB strips running along the bottom of the screen are a pleasant upgrade from the many RGB monitors that have their LED lighting on the back of the display, where your wall is most likely to be the one enjoying it. From the Predator XB273U GS’s on-screen display (OSD), you can make the RGB show a rainbow effect, a breathing one and static one with red, green or blue. And perhaps most importantly, you can also turn off the RGB if it’s too distracting, which I found to be the case for when watching a movie. The RGB uses Acer’s LightSense technology, which has the lighting sync up with music or what’s on the screen. There’s also a map for further customization if you really want to get into the pretty colors on your monitor’s bottom bezel. Hey, you’ve already spent the $500 for the PC monitor, so why not?

From top to bottom, I could see attention to detail on the Predator XB273U GS. An Acer Predator logo sits at the hexagonal base, which is outfitted with solid gray legs that are dense and thick. The stand makes it easy to adjust the monitor, particularly handy for getting just the right height and angle for a long gaming or work session. Adjustments are generous. You get a 20 degree backward tilt, 5 degree forward tilt and the ability to swivel left to right 20 degrees. The monitor’s height is also adjustable by 115mm (4.5 inches), and it’s easy to spin the display into portrait mode.

The Predator XB273U GS’s joystick for navigating the OSD was loud on our test unit, but we were told this is an early prototype, so this could change with the final retail versions.

In terms of color temperature settings, there’s warm, normal, cool, blue light and user for tweaks. There are also gaming modes for action, racing, sports, user, HDR, graphics, eco and standard. For testing, I used the monitor’s out-of-box settings, which used the warm color temp at 40% max brightness.

Acer Predator XB273U GS Hands-On

(Image credit: Tom's Hardware)

I’m used to gaming on a 1080p monitor, so the Predator XB273U GS’s sharper 1440p resolution was a noticeable upgrade. Finer details, such as the border around my Google Chrome extensions or close-ups of characters’ faces in Battlefield V cut scenes stood out in new ways.

In Battlefield V specifically, all sorts of gruesome details became more apparent, thanks to the monitor’s resolution and also the colors. Bloodstains smeared with fingerprints struck me for the first time. I could also discern more textures on the gun, such as its grip, as well as scratches on my weapon. Snow speckled on boxes looked a little sharper. The wooden walls of a shed were a much deeper brown.

Motion stayed sharp, including the shape of clouds as I scanned the area rapidly or when I was speeding through North Africa in a Jeep.

Similarly, in the fast-paced game Overwatch, I never suffered any juddering, stuttering or screen tearing. With an Nvidia GeForce GTX 1060, I was only able to hit about 60 frames per second in the esports title, but G-Sync Compatibility kept the experience smooth and tear-free. Meanwhile, variations in distant cliffs and mountains colors were more apparent than usual.

For general productivity, the monitor also served well. I work in a very sunny room that gets impressively bright. With the monitor set to 40% brightness, I could still get work done, although I preferred boosting it up to the max.

With IPS tech, we’d expect the picture to still look good and visible when viewing it from a side angle. And Acer leans into this with all the tilting and swiveling it allows on the Predator XB273U GS. With the monitor right next to a very sunny window, text was still readable from a perpendicular angle, but I could see reflections on the half of the screen furthest from me. At night and in a more typically lit room, those reflections were only on the further tenth of the screen.

The screen’s side angles were so accommodating that it was comfortable sharing the screen to watch Mission: Impossible Fallout in HDR.

With a VESA DisplayHDR 400 rating, this won’t be the best HDR monitor on the market when it lands in August (we prefer at least DisplayHDR 500 for a worthwhile boost over SDR when gaming). With out-of-the-box settings, the movie looked a little washed out. It’s possible that some hardware-assisted calibrating would’ve helped, but I wasn’t able to quickly make great improvements with some casual adjustments. But when I turned the monitor’s HDR mode on, color instantly improved. The gray concrete building Tom Cruise hung from at night had a greater variety of dark grays and beiges. A glass ceiling was a faint yellow without HDR mode on and orange with HDR on. Characters’ skin colors became more accurate, and lights in a dark tunnel the Impossible Mission Force held a sting in had a powerful yellowish tone.

SDRTom's Hardware

HDRTom's Hardware

However, considering the movie’s colors didn’t look great to begin with without HDR mode, I turned to an SDR version of the movie. I could see subtle differences between watching the movie in SDR and HDR, but the SDR version of the film never looked as washed out as the HDR version did before I turned HDR mode on.

The monitor’s two 2W speakers were loud enough to hear quiet dialogue, but not powerful enough for the booming effect that I’m used to with a TV.

Final Thoughts

At $500, the Predator XB273U GS will be a little more expensive than our favorite 1440p monitor at the moment. The Aorus CV27Q was $400-$430 when we first reviewed it in November and still is. It’s also listed on our Best Gaming Monitors page.

With the addition of RGB, speakers and an IPS panel, we see the price start adding up. However, some will be happy with the VA that the Aorus offers, which grants excellent contrast, or the even more budget-friendly TN.

Most importantly, the Predator XB273U GS brings the potential to improve on color. The Aorus CV27Q, for example, covered 86% of the DCI-P3 color space in our testing, compared to the Predator XB273U GS’ claimed 95%. For lavish, detailed games, speedy performance and HDR, the Predator XB273U GS looks like a strong contender.

AMD Ryzen 7 3700X CPU Is Cheaper Than Ever

Michelle Ehrhardt — Tue, 16 Jun 2020 21:47:46 +0000

AMD’s Ryzen 7 3700X desktop CPU is now $55 off on Newegg, bringing it down from its original $329.99 price to $274.49 on Newegg. That’s 17% off overall and the lowest price this CPU has ever seen.

The price drop is likely due to AMD announcing the Ryzen XT 3000-series today, which introduced us all to the Ryzen 3900XT, 3800XT and 3600XT. Regardless, we don't expect those CPUs to offer a massive gain in performance over the standard Ryzen 3000 CPUs. The Ryzen 7 3700X is still a great chip with eight CPU cores and 16 threads. Slotting into the AM4 CPU socket, the chip supports DDR4 RAM and runs at a base clock speed of 3.6 GHz with a max boost frequency of 4.4 GHz.

AMD Ryzen 7 3700X: was $329.99, now $274.49 at Newegg
AMD’s Ryzen 7 3700X CPU is an eight-core, 16-thread processor that slots into AM4 sockets and supports DDR4 memory. It runs at a base clock speed of 3.6 GHz and a max boost speed of 4.4 GHz.View Deal

In our AMD Ryzen 7 3700X review, we recorded the CPU hitting an average 140 frames per second in The Division 2 on Ultra settings. It also scored 16,616 on PCMark 10’s Excel benchmark. That’s good performance for its clock speed, which we attributed to the Ryzen 3000-series’ generational IPC uplift.

AMD’s non-mobile Ryzen 4000 series has yet to be announced, but the Ryzen 7 3700X should keep you set in the meantime.

AMD Ryzen 7 3700X Is on Sale for an All-Time Low $260

palcorn@outlook.com (Paul Alcorn) — Thu, 04 Jun 2020 20:51:06 +0000

(Image credit: Micro Center)

AMD's Ryzen 7 3700X CPU is selling for $260 at Micro Center, which is the lowest price we've ever seen for this CPU.

Powered by Zen 2, AMD's Ryzen 7 3700X features eight 7nm CPU cores and 16 threads . Those cores run at a 3.9 GHz base clock and boost up to 4.4 GHz within the chip's 65W TDP envelope.

AMD Ryzen 7 3700X : was $329, now $260 @ Micro Center
The Ryzen 7 3700X boasts AMD's Zen 2 microarchitecture paired with the 7nm process. Our testing shows it offers tremendous performance across eight cores and 16 threads. View Deal

In our AMD Ryzen 3700X review, we determined that the returned gaming frame rates were around 20% higher than its direct predecessor, the AMD Ryzen 7 2700X. This discounted CPU also provided great productivity performance, often matching or exceeding its closest rival, the Intel Core i7-9700K. Plus, on rendering and encoding tasks, AMD's chip usually came out ahead.

The Ryzen 7 3700X is also on sale at Amazon for $274.49.

The Disco Pixel PC: Building a Flashy, Formidable Mid-Tower in InWin’s 309 Case

Matt Safford — Wed, 29 Apr 2020 14:32:31 +0000

From the moment I first saw InWin’s 309 mid-tower case back at Comptex 2019, I was intrigued by its unique 144-pixel front panel and slick-looking GLOW2 software that lets you design your own light show right on your PC. So when the company offered up the case right as much of the world started heading toward a pandemic-induced lockdown, I grabbed parts for a build that would be both colorful (including Lian Li’s Strimer Plus and some RGB RAM from Adata ) as well as capable. The core components include one of the best gaming CPUs, AMD’s Ryzen 7 3700X and Nvidia’s RTX 2070 Super Founders Edition, our current pick for the best graphics card for 1440p gaming.

Holed up inside my home office, I got to assembling a system that was certain to brighten my days spent in relative isolation. I wasn’t sure what I’d call it when I started showing it off to colleagues over video chats, everyone (of a certain age) said it reminded them of the disco days and lo, the Disco Pixel Build was born.

Having recently worked on the jam-packed RGBaby build, it was a relief to be building in a roomy mid-tower case again, where there was actually a reasonable amount of room for components, cables and the fingers required to fiddle with them. But that doesn’t mean everything about this build was simple.

Storage wasn’t a problem, as I just went with what I had and slipped a 2TB Intel 660p (it’s a good budget drive, but not currently one of the best SSDs) in the first M.2 slot under the heat spreader of Gigabyte’s X570 Aorus Master motherboard. But InWin also sent along six of its Sirius Loop ASL120 fans. And the spinners do have built-in fan and ARGB splitters so you can helpfully daisy chain them together. That meant I could plug them into headers on the board rather than having to wire everything to some kind of RGB/fan hub. But I can now tell you from personal experience that three-pin RGB connectors get very finicky when you try and string six of them together and onto a motherboard connector. I eventually had to resort to electrical tape to hold them together, and even then it seemed like one or more would occasionally disconnect when I so much as looked at the system sideways.

Before I get too much more into the joys and frustrations of the Disco Pixel PC, let’s take a closer look at the parts I used.

Components for Disco Pixel PC Build

(Image credit: Tom's Hardware)

Case: InWin 309

The brighter, edgier (and I’d argue sleeker) followup to the 307 that launched in 2018, InWin’s 309 is a tempered-glass midtower case with an eye-catching front panel that packs in 144 bright, addressable pixels. You can control the light show via buttons on the front-left edge, and switch between a number of built-in patterns (including some awesome retro-arcade designs), or you can design your own patterns via the company’s surprisingly slick and capable GLOW2 software.

While the light show up front is second to none, the 309 can be challenging -- or at least counter-intuitive -- from an airflow perspective. The front panel is completely closed off from air, due to the addressable pixel array, and the top is a solid sheet of steel. Given that, it’s unlikely that the 309 would wind up on our list of best PC cases. There are some cutouts on the steel right side panel of the case, but the vast majority of the system’s airflow is going to have to come in from the mesh bottom and be exhausted out of the back.

This is further complicated by the fact that the current iteration of the InWin 309 ships without any fans at all. But the company did send us six of its neon-like RGB Sirius Loop fans to get the air moving. We could have actually used a seventh.

CPU: AMD Ryzen 7 3700X

What’s left to be said about AMD’s Ryzen 7 3700X? It’s been around for going on a year, but its 8 cores, 16 threads, and current sub-$300 price means it’s still sitting pretty on our best gaming CPUs page as the best overall value, offering double the threads of Intel’s pricier Core i7-9700K, while still delivering very good gaming and productivity performance. Plus, it includes an attractive bundled cooler.

CPU Cooler: AMD Wraith Prism

If the world weren’t upside down right now, we probably would have gone with an AIO for this build. But many etailers are experiencing shipping delays, our lab is currently locked down in Midtown Manhattan, and I didn’t want to deal with the hassle of trying to get one of our off-site writers to ship me something else. The fact of the matter is, AMD’s Wraith Prism is more than good enough, delivering solid cooling, a little room for overclocking, and an RGB light ring and fan--all in a compact, easy-to-install package that comes free in the box with AMD’s Ryzen processor. It’s hard to argue with free, especially when it’s this capable, pretty, and Intel doesn’t ship a cooler with its unlocked processors at all.

Graphics Card: Nvidia GeForce GTX 2070 Super Founders Edition

This is another area where, given different circumstances, we probably would have gone with a flashier GPU with RGBs and some out-of-the-box overclocking. But the 2070 Super Founders Edition was close to hand, a capable performer, and I’d argue that--while it doesn’t light up beyond the GeForce RTX logo--its silver metal shell makes it prettier than the vast majority of third-party cards. That’s 1,000 points for aesthetics, Nvidia. But even at idle, I can hear the card’s fans spinning from across the room as I write this. Maybe it’s time to implement a zero-RPM fan mode like many of your third-party partners?

Motherboard: Gigabyte X570 Aorus Master

For what I installed in it, the ATX Gigabyte X570 Aorus Master is arguably overkill, with its three M.2 slots, 2.5GB Ethernet and Wi-Fi 6. But who doesn’t love next-gen connectivity and expansion options aplenty.The board also looks good, and its RGB and fan headers are laid out in such a way that most were exactly where I wanted them for this build. How often does that happen?

Power Supply: Corsair RM 750x

The power supply gets mounted up top, behind a honeycomb-cut chamber in this case, so it’s not all that visible. I went with Corsair’s RM 750x because it’s fully modular and has enough wattage headroom for substantial future upgrades. Its fan also sits at idle during low loads, which is something I wish Nvidia could figure out with its FE graphics cards.

RAM: 32GB DDR4-3600 Adata XPG Spectrix D41

3600 MHz is the sweet spot for Ryzen 3000 support, so I went with Adata’s Spectrix D41 3600 kit, which brings aggressive red metal heat spreaders and some diffused RGB glow up top. While the red of the spreaders doesn’t really match the rest of the interior, with four sticks jammed in close together, all you can really see of the memory is the RGB lighting on the top edge, anyway.

Storage: 2TB Intel 660p

In different times, we’d have probably gone with a PCIe 4.0 SSD with this build, to take advantage of one of X570’s key features. But as I started thinking about assembling this build, I remembered I had a spare 2TB Intel 660p in an external enclosure that I’d bought last year when a third-party seller was very briefly offering it up for less than $103. I didn’t exactly need it at the time, but how do you pass up a nickel-per-gig for PCIe solid-state storage?

For the last six months or so, the drive has been living inside an M.2 enclosure as a seriously roomy and fairly speedy external SSD. Now it lives behind a metal heatsink as the sole storage device inside the Disco Pixel PC. Sure, it doesn’t have any lights, but it’s not like you’d be able to easily see a lit-up M.2 drive with everything else we’re putting in this build, anyway.

Fans: 6x Sirius Loop ASL120

The version of the Inwin 309 case that the company is currently selling ships with no fans--something that’s becoming increasingly common in cases where companies know you’re going to be designing a showy build, and so will likely want to use specific spinners from another company.

For our purposes, InWin sent along a pair of three-packs of its Sirius Loop ASL120 fans. They aren’t the most vivid of RGB air movers, but the thin neon-like light strip that runs around the outside looks downright understated compared to the front panel and our next component. For the sake of symmetry, we installed three on the bottom as intakes, and three up top where a radiator might go if you were installing one in the case. As noted earlier, we would have liked a seventh fan to use for exhaust, and for long-term use with this system, we’d move one of the fans from up top if need be. But we left the three fans up top here because it looked the best that way and we weren’t easily able to get another matching fan for exhaust.

RGB Cable Extensions: Lian Li Strimer Plus

Perhaps the only RGB product that could visually compete with the 144-pixel front panel of the Inwin 309 case is Lian Li’s updated Strimer Plus RGB extension cables. I had these on hand from our recent review, and they were an obvious pairing for such a vivid build. Plus, unlike with the too-cramped RGBaby build, there was actually room here behind the motherboard for the extra ATX and PCIe power cables that result from using the sleeved Strimer Plus extensions.

	Product	Cost
PC Case	InWin 309	$199.00
CPU	AMD Ryzen 7 3700X	$294.14
CPU Cooler	AMD Wraith Prism	(included with CPU)
Graphics Card	Nvidia GeForce GTX 2070 Super Founders Edition	$499.99
Motherboard	Gigabyte X570 Aorus Master	$359.00
Power Supply	Corsair RM 750x	$149.99
RAM	32GB DDR4-3600 Adata XPG Spectrix D41	$127.99 (x2)
Storage	2TB Intel 660p	$219.99
Fans	6x Sirius Loop ASL120	$25.08 (x2)
RGB Cable Extensions	Lian Li Strimer Plus (24-pin, PCIe	$89.98
TOTAL		$2,118.23

(Image credit: Tom's Hardware)

The Disco Pixel build started off simple enough, by popping the top M.2 heatsink off the Aorus motherboard and installing the Intel SSD 660p underneath.The heatsink’s thermal pad is pre-installed, so once you peel off the protective plastic, the SSD just sticks on; you then slide it into the drive slot and screw down the heatsink. That was simple.

(Image credit: Tom's Hardware)

Installing the Ryzen CPU and ADATA RAM was similarly easy and as expected.

(Image credit: Tom's Hardware)

The memory is a bit bulky with its heatspreaders and RGB lights, but I’m using a stock AMD Wraith Prism cooler here, so installation isn’t going to be a problem.

(Image credit: Tom's Hardware)

Also at this stage, I connected the RGB cable to the Wraith cooler and plugged both it and the fan header into the motherboard.

(Image credit: Tom's Hardware)

Having completed the first few steps without issue, I set the motherboard (and my sheepskin rug) aside to break out and strip down the case. My furry build buddy gave me a one-eyed nod of approval. Her depth perception isn’t the best, but she’s still a harsh critic of my cable routing skills.

Tom's Hardware

After working in the Min-ITX RGBaby’s Jonsbo case, the InWin 309 feels positively massive, even though it’s just a mid-tower. It’s also worth pointing out that this is a hefty chassis, even when empty. With its steel shell, glass side and front, and the electronics housed up front, it weighs 30 pounds all on its own.

Thankfully for my back, once I removed the side panels and an unneeded steel plate for mounting 2.5-inch drives, the case was easier to manipulate--at least until I started putting parts in it. First to go in was the power supply up top, behind the honeycomb section, followed by dropping in the motherboard. The latter has a pre-installed IO plate, which means installing the board was as simple as putting it in place and screwing it down on the standoffs.

(Image credit: Tom's Hardware)

Also note in the image above the generous port panel on the front-left edge. Aside from USB 3 and USB-C ports, you get separate audio jacks, power and reset buttons, and controls for the front-panel lighting, which we’ll get to in detail later.

(Image credit: Tom's Hardware)

Next in was the graphics card. But first I installed a handy metal support bracket that InWin includes with the case to keep hefty GPUs from sagging in their slot. It wasn’t really necessary with the standard 2070 Super, but I figured I’d put it in anyway. It attaches to slots on the motherboard tray via two screws, and can be slid up and down to fit the placement and thickness of your graphics card.

Next, it was time to start plugging in all the requisite cables. That included the usual front-panel (aided by the motherboard’s inclusion of a G-connector that lets you plug in all the headers first, then plug the whole thing into the board), USB, and power supply connectors.

The case itself also requires connecting to a SATA power connector for the front pixel array. I also plugged in the optional 5V RGB header that lets you control the case lighting via RGB software from most of the major motherboard makers. As it turns out though, the physical control buttons on the side of the case as well as InWin’s surprisingly good Glow2 software do a much better job of letting you control the case’s versatile light show.

Speaking of lights, I also installed the Strimer Plus cables at this point. And I had to do this more than once because the main ATX Strimer cable had the lights on the wrong side for the purpose of this build. So I had to remove the light strip from the top of the cables and pop off the cable combs, which only have clips on one side to hold the light tubes. This is a tedious process, but fairly straightforward once you get a clear sense of what you’re doing.

Also note that the Strimer Plus lets you control its lights by plugging it into the motherboard. But just as with the case, I soon learned the lighting effects are much more dynamic if you use the buttons on Lian Li’s included control box, so I plugged that in, set the lights the way I wanted, and stuffed it behind the motherboard tray with dozens of other cables. After this install and testing and reviewing the original Strimer, I think I’m pretty far along in the Tom’s Hardware RGB doctorate program.

(Image credit: Tom's Hardware)

With the RGB cables and all the core components in place and connected, I plugged the system in to see if everything would light up and boot. The system lit up like neon Christmas and the system saw my boot drive, so I went ahead and installed Windows so I could also play with the Glow2 software a bit. But I still like the default random twinkling pixel pattern at least as much as any of the other options.

With the core components, OS, and lots of glowing things all working as expected, it was time to install the fans -- three in the bottom and three up top. The good news is that the fans have splitters for both the RGB headers and fan connections, so you can daisy chain them to each other. And the motherboard actually has fan and RGB headers placed conveniently along the top and the bottom of the board.

(Image credit: Tom's Hardware)

The bad news? While the above made the initial install of the fans easy -- I just screwed down three as intakes in the bottom and three in the top so their light rings would show clearly -- when I thought I’d plugged everything in and fired the system back up, only three of the six fans (one on the bottom and two up top) actually lit up.

RGB lighting headers are finicky enough when you’re just trying to get one to stay on your motherboard. But connecting six of them together (in two three-fan chains) meant that the pin connectors pulled themselves apart with almost no effort. In fact, just putting the right side panel on the case was what had pulled them apart the first time.

After a few frustrating attempts to push the RGB headers back together on their own, only to have them come apart when I adjusted something else in the case, I dug out some electrical tape and taped all the pin connectors together where one header met another. This is far from pretty, but at least there’s lots of room in the case to hide cables. For the fans up top, most of the unsightly taped-up cables get stowed behind the fans in the power supply chamber. Down at the bottom, there’s a decent amount of space behind the rear edge of the fans to just tuck the unsightly cable mess.

Tom's Hardware

With the fans finally working, there was little left to do on the build front other than some final wire cleanup (much of which I had done during the process of messing with the fan cables), attaching the Wi-Fi antenna (important because there’s no Ethernet port near my work bench), and start taking photos of the finished system in between installing all the necessary drivers, OS updates, and software required for setting up and benchmarking a new build.

Thankfully, the trio of silver buttons on the front of the case let me cycle through the ample lighting presets so I could get a good sense of what that 144-pixel panel was capable of. There are some interestingly retro presets here, and even a clock.

Tom's Hardware

MORE: Best Gaming Desktops

MORE: How To Build A PC

MORE: All PC Builds Content

The InWin 309 is definitely a unique case, with striking visuals up front and a nice selection of ports running down its left side. The left side panel is also tempered glass, with one of the easiest-to use mounting/removal mechanisms we’ve seen in a case yet. Depress the handle up top and the door lifts out and off. Drop it back in the bottom of the case and close the top, and everything pops easily and securely back into place.

Its main drawbacks are its $200 price (which is a lot to pay, especially when you consider you’ll have to bring your own fans) and the fact that the blocked-off front and top means airflow is more restricted than on most cases. There’s plenty of room for components though, so as long as you mount fans in the right places, keeping things cool shouldn’t be a problem. Even with our lack of an exhaust fan, the core components didn’t get too warm. But of course, your mileage will vary, depending on the components you use.

The trio of buttons on the edge of the InWin 309’s front panel mean you can do a lot with the case’s lighting without installing any software. But you’ll probably want to grab the company’s Glow2 software, because it’s stable, intuitive, and will let you do even more with that 144-pixel front panel.

(Image credit: Tom's Hardware)

From the main window of Glow2, you can change the color, brightness, and speed of the 11 pre-set visuals. Note that the Candle and E.C.G. presets react to the sound in your room thanks to a microphone built into the top of the case. The Music preset reacts to music, games or whatever is playing on the system itself--any audio playing in Windows seems to trigger the front pixels to light up with the Music preset is selected.

You can also choose to let your motherboard control the lighting. But the lighting options in most motherboard software are far less versatile, intuitive, and visually striking as what you’re about to create with Glow2.

(Image credit: Tom's Hardware)

The Creation option in the Glow2 software lets you import or “draw” your own patterns and save them to one of four frames. Controlling the transition between them means you can even create some crude animation effects. The only real limitation is the resolution. With 8 pixels across and 18 down, representing anything but the most basic of images is next to impossible. Even the Tom’s Hardware hammer was too complex to really pull off on the front of the InWin 309. But abstract patterns, particularly the Twinkling preset, sure look good.

The software is also handy for those times you don’t want to be blinded by the light. There are seven levels of brightness, with the highest being arguably too bright for a dark room, and the lowest turning the lights off completely. As much as we light pretty lights, there will always come a time when you want the light show to go away while you watch a movie or get some sleep.

Performance and Temperatures

On the performance side of things with the Disco Pixel build, we were aiming for “good enough” more than true top-end performance. Still, with an 8-core AMD Ryzen 7 3700X, 32GB of DDR4 3600 RAM, a 2TB Intel 660p NVMe SSD and an Nvidia GeForce RTX 2070 Super behind the light show, this system is no slouch. But it does often get outperformed by our previous RGBaby build, with its 12-core Ryzen 9 3900X CPU and Zotac RTX 2080 AMP graphics.

The Disco Pixel delivered a Geekbench 5 score of 7804, or about 26% less than the RGBaby’s 10519 showing on the same test. On Cinebench R20, the Disco Pixel’s multi-core score of 4500 was also substantially lower than the RGBaby’s 6915. But in the single-core version of the test (which is arguably more important for gaming), the Disco Pixel’s 472 wasn’t that far off from the RGBaby’s 494.

Tom's Hardware

As for gaming performance, the Disco Pixel also did well, often sticking close to or outpacing the RGBaby with its RTX 2080, and pushing above 60 frames per second (fps) at 1080p on all of our test titles. Just note that if you plan on gaming at 4K, you’ll want to dial down some in-game settings for the most-demanding titles, or opt for a higher-end card like an RTX 2080 Super.

To temperature test the Disco Pixel, we ran Metro Exodus 15 times on a loop to simulate roughly half an hour of gaming. The CPU measured an average of 66.8 degrees Celsius (152.2 degrees Fahrenheit) and the GPU measured an average of 68.3 degrees Celsius (154.9 degrees Fahrenheit). Both of these temperatures are well within thermal limits, but the CPU temperature is a bit high given that we were running the processor at stock settings and a gaming load is generally much less stressful than many time-consuming CPU-specific tasks. If you want to overclock or you plan on doing lots of CPU-specific productivity work, we’d definitely recommend installing an exhaust fan to help eject warm air, as well as going with a higher-end cooler than the AMD stock model we installed here.

Conclusion

(Image credit: Tom's Hardware)

The Disco Pixel is one of the most colorful PCs we’ve ever built, thanks in large part to the InWin 309 case and Lian Li’s Strimer Plus cables. I know plenty of people don’t appreciate RGB lighting, but with so many of us stuck at home, it felt like a good time to build something visual, versatile, and powerful enough for some serious gaming and productivity.

If I had better access to parts, I would have installed a seventh matching fan at the back for exhaust, and probably a PCIe 4.0 SSD and extra storage to take better advantage of the Aorus X570 board’s plethora of features. But as it stands, the Disco Pixel is plenty powerful for most mainstream tasks, from high-speed gaming and streaming to video editing. It also lights up a room like no other PC I’ve ever assembled. But after another round of dealing with excessive RGB wiring and software, I’d be lying if I said I wasn’t looking forward to a future build with as little lighting as possible.

MORE: Best Gaming Desktops

MORE: How To Build A PC

MORE: All PC Builds Content

Corsair's New Vengeance Desktops Are All AMD

Andrew E. Freedman — Thu, 23 Jan 2020 15:03:28 +0000

Corsair's Vengeance gaming desktop lineup is back with a, well, vengeance. The company is releasing a new line, the 6100-series, stocked entirely with AMD-based parts and components by Corsair itself.

There are two options: the Vengeance 6180 and the Vengeance 6182. The two are almost identical, with an AMD Ryzen 7 3700X, 16GB of Corsair Vengeance RGB Pro RAM, an AMD Radeon RX 5700 XT, Corsair Hydro Series H100i RGB Platinum liquid cooling, Corsair RM650 80 Plus Gold CPU and a 2TB, 3.5-inch HDD.

The differences are that the 6180 comes with an AMD B450 motherboard and a Corsair Force MP510 480GB SSD, while the 6182 uses an X570 chipset and a Corsair Force MP600 1TB SSD. Corsair hasn't specified which vendors' motherboards it is using.

Corsair

These will start going on sale today, with the 6180 going for $1,999. The pricing hasn't been announced for the 6182.

Ryzen 7 3700X Now at $299, a Savings of $30

palcorn@outlook.com (Paul Alcorn) — Sat, 30 Nov 2019 22:19:15 +0000

(Image credit: Wal-Mart)

AMD's Ryzen 3000 series processors are all the rage this Black Friday (just ask Intel), and now you can scoop up the Ryzen 7 3700X for a mere $299 at Wal-Mart, which is $30 off the list price. Even though we've seen this processor retail as low as $290 for the Black Friday season, this deal is still a steal.

AMD's Ryzen deals have been off the chain this Black Friday, but most of those savings have come on previous-gen chips, and with the company's newest 7nm silicon flying off shelves at full pricing, finding a current-gen proc at reduced pricing is a rarity. That makes this 3700X deal all the sweeter.

The Ryzen 7 3700X comes with eight fully-enabled 7nm cores and 16 threads powered by the Zen 2 microarchitecture. The cores run at a 3.9 GHz base frequency and boost up to 4.4 GHz within the chips' 65W TDP envelope.

AMD Ryzen 7 3700X at Wal-Mart: was $329, now $299

AMD's Ryzen 7 3700X comes armed with the company's Zen 2 microarchitecture paired with the 7nm process, delivering tremendous performance across its eight cores and 16 threads at a great price point. View Deal

In our review of the AMD Ryzen 3700X, we noted that it returned gaming frame rates that were around 20 percent higher than its direct predecessor, the Ryzen 7 2700X. It also provides great productivity performance, often matching or exceeding Intel's Core i7-9700K. And on rendering and encoding tasks, it usually comes out ahead.

If you're looking for a different processor, check out our best Black Friday CPU deals or Best Ryzen Deals pages. For AMD fans, we've also got a list of the best Radeon deals.

AMD Ryzen 9 3900X and Ryzen 7 3700X Review: Zen 2 and 7nm Unleashed

palcorn@outlook.com (Paul Alcorn) — Thu, 21 Nov 2019 15:40:00 +0000

AMD's launch of the Ryzen 3000 series processors marks an occasion that was nearly unthinkable a few short years ago: AMD has taken the process lead over Intel by fielding new 7nm processors that contain smaller and more densely-packed transistors than Intel's competing 14nm chips. The advantages of increased density come in the form of higher performance, better power efficiency, more cores, and more cache packed into a smaller area than the first-gen Ryzen models, all of which, as you can see in our CPU Benchmark Hierarchy, makes third-gen Ryzen a potent adversary for Intel both on the desktop and in the data center.

AMD paved the way for the 'Matisse' Ryzen 3000 series several years ago when it unveiled the revolutionary chiplet-based Zen microarchitecture. At the time, AMD laid out a roadmap that included a steady cadence of tick-tock-like updates interspersed with new revisions of the scalable microarchitecture. After the company's sophomore effort with the second-gen Ryzen processors, which featured a faster process paired with the same first-gen Zen design, the company is plowing forward with its Zen 2 architecture that AMD says offers up to 15% more instructions per cycle (IPC). Paired with the advantages of the 7nm process and more cores, not to mention AMD's trailblazing of the PCIe 4.0 interface on desktop platforms, the Ryzen 3000 chips promise an explosive step forward in performance.

AMD's first chips to come packing TSMC's 7nm process span the entire range of the mainstream desktop stack, but push core counts up from eight cores to 12 cores and 24 threads with the Ryzen 9 3900X we have in the lab today, upsetting the status quo and bringing mainstream platforms into what used to be the realm of the pricey high end desktop. If you're looking for something even beefier, AMD also recently released the 16-core Ryzen 9 3950X, which has taken our best CPU list by storm.

	SEP (USD)	Cores / Threads	TDP (Watts)	Base / Boost Frequency (GHz)	L3 Cache (MB)	PCIe 4.0 Lanes
Ryzen 9 3950X	$749	16 / 32	105W	3.5 / 4.7	64	24
Ryzen 9 3900X	$499	12 / 24	105W	3.8 / 4.6	64	24
Ryzen 7 3800X	$399	8 / 16	105W	3.9 / 4.5	32	24
Ryzen 7 3700X	$329	8 / 16	65W	3.6 / 4.4	32	24
Ryzen 5 3600X	$249	6 / 12	95W	3.8 / 4.4	32	24
Ryzen 5 3600	$199	6 / 12	65W	3.6 / 4.2	32	24

Aside from those halo parts, AMD also has plenty of models that address the bulk of casual users, gamers, and enthusiasts, like the eight-core 16-thread Ryzen 7 3700X we also have in the lab, and a lineup of six-core 12-thread Ryzen 5 models. The Ryzen 7 3700X is particularly impressive with its combination of price and performance putting it squarely among the best gaming CPUs.

AMD is staying true to its enthusiast-friendly roots: Although you can pair the Ryzen 3000 chips with the new X570 chipset, they are also backward compatible with most AM4 socket motherboards. All of the models also come with beefy stock coolers, solder thermal interface material between the heat spreader and die to improve thermal transfer, and unlocked multipliers for easy overclocking. AMD even added support for auto-overclocking for mainstream processors. Pair that with the lower per-core pricing and the debut of the PCIe 4.0 interface for the desktop, and the Ryzen 3000 series appears to be a potent force.

AMD's ability to deliver on its optimistic roadmap in the waning light of Moore's Law is truly impressive, especially as we have become accustomed to never-ending cadences of incremental updates. But at the end of the day it all boils down to real-world performance. Let's see what the Ryzen 3000 series has in store.

Ryzen 9 3900X

	Process	SEP / RCP (USD)	Cores / Threads	TDP (Watts)	Base Frequency (GHz)	L3 Cache (MB)	PCIe Lanes	Memory Support	iGPU	Price Per Thread
Intel Core i9-9920X	14nm	$1199	12 / 24	165W	3.5 / 4.4	19.25	16 Gen3	Quad-Channel DDR4-2666	No	$49.95
Ryzen 9 3900X	7nm	$499	12 / 24	105W	3.8 / 4.6	64	24 Gen4	Dual-Channel DDR4-3200	No	$20.79
Threadripper 2920X	12nm	$625	12 / 24	180W	3.5 / 4.3	32	64 Gen3	Quad-Channel DDR4-2933	No	$26.04
Core i9-9900K	14nm	$488	8 / 16	95W	3.6 / 5.0	16	16 Gen3	Dual-Channel DDR4-2666	Yes	$61

Make no mistake - from a core count perspective, the $500 12-core 24-thread Ryzen 9 3900X really has no comparison on the mainstream desktop. We have to reach up to Intel's high end desktop (HEDT) platform to find a fair comparison based on core counts. Intel's Core i9-9920X slots in with 12 cores and 24-threads for $1,199, a $700 premium over AMD's Ryzen 9 3900X.

There's no doubt the 3900X also blurs the line between the AMD's own HEDT Threadripper platform and the mainstream desktop: The Threadripper 1920X is AMD's only core-comparable processor. That processors has its own advantages, like access to 64 lanes of PCIe 3.0, and like the -9920X, it supports quad-channel memory. But both company's HEDT chips are much more expensive than the 3900X and require pricey HEDT motherboards.

Back in the familiar realm of the mainstream desktop, Intel's $488 Core i9-9900K serves as the 3900X's primary competitor. The -9900K comes with four fewer cores and eight fewer threads than the 3900X, marking a distinct difference in the price you pay per thread, but the -9900K does hold the clock speed advantage. AMD hopes to offset that advantage with its increased IPC throughput and the 3900X also supports the PCIe 4.0 interface with twice the bandwidth of the -9900K's PCIe 3.0 interface. You'll also notice the Core i9-9900K, known for its high power consumption and intense heat generation, has a lower 95W TDP than the 3900X's 105W rating. We can chalk that up to different measurement techniques. We'll provide extensive power and efficiency testing on the following pages to get a more accurate picture of actual power consumption.

As pictured here, the 39000X comes packing AMD's Zen 2 microarchitecture spread across two small 7nm eight-core compute chiplets tied together with the Infinity Fabric interconnect via a larger 12nm I/O die (IOD). Each small 3900X compute chiplet, referred to as a CCD (Core Chiplet Die), comes with eight physical cores spread across two four-core Core Complexes (CCXes). Each CCX has 16MB of shared L3 cache, totaling 32MB of L3 cache per CCD, and 64MB of total cache for the entire chip. AMD disables two cores per CCD to create the 12-core 3900X.

Each 7nm CCD measures ~74mm² and has 3.9 billion transistors, while the 12nm IOD is ~125mm² and has 2.09 billion transistors. That means the 3900X comes with ~273mm² of silicon that sports ~9.89 billion transistors.

The 3900X's larger cache comes courtesy of the denser 7nm manufacturing process, but it does have a slightly higher latency (on the order of "five or six" clocks) than the 16MB of L3 cache found on previous-generation models. However, the increased capacity allows the processor to store more data closer to the execution cores, thus increasing cache hit rates that ultimately yield more performance. AMD also decreased the size of its L1 instruction cache from 64KB with the first-gen Zen processors to 32KB for Zen 2 chips. This allowed the company to expand its microop cache, and paired with changing the L1 instruction cache from 4-way to 8-way associativity, AMD feels this provides a more balanced approach to its cache subsystem.

The -9900K's 16MB of L3 cache pales in comparison from a capacity standpoint, but cache bandwidth and latency are more important metrics. We'll put hard numbers behind the differences on the following pages.

As a sidenote, AMD now calls its combined L2+L3 cache "GameCache" to highlight to casual consumers the importance of cache to gaming performance, but we'll stick with the established terms.

Ryzen 7 3700X

The eight-core 16-thread Ryzen 7 3700X slots in at $329 and comes with a 65W TDP rating, which is significantly lower than the competing Core i7-9700K's 95W rating. You'll notice that AMD has maintained similar price points for the new models compared to the previous-gen Ryzen 7's, but we caution that pricing is a moving target for the last-gen chips.

	Process	SEP / RCP (USD)	Cores / Threads	TDP (Watts)	Base Frequency (GHz)	Total Cache (MB)	PCIe Lanes	iGPU	Price Per Thread
Core i9-9900K	14nm	$488	8 / 16	95w	3.6 / 5.0	16	16 Gen3	Yes	$30.05
Ryzen 7 3800X	7nm	$399	8 / 16	105W	3.9 / 4.5	32	24 Gen4	No	$24.94
Core i9-9700K	14nm	$374	8 / 8	95W	3.6 / 4.9	12	16 Gen3	Yes	$46.75
Ryzen 7 2700X	12nm	$329	8 / 16	105W	3.7 / 4.3	16	20 Gen3	No	$20.56
Ryzen 7 3700X	7nm	$329	8 / 16	65W	3.6 / 4.4	32	24 Gen4	No	$20.56
Core i7-9700	14nm	$323	8 / 8	95W	3.6 / 4.9	12	16 Gen3	Yes	$40.38

Although third-gen Ryzen pricing is close to the current-gen processors on sale, this is far lower than the per-core pricing at the launch of the previous gen. Normalize the numbers to price-per-thread, and its clear AMD maintains a pricing advantage over Intel's lineup. But performance varies based on architecture, so the price-to-performance ratio is where the rubber meets the road.

The Ryzen 7 3700X features a single CCD with all eight active cores connected to the I/O die, highlighting that the company's Zen 2 architecture is inherently scalable. Threadripper processors also come with varying numbers of compute dies, but substitute in 'dummy' dies to ensure structural rigidity and prevent crushing the integrated heat spreader (IHS) when you tighten down your cooler. The smaller surface area of the 2700X's IHS doesn't require a dummy die, so this pad is simply left unoccupied.

AMD hasn't sampled the Ryzen 7 3800X yet, which features a higher 105W rating and 3.9 / 4.5 GHz base/boost clocks, which is higher than the Ryzen 7 3700X's 3.6 / 4.4 GHz base/boost frequency. It also looks like a compelling part, so look to these pages for a review soon.

(Image credit: AMD)

Both the Ryzen 9 3900X and the Ryzen 7 3700X come with the bundled Wraith Prism RGB cooler that features four direct-contact copper heat pipes, three independent RGB zones, switchable fan profiles, and a 39 dB(A) noise rating. The cooler is rated to dissipate 116W of waste heat in "L" mode (2800 RPM) and 124W in "H" mode (3600 RPM). Cooler Master manufactures the heat sink/fan, while AMD provides software for controlling the lighting and fan profiles. Company representatives claim the cooler represents a roughly $43 value, and that it also allows for some overclocking headroom. Intel's K-series models, in contrast, don't come with a bundled cooler.

Memory Subsystem and Overclocking, Infinity Fabric

Ryzen 3000 chips support dual-channel DDR4-3200, a step up from the previous-gen's support for DDR4-2966. That should boost performance significantly because the Zen 2 microarchitecture, like its predecessor, benefits heavily from increased memory performance (particularly in gaming).

(Image credit: AMD)

AMD's new Zen 2 microarchitecture uses a centralized memory controller on the I/O die, which helps ensure consistent memory latency in the multi-die Ryzen 9 models. It also improves cache access latency. AMD has also overhauled the Infinity Fabric, doubling its throughput by increasing the previous-gen 256-bit interconnect to 512-bit, which facilitates access to memory and enables the PCIe 4.0 interface. AMD also instituted more fine-grained Infinity Fabric quality of service controls and claims to have reduced the amount of energy required to transfer a bit by 27%.

(Image credit: AMD)

AMD has improved memory overclocking substantially, partly due to decoupling the Infinity Fabric from the memory clock. AMD's first-gen Ryzen processors had plenty of difficulties with memory overclocking when they first launched, but AMD has addressed those concerns with the second-gen products and has even demoed an air-cooled Ryzen platform running at DDR4-5100. We also didn't encounter any issues during our testing.

As with previous-gen Ryzen, memory overclocking confers big performance speedups for gaming. To sidestep the Infinity Fabric's maximum frequency of 2,000 MHz, which effectively constrains memory overclocking, AMD allows users to separate the memory and Infinity Fabric clock dependencies. The domains remain tied together at a 1:1 ratio up to DDR4-3600, but run at a 2:1 ratio beyond that transfer rate. This setting, which is also user-adjustable in the BIOS, improves memory bandwidth but comes with a latency penalty (~9ns). Tuners can also adjust the Infinity Fabric clock (fclk) in 33Mhz increments to get an extra kicker during overclocking. AMD says that the price/performance sweetspot will be around DDR4-3600.

As before, AMD supports up to 128GB of RAM and enables ECC support, but AMD leaves qualification and enablement of the feature up to motherboard vendors.

DIMM Config	Memory Ranks	Official Supported Transfer Rate (MT/s)
2 of 2	Single	DDR4-3200
2 of 4		DDR4-3200
4 of 4		DDR4-2933
2 of 2	Dual	DDR4-3200
2 of 4		DDR4-3200
4 of 4		DDR4-2667

As seen with the first-gen Zen chips, AMD's official supported memory data transfer rates vary based on the type of DIMM (single rank or dual rank) and the number of populated channels, as outlined above.

PCIe 4.0 Comes to the Desktop

Ryzen 3000 processors support the PCIe interface on X570 motherboards, and while the chips will drop into some previous-gen AM4 motherboards, the processor will downshift into PCIe 3.0 on those platforms. AMD has also infused the new technology into its "Navi" Radeon 5000 series GPUs and worked with storage vendors to assure a supply of speedy new PCIe 4.0 SSDs. We recently had the opportunity to take an early look at PCIe 4.0 SSD performance, which you can see here.

	Bandwidth	Gigatransfer	Frequency	Encoding
PCIe 3.0	32 GB/s	8 GT/s	8.0 GHz	128b/130b
PCIe 4.0	128 GB/s	16 GT/s	32.0 GHz	128b/130b

PCIe 4.0 provides yet another advantage for performance seekers, particularly in the content creation realm, over Intel's platform, but it doesn't materially impact gaming performance (at least not yet). The new interface also comes at the cost of higher pricing for X570-equipped motherboards due to tighter signalling requirements. Those prices could recede over time as the pricing of the PCIe 4.0 component ecosystem, like switches and redrivers, benefit from economies of scale, but AMD has wisely encouraged its partners to continue offering the current-gen X470 motherboards that will now serve as a lower tier of motherboards.

AMD's new Ryzen 3000 series lineup is fully compatible with existing X470 motherboards and will operate at their full performance on the previous-gen boards, albeit at the loss of PCIe 4.0 connectivity. That shouldn't be too much of a concern for users without PCIe 4.0 devices or SSD RAID storage arrays that hang off the chipset. Fast storage arrays will certainly benefit from the faster PCIe 4.0 connection between the chipset and processor, though.

Ryzen-Specific Windows 10 Scheduler Updates

AMD worked with Microsoft to deliver on a much needed feature: A Ryzen-aware scheduler. The new scheduler arrived with the Windows 10 May update and benefits both current-gen and previous-gen Ryzen models (Threadripper and Ryzen 3000 processors).

The new scheduler pins threads within a single CCX (the four-core clusters inside each CCD) before scheduling threads to other CCXes. This approach reduces latency during thread synchronizations or frequent cache accesses, thus improving performance for all existing Ryzen processors. AMD says the feature doesn't benefit all applications, but can result in significant performance improvements in those that do.

AMD also introduced its Collaborative Power Performance Control 2 (CPPC2) feature, which is a software feature that manipulates Ryzen 3000's power states from within the operating system. This is similar to Intel's Speed Shift technology and reduces power state transition latency from 30ns to 1ns, which ultimately saves power and boosts efficiency. The feature comes enabled in the latest AMD chipset drivers and the Windows 10 May update (and newer).

As before, these mainstream models don't come with integrated graphics, meaning you'll need a discrete GPU.

MORE: Best CPUs
MORE: CPU Benchmark Hierarchy
MORE: All CPUs Content

TSMC 7nm Process

AMD tapped TSMC's 7nm process for the Ryzen 3000 series processors. AMD's first-gen Ryzen processors debuted on GlobalFoundries' 14nm GPP node, but the 2000-series CPUs moved to GloFo's 12nm LP process technology. The ported-over design helped boost transistor performance, but did not affect die area or transistor density. As a result, Pinnacle Ridge's ~4.8 billion transistors and 213mm² area remained the same as first-gen Ryzen.

In contrast, TSMC's 7nm process represents a true shrink that provides twice the transistor density. AMD says the process allowed it to shrink the CCX by 29% relative to the 12nm process, which helped pave the way for Zen 2's enhancements, like the doubled L3 cache capacity and the ability to double core counts within the same package dimensions. It's also important to note that the company also removed I/O and memory controllers from the compute chiplet this time around, resulting in even smaller packages.

AMD also claims the process affords up to 350 more MHz of core frequency at the same voltage as the 12nm LP process. The new process also delivers on the energy efficiency front with up to 75% higher performance-per-watt compared to the 12nm LP process. AMD also says the 7nm node produces up to 58% higher performance-per-watt than Intel's aging, but highly refined, 14nm++ process, but be aware that the Ryzen 3000 chips still have a 12nm I/O die that contributes to the chip's overall power consumption.

AMD says that the 15% increase in IPC throughput from the Zen 2 microarchitecture serves up 60% of the performance improvements seen in the Ryzen 3000 series chips, with the remaining 40% coming from the 7nm process and frequency improvements.

Zen 2 Microarchitecture

Zen's modular and scalable design provides AMD with plenty of advantages in terms of cost and time to market, and fine-grained tuning to the architecture has yielded phenomenal results.

(Image credit: AMD)

AMD has improved IPC by roughly 15% (though that can vary by workload), doubled the L3 cache size to keep data as close to the execution units as possible, and doubled floating point performance by expanding floating point bandwidth to 256-bit to improve performance with AVX2 instructions.

Headline improvements include a doubled micro-op (4K) and L3 cache (32MB), which came at the expense of a slightly smaller L1 instruction cache that is now an 8-way associative 32K block as opposed to the 64K block with 4-way associativity on first-gen Ryzen. AMD also beefed up the Translation Lookaside Buffer (TLB) to 2,000 entries.

AMD now has a double-stage branch predictor, with its Perceptron predictor handling the first stage while a new TAGE branch predictor, which features larger lookup tables to improve performance, serves as the second stage. That's paired with larger L1 and L2 branch target predictors (BTBs) that increase throughput by reducing stalls. AMD says the improved branch predictor expends extra energy on the front end, but the 30% lower misprediction rate ultimately saves more energy on the backend. A third address generation unit (AGU) also keeps the hungry execution cores fed with data from main memory.

Enter the X570 Chipset

AMD's Ryzen 3000 series processors have dynamic algorithms that adjust parameters based upon several factors, with power delivery and heat dissipation being the chief variables that can unlock extra performance. As such, motherboard selection is going to be a big factor in the amount of performance you receive if you choose to use AMD's Precision Boost Overdrive (PBO - next page) and Auto Overclock features. The X570 motherboard ecosystem has proven to be pricey compared to the previous-gen X470 models, but AMD says that the Ryzen 3000 series processors will operate at full performance at stock settings with X470 motherbaords. You just sacrifice access to the PCIe 4.0 interface.

(Image credit: AMD)

The actual X570 chipset is a 14nm variant of the 12nm I/O die inside the Ryzen 3000-series processors, which is a clever reuse of the technology that ultimately lowers costs. This chipset is also fully produced by AMD, whereas the X470 chipset came from ASMedia, which says it will continue to produce some chipsets for Ryzen 3000 series processors. AMD uses the smaller 12nm process for the processor's in-package I/O die to leverage the increased frequency potential for the memory controllers. That improves memory data transfer rates, but AMD uses the more economical 14nm variant, which has its memory controllers disabled, for the chipset die.

(Image credit: AMD)

Most X570 motherboards come with a fan on the chipset to provide active cooling for the chipset, which now consumes ~11-15W compared to the 6W consumed by the X470 chipset. That's due to the power-hungry nature of the PCIe 4.0 interface when it is under full load. Small fans like these tend to be noisy, but our motherboard team is hard at work on the first wave of X570 motherboard reviews and will provide more perspective.

(Image credit: AMD)

Ryzen 3000-series chips are compatible with most previous-gen motherboards with the AM4 socket, but some updates are left to vendor discretion. As such, you won't be able to drop a new Third-gen Ryzen chip into all X370 and B350 motherboards, and A320's upgrade path is blocked entirely. Due to the uneven application of BIOS updates across the various vendors, and even among different motherboards in the respective product stacks, you'll have to check the CPU support list for your X370 or B350 motherboard to ensure it supports Third-gen Ryzen.

There are plenty of X470 and B450 motherboards still on the market, but some of the boards that have been in the supply chain for a while will need a BIOS update before you install a Third-gen Ryzen processor. As we've seen in the past, that isn't always possible if you don't already have a Ryzen processor or if the motherboard doesn't have an out-of-band BIOS update feature, like BIOS Flashback. AMD also announced that all motherboards that support Ryzen 3000 processors out of the box will come with a new badge to help simplify things.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Zen 2 Instructions Per Cycle (IPC)

It's important to remember that IPC can vary by workload, so dissimilar tasks may yield different outcomes. We set a static 3 GHz clock rate and dialed memory to the respective processors' supported frequency for the following tests:

All of the processors in this test come with eight cores and sixteen threads, so we left the core allocations unaltered and the Ryzen 7 1800X serves as our baseline comparison. These apples-to-apples tests expose a significant boost moving from the first-gen to third-gen Ryzen's, with single-threaded IPC improvements ranging from 5% to 18% for most applications. AVX-heavy workloads receive the biggest benefit with the AVX y-cruncher benchmark exposing a 70% and 163% increase in single- and multi-threaded workloads, respectively. That comes as a side benefit of AMD's move to a 256-bit floating point unit instead of splitting AVX workloads into two instructions fed across two cycles. Performance improvements are more muted with cryptographics workloads, which only experience a ~5% uplift.

AMD used SPECviewperf 13 to measure its IPC improvements, and it's clear it's results are more than plausible, if not a conservative estimate. Removing our results from y-cruncher, which is clearly a standout, and the crytpographic workloads yields an average 13% IPC uplift, which isn't too far off from AMD's official claim of 15%. Throwing in the y-cruncher and cryptographic tests yields a whopping 18% in IPC uplift.

Power Consumption

Power consumption measurements are always a bit tricky. But as long as your 12V supply (EPS) readings, motherboard power supply sensor values, and voltage transformer losses plausibly coincide, everything is fine. Therefore, we're using pure package power to avoid possible influences from our motherboard. Results from the PWM controller are very reliable if you take them as averages over a few minutes.

We first measured power consumption during an AIDA stress test, but we disabled AVX instructions. The Ryzen 7 3700X beats the pack with 90W of package power consumption under full load, trailed slightly but the Core i7-9700K. The Ryzen 9 3900X pulls 142W at stock settings, and that increases to 168W when we engage the new "Auto OC" and Precision Boost Overdrive features. That is 29W more than the stock Core i9-9900K during this test, but the 3900X comes with four more cores, so performance efficiency will be the real judge of power consumption.

We're moving away from using AVX-based stress tests for our CPU power testing, though we will continue to use them for their intended purpose of validating overclocks. AVX-based stress testing utilities essentially act as a power virus that fully saturates the processor in a way that it will rarely, if ever, be used by a real application. Those utilities are useful for testing power delivery subsystems on motherboards, or to generate intense thermal loads for case testing, but they don't provide a performance measurement that can be used to quantify efficiency.

The y-cruncher benchmark computes pi using a heavy multi-threaded AVX workload and also generates a performance measurement that we can use for efficiency metrics. We're also adding in HandBrake in x264 and x265 flavors. The latter uses a heavier distribution of AVX instructions than the former, but both transcoders are great for stressing the processor with a real-world workload. As we can see, the Ryzen 7 3700X sucks the least power of the group during the tests, but we should also bear in mind that it also has the lowest TDP rating.

As a sidenote, we tested Intel's Core i9-7920X as part of our test pool, but removed the power results due to incorrect reporting from the motherboard's sensor loop.

Combining the performance metrics recorded from the three applications, we can see that the Ryzen 7 3700X is an incredibly efficient processor given its level of performance, and the beefy Ryzen 9 3900X also impresses, though you could argue the overclocked configuration consumes a lot more power in exchange for a relatively tiny gain in performance. In either case, the 7nm process obviously confers a solid power-to-performance ratio.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Precision Boost Overdrive, AutoOC, and Ryzen Master Software

AMD's Precision Boost Overdrive (PBO) is a boon to enthusiasts with its adaptive overclocking approach, and it's making its way from the Threadripper platform to all of AMD's Ryzen 3000 processors. The software allows the processor to communicate with the platform to modulate performance based on the motherboard's power delivery subsystem and thermal dissipation capabilities.

The processor monitors Package Power Tracking (PPT) and Thermal Design Current (TDC) variables, measuring available margin to the motherboard's maximum power output and current, respectively. Electrical Design Current (EDC) also indicates the maximum current possible from the VRMs during peak/transient conditions. A control loop feeds real-time telemetry data back to the processor, which then dynamically adjusts performance based on thermal and power conditions. AMD also exposes some of these monitoring features with its Ryzen Master overclocking software.

Motherboard vendors define the power limits for their boards and are developing custom profiles that support a new Auto OC feature. This new feature grants you some control over the maximum attainable boost clocks by allowing you to add up to an extra 200MHz to the maximum boost clock, but it isn't guaranteed that the processor will reach those speeds at all times, or under all conditions. Instead, the processor will still respect the limits imposed by the motherboard maker. AMD says that Auto OC is designed to improve performance in single-threaded workloads, while PBO boosts heavily-threaded applications. In either case, you can toggle both settings simultaneously for the best of both worlds.

(Image credit: AMD)

Our Overclocking Efforts

Due to time constraints, we tested the Ryzen 9 3900X and Ryzen 7 3700X with both automated overclocking features activated instead of with a manual all-core overclock. Several motherboard vendors have told us that overclocking headroom is extremely limited on the Ryzen 3000 processors, and that exceeding the boost clocks, or even meeting them, isn't possible for all-core overclocking. Our resident overclocking expert Allen 'Splave' Golibersuch has also spent time with early Ryzen 3000 samples and was unable to break the 4.1 GHz barrier without sub-ambient cooling.

In either case, the combination of PBO and AutoOC yielded improvements in some applications, but wasn't as impressive with the Ryzen 7 3700X as it was with the Ryzen 9 3900X. In some cases, the boost confers no benefit for the Ryzen 7 3700X in our application testing, and on a few occasions, we see performance regressions in lightly-threaded workloads compared to the stock configuration. We tested with multiple motherboards and met with the same result, which could boil down to the quality of our sample or motherboard firmwares. As with most processor launches, motherboard firmwares are still a work in progress, so there is hope that the situation will improve. We'll update our results when a fix becomes available, but we did encounter this issue the night before NDA lift, so hopefully a fix will come soon.

We regularly observed our Ryzen 9 3900X maintaining an all-core 4.1 GHz during our testing, while the Ryzen 7 3700X often peaked at 4.125 GHz.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

The new AMD-optimized Windows scheduler is only present in Windows 10 1903 and promises to expose gains in several types of applications. As such, we updated our test image to the latest version of Windows 10 available at the time of publication (18362.207). All of our test results come from the aforementioned operating system and include all publicly available security mitigations and the latest motherboard firmware revisions. Intel is currently impacted by Spectre, Spectre v4, Meltdown, Foreshadow, Spectre v3a, Lazy FPU, Spoiler, and MDS, while AMD is only impacted by Spectre and Spectre v4. AMD has added hardware-based mitigations for both variants of Spectre, which should reduce the performance impact, but the requisite patches for both companies have performance penalties, which also furthers the need to move forward to the latest operating system available.

We also revamped our game suite, updated to all of the latest versions of application tests, adding a few more along the way, and expanded our power testing suite. We also moved from an EVGA Nvidia GeForce 1080 FE graphics card to the Nvidia GeForce RTX 2080 Ti for game testing. We use a Gigabyte GeForce RTX 2080 for synthetic tests to streamline our testing process.

Other improvements include moving from SATA SSDs to Intel's 2TB DCP4510 NVMe SSDs. It helps that the drive delivers 3,200/2,000 MB/s of sustained sequential read/write throughput, which speeds up the imaging process.

All applications, drivers, and BIOS revisions are up-to-date as of seven days prior to the publication date (excluding the Ryzen 3000 BIOS, which is two days old). Due to the significant overhaul of our testing methodology and systems, all test results in this review are not directly comparable to previous reviews, but will be comparable moving forward.

A Note on Multi-Core Enhancement (MCE)

Intel's motherboard partners have infused their boards with predefined all-core boost profiles that go by many names, such as Multi-Core Enhancement (MCE) with ASUS motherboards and Enhanced Turbo with our MSI motherboard. These features are largely referred to as MCE, but the functionality remains the same: These settings essentially apply an all-core overclock to the processor that is defined by the maximum Turbo Boost bin supported by the processor. This setting modifies the CPU's clock rate and voltage to deliver higher performance, which is basically factory-sanctioned overclocking.

MSI turns this on by default in its BIOS, similar to most of its competition. Performance, power consumption, and heat are all affected, naturally. We manually disable this feature for our stock CPU testing to best reflect Intel's specifications.

MSI MEG X570 Godlike

We're using MSI's MEG X570 Godlike as our test platform for the second- and third-gen AMD processors. Due to the compatibility matrix for the AM4 socket, we stepped back to the MSI X470 Gaming M7 AC for the Ryzen 7 1800X.

The pricey Godlike board retails for around $800, but has the 14+4+1-phase power delivery subsystem to support aggressive overclocking.

(Image credit: MSI)

The MEG X570 Godlike sits at the top of MSI's motherboard hierarchy. It also comes with a few nifty accessories likea 10Gb “Super LAN” Ethernet card and a PCIe Gen 4 Xpander-Z M.2 expansion card. That let's you add two more M.2 drives to complement the three M.2 PCIe Gen 4 M.2 ports on the board. You also get four PCIe 4.0 x16 slots, an RGB Mystic Light Infinity II mirror over the IO shroud, and a tiny OLED screen, alongside the two-digit LCD display for error codes.

Comparison Products

Intel Core i9-9900K

Intel Core i7-9700K

Ryzen 7 2700X

Test System and Configuration

AMD Socket AM4 (X570)
	AMD Ryzen 9 3900X, Ryzen 7 3700X, Ryzen 7 2700X
	MSI MEG X570 Godlike
	2x 8GB G.Skill Flare DDR4-3200
	Ryzen 3000 - DDR4-3200, DDR4-3600
	Second-gen Ryzen - DDR4-2933, DDR4-3466

Intel LGA 1151 (Z390)
	Intel Core i9-9900K, i7-9700K
	MSI MEG Z390 Godlike
	2x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2667 & DDR4-3466

AMD Socket AM4 (X470)
	AMD Ryzen 7 1800X
	MSI X470 Gaming M7 AC
	2x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2933

AMD Socket SP3 (TR4)
	AMD Threadripper 2920X
	MSI MEG X399 Creation
	4x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2933

Intel LGA 2066
	Intel Core i9-7920X
	MSI X299 XPower Gaming AC
	4x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2666

All Systems
	Nvidia GeForce RTX 2080 Ti
	2TB Intel DC4510 SSD
	EVGA Supernova 1600 T2, 1600W
	Windows 10 Pro (1903 - All Updates)

Cooling
	Corsair H115i
	Custom Loop, EKWB Supremacy EVO waterblock, Dual-720mm radiators
	AMD Wraith Prism Stock Cooler
	Enermax Liqtech 240 TR4 II

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

We tested the Threadripper 2920X in Game Mode for our game suite, and Creator Mode for our application tests.

VRMark, 3DMark

We aren't big fans of using synthetic benchmarks to measure performance, but 3DMark's DX11 and DX12 CPU tests provide useful insight into the amount of horsepower available to game engines.

The DX11 and DX12 CPU test results expose the full threaded heft of the Ryzen 3000 series processors. The Ryzen 9 3900X even manages to dethrone the overclocked Core i9-9900K in both tests.

The VRMark test benefits heavily from per-core performance, and the Ryzen 3000 processors have made great strides compared to the first- and second-gen models. You'll notice that our combined Precision Boost Overdrive and AutoOC configuration leads to slightly lower performance for the Ryzen 7 3700 in this test, while the 3900X experiences a small benefit. That's a trend that we'll see repeat in some of our application tests. We've reached out to both MSI and AMD on the matter, and will update these results when a fix becomes available.

Intel's Core i7-7920X is the only twelve-core Intel processor we have on hand for testing, so we're including it in our test pool. Be aware that this is a previous-gen model, so the newer Core i9-9920X, which is based on the same architecture, offers more performance via incremental improvements to its all-core boost frequencies.

Ashes of the Singularity: Escalation

Ashes of the Singularity: Escalation is a computationally intense title that scales well with thread count, but clock speeds and per-core performance play a big role, as evidenced by the overclocked Core i9-9900K's commanding performance. However, both the Ryzen 9 3900X and the Ryzen 7 3700X beat the -9900K in stock trim.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Civilization VI AI Test

This Civilization VI test mesures AI performance in a turn-based scenario and tends to prize per-core performance. The 3900X doesn't benefit from the auto-overclocking features, and the 3700X again suffers a slight decline in performance, indicating there are still a few kinks to work out. In either case, both processors at stock settings easily beat their previous-gen predecessors, even when they're overclocked.

Civilization VI Graphics Test

Warhammer 40,000: Dawn of War III

Tthe Warhammer 40,000 benchmark responds well to threading, but it's clear that Intel's per-core performance advantage has a big impact.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Far Cry 5

Final Fantasy XV

We run this test with the standard quality preset to sidestep the impact of a bug that causes the game engine to render off-screen objects with the higher-resolution setting.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Grand Theft Auto V

Grand Theft Auto V favors Intel architectures and, more generally, multi-core designs with high clock rates.

Hitman

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Project CARS 2

Although Project CARS 2 is purportedly optimized for threading, clock rates obviously affect this title's frame rates. Intel's per-core performance advantage pays big dividends in this title.

The Division 2

World of Tanks enCore

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Web Browser

The Krakken suite evaluates JavaScript performance using several workloads, including audio, imaging, and cryptography. Like most browser-based benchmarks, single-threaded performance reigns supreme. Browsers tend to be impacted more by the recent security mitigations than other types of applications, resulting in reduced performance from the Intel processors in these benchmarks. AMD's improved IPC comes into play as the 3900X takes the lead in Krakken. The stock Ryzen 7 3700X also grapples with the overclocked Core i7-9900K and i9-9900K, which is a surprising turn of events in a lightly-threaded application.

Surprisingly the Ryzen 3000 processors lag the 2700X in the WebXPRT 3 suite, but are far more competitive in the Speedometer benchmark.

Microsoft Office

Microsoft's office suite makes its debut in our test suite via PCMark 10's new application test. This benchmark tests with real Microsoft Office applications, and we can see that the Ryzen 3000 series processors are very competitive in Excel, the Edge browser, and Word.

Productivity

The application start-up metric measures load time snappiness in word processors, GIMP, and Web browsers under warm- and cold-start conditions. Other platform-level considerations affect this test as well, including the storage subsystem. The 3000-series processors occupy the middle of the ranks, but it will be interesting to revisit this benchmark with a PCIe 4.0 SSD in the future.

Our video conferencing suite measures performance in single- and multi-user applications that utilize the Windows Media Foundation for playback and encoding. It also performs facial detection to model real-world usage.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Rendering

It shouldn't surprise anyone to see the 12-core 24-thread 3900X bring a taste of HEDT performance to the multi-threaded rendering benchmarks. Ryzen 3700X also performs well given its price point.

Encoding and Compression

Our threaded compression and decompression metrics work directly from system memory, removing storage throughput from the equation. Ryzen 3000's improved memory performance, along with the generous helping of cores, plays a big role in its commanding lead.

Core i9-9900K traditionally leverages high frequencies to dominate the HandBrake x265 test, which relies heavily on AVX instructions, and the H.264 test. But Ryzen's improved AVX throughput shakes up the status quo, stealing the lead from the incumbent. We can also see the vast improvement in Ryzen's AVX performance in the y-cruncher tests.

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Conclusion

AMD’s Ryzen 3000 series represent yet another big step forward as the company leads the way with the first 7nm processors for the desktop PC and brings the first PCIe 4.0-enabled platform to market. The benefits of the 7nm process paired with the Zen 2 microarchitecture, and its big boost to IPC, manifest as a more power efficient platform with higher core counts than competing chips, and at a lower price per thread, which places both products but especially the 3700X among the best gaming CPUs you can get.

The Ryzen processors are extremely competitive in performance across the full span of our gaming and application test suites, notching impressive wins in heavily-threaded applications and significantly narrowing the gap in the lightly-threaded applications that Intel has traditionally dominated. To put things in perspective, consider that the overclocked Ryzen 7 2700X rarely matched the stock performance of the Ryzen 7 3700X.

Intel still holds the absolute performance crown in gaming, but much of that performance advantage will be less noticeable when gaming at higher resolutions, or if you pair the processors with a lesser graphics card.

AMD is also taking the leadership position by delivering the first PCIe 4.0-enabled platform for the desktop PC, a role that we would typically expect the market leader to fill. Unfortunately the faster interface does result in higher-priced X570 motherboards, but AMD has wisely encouraged its partners to continue to offer X470 motherboards, which are cheap and plentiful. You'll lose access to the PCIe 4.0 interface in exchange for lower pricing, but you'll also have a compelling upgrade path in the future.

AMD continues to offer as much backward compatibility as it can given its expanding portfolio, earning kudos from the enthusiast community, and is also staying true to its standard value proposition of offering more for less. Both the Ryzen 9 3900X and the Ryzen 7 3700X come with a beefy bundled Wraith Prism cooler that can even provide a bit of overclocking headroom, too.

AMD also continues to offer fully unlocked processors for all models and allows overclocking on value-centric motherboards, which has long been a sore point for enthusiasts that have to pay a premium for access to Intel's overclocking features. AMD is even expanding on that with the introduction of Precision Boost Overdrive and AutoOC features that bring overclocking to mainstream users through a few clicks in its easy-to-use Ryzen Master utility. Intel has responded in kind with its Intel Performance Maximizer, but that software is only compatible with the company's pricey 9th-Generation processors. That said, Intel obviously still holds the overclocking crown, but that's becoming less of an advantage in the face of processors that come with up to twice the cores.

The Ryzen 9 3900X redefines our expectations for the mainstream desktop with a beastly 12-cores and 24-threads and represents a great value if you're seeking a well-rounded performer. The extra cores and threads will pay big dividends in productivity applications, and the solid performance in more common lightly-threaded applications is more than enough for most users.

The Ryzen 7 3700X slots in as the more accessible counterpart that will appease the vast majority of customers, and it also comes with the many of the same attractions of the previous-gen model, except it is faster and consumes less power. If you're looking for the best value on the market, the Ryzen 7 3700X is your chip.

Image Credits: Tom's Hardware

MORE: Best CPUs
MORE: Intel & AMD Processor Hierarchy
MORE: All CPUs Content

Gigabyte X570 Aorus Elite Motherboard Review: Sub-$200 Goodness

Joe Shields — Fri, 15 Nov 2019 19:48:08 +0000

Features and Layout

Gigabyte’s X570 Aorus Elite mainboard comes in on the budget end of the X570 platform (which is generally more expensive than previous-generation X470 boards), priced under $200. It comes with all of the basics, including PCIe 4.0 support, dual PCIe 4.0 M.2 slots, an integrated I/O shield, large heatsinks covering the VRM and front panel USB Type-C support, among other features.

Gigabyte X570 Aorus Elite ( (Image credit: Gigabyte))

Supporting both Ryzen 2000 and Ryzen 3000 series processors, the X570 Aorus Elite
is the second board in Gigabyte's X570 product stack, above the non-Aorus-branded X570 Gaming X. The Elite aims to give users a well-balanced platform to build on, offering up-to-date connectivity and a robust power delivery area capable of driving all Ryzen 3000 processors.

The full complement of six SATA ports, two M.2 slots, an Intel I211 Gigabit NIC and Realtek ALC1200 audio codec which supports 7.1 surround are included, and the four DIMM slots are capable of supporting up to 128GB of RAM and/or speeds up to DDR4-4000 (when overclocked). Below is a complete list of specifications from Gigabyte.

Gigabyte X570 Aorus Elite Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	12+2 phase (doubled - 7 phase, actual)
Video Ports	HDMI
USB Ports	USB 3.1 Gen 2 (10 Gbps): 2x Type-A USB 3.1 Gen 1 (5 Gbps): 4x Type-A USB 2.0: 4x Type-A
Network Jacks	(1) Gigabit Ethernet
Audio Jacks	(5) Analog + SPDIF
Legacy Ports/Jacks	✗
Other Ports/Jack	✗
PCIe x16	(1) v4.0
PCIe x8	✗
PCIe x4	(1) v4.0
PCIe x1	(2) v4.0
CrossFire/SLI	AMD Quad-GPU Crossfire and 2-Way AMD Crossfire
DIMM slots	(4) DDR4
M.2 slots	(1) PCIe 4.0 x4 / SATA + PCIe (1) PCIe 4.0 x4 / SATA + PCIe
U.2 Ports	✗
SATA Ports	(6) 6Gb/s
USB Headers	(1) v3.x Gen2, (2) v3.x Gen1, (2) v2.0
Fan Headers	(4) 4-Pin
Legacy Interfaces	✗
Other Interfaces	FP-Audio, RGB-LED, TPM
Diagnostics Panel	✗
Internal Button/Switch	✗ / ✗
SATA Controllers	Integrated (0/1/10)
Ethernet Controllers	Intel GbE LAN
Wi-Fi / Bluetooth	✗
USB Controllers	✗
HD Audio Codec	ALC1220
DDL/DTS Connect	✗ / ✗
Warranty	3 Years

As we’d expect with a budget-priced board, included accessories are minimal, but the basics are covered. Here’s a list of what ships in the box with the board.

User’s manual
Support CD
Installation guide
4x SATA cables
Screw for M.2 slot
Aorus sticker
G connector

The Gigabyte X570 Aorus Elite’s appearance is fairly indistinct, with an all-black PCB and some stenciling around the chipset heatsink and audio area. Outside of that, we can see the Aorus branding on the left VRM heatsink along with a shroud covering the integrated rear IO plate. All heatsinks on the board have a brushed-aluminum finish with the chipset heatsink sporting a small fan, along with the Aorus falcon sitting proudly on top.

The DIMM and PCIe slots are also black, matching the board with the primary, metal-clad PCIe slot, which Gigabyte calls Ultra Durable PCIe armor. All other connectors, including the 8-pin EPS, 24-pin ATX and the SATA ports are all black as well.

RGB LEDs do make an appearance on the board. They’re found under the IO shroud by the VRM heatsink, as well as a line on the bottom-left side used to separate the audio bits from the rest of the board. The latter provides a nice glow underneath, while the RGB around the VRM makes for a nice accent on top.

Overall, the Gigabyte X570 Aorus Elite should fit into most build themes, with its basic-black styling and reserved use of integrated RGB LED lighting.

Starting off at the top half of the motherboard, we get a closer view of the heatsinks and shroud covering the VRMs and back of the IO area. Between the shroud and left heatsink with the Aorus branding on it is where we find that first RGB LED strip. Just above that is a single 8-pin EPS connector.

The VRM for the Elite is listed as a 12+2 phase system on the website. Digging a bit deeper we see the board uses an Infineon IR35201 controller in a 6+1 configuration and uses phase doublers (Infineon IR3599) to run in the 12+2 Gigabyte states. The VRM’s should be able to handle any of the Zen 2 CPUs at stock and with some overclocking.

The top half of the board also houses all four fan headers. Three are located across the top while the 4th is just above the M.2 slot next to the rear IO shroud. All fan headers are hybrids that support both PWM- and DC-controlled fans. Gigabyte’s Smart Fan 5 software manages all the fan headers and allows control over them through six temperature sensors on the board which you can base your fan off of. For example, if your PCH gets hot, the case fan header can spin faster. It also supports “Fan Stop” capabilities which, as the name implies, shuts off the fans below a certain threshold.

Toward the right side of the board, we see the four DIMM slots which skip any armor (not that it’s needed), but use a double-sided locking mechanism to secure the modules. Last, we can see two of the four RGB headers in the upper right-hand corner (the others are located across the bottom). In each area, one header supports your basic RGB strips with a 4-pin setup (2A max) while the other supports addressable RGBs (5A max, 1000 LED max) with a 3-pin header.

Moving down to the bottom portion of the board, on the left side is the audio section. The Realtek ALC1200’s 7.1-channel chip is hidden underneath the EMI shield, with Amp-Up Audio stenciled on top. Below that are two rows of audio caps with the yellow Chemicons on the left and red WIMA FKP2 capacitors on the right. Separating the audio section from the rest of the board is a “noise guard,” which also includes the 2nd area with RGB illumination. Both sets of LEDs can be controlled via the included RGB Fusion 2.0 software, along with the headers.

The PCIe area consists of two full-length slots and two x1 size slots. The top PCIe connector uses Gigabyte’s armor around the slot to prevent shearing with heavy video cards. The top slot runs at a full PCIe 4.0 x16 sourced from the CPU while the bottom slot is limited to PCIe 4.0 x4 bandwidth from the chipset. The two x1 size slots are also PCIe 4.0.

Also found around the PCIe slots are the two M.2 connectors. The first is located above the primary PCIe slot and has a heatsink on it while the second is above the other full-length slot, sans heatsink. Both connectors support SATA and PCIe 4.0 x4/x2 SSDs up to 110mm in length. The nice bit (thanks to the extra bandwidth addorded by PCIe 4.0) is that there’s no port sharing when using both slots.

The chipset heatsink covers a lot of area on the board and has a small fan inside to help keep the 11W chip cool. We only heard the fan on boot when it ramps up to full speed and then winds down. Outside of that, the fan remained inaudible, even under heavy loads including stress testing. Sliding more to the right are the six SATA3 (6 Gbps) ports.

Finally, across the bottom are several headers which include the 2nd set of RGB headers, the Q-Flash button, and front-panel USB headers. There is nothing out of the ordinary to report on this front, so here’s a bulleted list of the other headers:

Front Panel Audio
aRGB and RGB headers
Q-Flash button
TPM header
2x USB 2.0 headers
2x USB 3.0 headers
Front panel header

Last but far from least is the rear I/O. Surprisingly, the X570 Aorus Elite has an integrated rear I/O plate, which gives the board a more expensive feel and a cleaner look. Gigabyte used the same design cues with an Aorus falcon on the I/O plate as well as the same lined pattern stenciled on the board.

But it isn’t just about looks. There are a total of 10 USB ports available: Four USB 2.0 (black), four USB 3.0 (blue and white - the latter for bios flashback/Q-Flash) and two USB 3.1 Gen2 ports. One thing you won’t find is a USB Type-C port of any kind, but such as life when buying an entry-level board. You’ll also find the Intel I211 LAN port here, as well as the audio stack (5 analogs, one SPDIF). If you happen to be using an APU on this motherboard, the video comes from a single HDMI 2.0 port.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Software and Firmware

In the Gigabyte software ecosystem, the company offers several applications designed to help the user get more from their PC, and handily stows them all in a single App Center wrapper. From here, you can access Easy Tune, RGB Fusion 2, @Bios, Game Boost, Cloud Station, On/Off Charge, and more.

App Center also acts like a quasi-Windows Settings control panel, with easy access to user account information, firewall, devices, sound, power options and more. The app itself runs out of the way in the tray until it’s needed. Overall, the software is a good toolbox for accessing the Gigabyte apps and Windows settings, though one thing I would like to see is a driver-updating utility which we have seen in other similar applications from different board partners.

The first application we’ll look at is Easy Tune, which is designed to display system information including temperatures, voltages and clock speeds and fan control. Across the top are several sections, each with different functionality, while on the bottom is live system monitoring.

The first section is OC Smart Boost, with options to overclock the CPU. In this case, default is 3.6GHz on one core) and 3.8 GHz with all cores. In most cases, Precision Boost Overdrive (PBO) will clock past those points, so we suggest using that. In the advanced CPU and DDR overclock portion, users will find all the overclocking options. This includes BCLK and CPU ratio functions, CPU Vcore, SOC and DRAM voltages, among some other lesser options. The DDR portion only offers control for memory frequency and XMP/DOCP profile setups, but no timing control (which should be done in the BIOS anyway). In the advanced power section, we find Load Line calibration for both Vcore and SOC, in case you see a lot of vdroop.

Easy Tune works well as a monitoring tool as well as for overclocking. Some users may not be comfortable in the BIOS and this Windows-based utility is a bit less intimidating when you aren’t used to digging around outside of your OS.

Gigabyte’s RGB LED control application is called RGB Fusion 2.0. This program gives you control over the integrated RGB LEDs on the board as well as any compatible devices you plug into the board, including memory, video cards, and any LEDs attached to the board through its four headers. You’re able to customize the lighting through eight pre-programmed functions, along with the color, speed and brightness.

Firmware

Moving on to the UEFI / BIOS, there are some slight changes to what I am used to across the top. For example, MIT has been replaced with “Tweaker,” though overall styling and the Aorus theme of Orange and black remain the same.

Starting off in Easy Mode, this section is mostly informative with a bit of editing and interaction allowed. It displays information such as the motherboard name, BIOS version and the installed CPU and RAM amount. There is a section covering the CPU frequency and voltage, along with temperatures of the CPU, chipset, and VRMs. It will also display an installed SATA or M.2 drives, as well as what is populating the PCIe slots.

You’re able to adjust a few things on this screen including setting the XMP profile, changing the boot sequence, as well as access Smart Fan 5 to control your fans. On the lower right-hand side is where one can switch into advanced mode, Smart Fan 5, or Q-Flash, as well as loading defaults, can be done here. Any other functionality will have to come from the advanced sections.

The Advanced mode is where most of the tweaking and overclocking will be handled. Across the top, there are several headings each with specific functionality beneath. From left to right, there’s Favorites, Tweaker, Settings, System Info., Boot and Save and Exit.

The favorites section is a user-customized portion of the BIOS. By default, it includes CPU BCLK and Ratio controls as well as XMP profile and Vcore/Load Line Calibration functions. You can add to this page by pressing the insert key from other tabs to make it ‘yours’.

The tweaker section, or as it was called on X470 based boards, MIT, is where you’ll find all the functionality necessary for overclocking the CPU, setting memory speed and timings and other power type features. For the most part, Gigabyte has done a good job at putting the most-often used options under the same heading. But still, we found ourselves jumping around a bit. There is an entire section for overclocking within the Settings heading, which is mostly duplicated in the tweaker section. I would like to have seen PBO options in the tweaker section, at least.

The Settings section contains subheadings for Platform power, IO ports, Miscellaneous, AMD CBS (memory, power XFR, etc), as well as AMD Overclocking, PC Health, and Smart Fan 5 access. If you needed to mess with SATA, USB or Network configurations, this is where it’s done.

The System Info. section is informational displaying details on the BIOS, Processor, LAN MAC address and is where to adjust system date and time. You can also reach Q-Flash from here (and elsewhere) as well as get details on attached devices.

The Boot section is where users are able to control the boot options, full-screen logo enable/disable, fast boot and any LAN PXE boot options.

Last up is the Save and Exit section, where you can save any bios changes, load optimized defaults and save and load user profiles.

Jumping into Smart Fan 5 from the BIOS, users are able to create custom fan curves and choose which sensor input the header reacts to. For example, basing the CPU header(s) that off CPU temperatures, and case fans VRM or motherboard temperatures. The point is, you get pretty granular control over when the fans ramp up. This isn’t something you typically see on a budget board.

Overall, the updated BIOS is easy to navigate. But there are a lot of sections with duplicate entries, which can be convenient but also conusing. Overall, the firmware lets you do what you want to do with a fairly easy learning curve. We were able to overclock, for what little that is actually worth, and change settings without issue.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

How We Test

We’ll be comparing the Gigabyte X570 Aorus Elite to the Asus TUF Gaming X570-Plus Wi-Fi since it is similarly priced. We’ve also included the Gigabyte X570 Aorus Pro Wi-Fi and Biostar X570GT8 for additional datasets.

Comparison Products

Asus TUF Gaming X570-Plus Wi-Fi

Biostar X570GT8

Gigabyte X570 Aorus Pro Wi-Fi

While we tested this Gigabyte board at a different location than our previous X570 reviews, our review systems are as close as possible to running the same specifications. Though our memory may be different, the speed and primary timings are the same as well as the GPU. We use as an updated W10 64-bit OS with all threat mitigations applied.

Test System Components

Sound	Integrated HD audio
Network	Integrated gigabit networking
Graphics Driver	GeForce 413.36

Benchmark Settings

Synthetic Benchmarks and Settings
PCMark 10	Version 2.0.2115 64Essentials, Productivity, Digital Content Creation, MS Office
3DMark	Version 2.9.6631 64Firestrike Extreme and Time Spy Default Preset
Cinebench R15	Build RC184115DEMOOpenGL Benchmark - Single and Multi-threaded
Cinebench R20	Version RBBENCHMARK281795Open GL Benchmark - Single and Multi-threaded
Application Tests and Settings
LAME MP3	Version SSE2_2019Mixed 271MB WAV to mp3: Command: -b 160 --nores (160Kb/s)
HandBrake CLI	Version: 1.2.2Sintel Open Movie Project: 4.19GB 4K mkv to x264 (light AVX) and x265 (heavy AVX)
Corona 1.4	Version 1.4Custom benchmark
7-Zip	Version 19.00Integrated benchmark
Game Tests and Settings
*Ashes of the Singularity: Escalation*	Version 1.31.21360High Preset - 1920 x 1080 / 2560 x 1440Crazy Preset - 1920 x 1080 / 2560 x 1440
*F1 2017*	2017 Season, Abu Dhabi track, RainMedium PresetUltra High Preset

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark Results and Final Analysis

All standard benchmarks and power tests are performed using the CPU’s stock frequencies (including stock AMD Turbo), with all of its power-saving features enabled. Optimized defaults are set in the BIOS and the memory set. The memory is manually set up to run at DDR4 3200 MHz ( the base spec for Zen 2), at 16-18-18-38 primary timings.

Synthetic Benchmarks

Synthetics are a great tool to figure out if a board is running out of spec, as identical settings should produce extremely similar performance results. Advanced memory timings are the one place where motherboard makers can still optimize for either stability or performance though, and those settings can impact some testing.

In our synthetic set of tests, the Gigabyte X570 Aorus Elite performed admirably, trading blows with the other X570 models we’ve tested. All results were within general run variance difference, with no anomalous data points. In general, Precision Boost Overdrive (PBO) showed some improvement across most tests, but not much overall.

3D Games

Checking in on the games, here we also see parity among the other boards tested and do not find any appreciable differences. PBO didn’t do much for gaming, especially at the higher resolution.

Timed Applications

The timed applications also show little difference overall. A tenth of a second separates the LAME results, while the Corona result shows just a couple of percent difference between worst to first. The same goes for Handbrake testing. PBO resulted in an improvement here of a couple percent, which is one of the better results using that feature.

Overall Performance

Overall performance differences between the boards we tested were negligible. The Gigabyte X570 Aorus Elite’s worst showing was .4% slower than the average and best was 2% faster. We could rerun these tests and get a slightly different story. So for all intents and purposes, the boards performed the same overall.

Power and Relative Energy Efficiency

When talking power consumption, the Gigabyte X570 Aorus Elite idled at 60W, the lowest result by several watts, and used 145W in Prime 95 Small FFTs. The average was 103W, the least amount of power overall. When enabling PBO on this board, the load use jumped to 215W in the same test.

Overclocking

I was excited to finally get overclocking and see what this inexpensive motherboard was able to accomplish. After a bit of tweaking, the X570 Aorus Elite was able to push our Ryzen 7 3700X to 4.16 GHz at 1.32V. Anything beyond this point yielded a near-instant stoppage of AIDA64’s stress test. Our EVGA CLC 240 cooler was able to keep the 3700X below 90 degrees celsius, which was adequate. But for those who would like to push larger chips, chances are a 240mm AIO of any type won’t be sufficient.

On the memory side of things, we were able to load up our G.Skill Trident Z Neo 4x8GB DDR4 3600 16-16-16-36 sticks without issue. Much beyond that value, the memory divider hits 1:2 situation and overall performance tends to drop without much in the way of increased speeds. AMD said DDR4 3600 is the sweet spot, and we're able to reach that without issue.

Overall, the Gigabyte board clocked well and brought the chip to its limit. We’ll test overclocking on the Asus TUF Gaming X570-Plus Wi-Fi and other boards as time goes on and see if they can do a better job, but from what we’ve seen in our own testing and elsewhere, the CPU itself is putting a lid on things.

Final Thoughts

The Gigabyte X570 Aorus Elite has proven itself to be a solid board with a sub-$200 price point, and it’s currently one of just a few boards under that threshold for X570. The Elite showed good performance overall, and was able to handle everything our suite threw at it when running stock, using PBO as well as manual overclocking. So don’t let the entry-level price fool you.

The board includes a total of six SATA ports, dual PCIe 4.0 x4 M.2 slots (one with a heatsink) and a good number of USB ports, including USB 3.1 Gen 2 ports out back and the front panel. However, it does not have a USB Type-C port on the rear IO. If that is a requirement, it will have to come from your chassis’ front panel.

If we compare this board to the Asus TUF Gaming X570-Plus Wi-Fi (also priced at $199) it comes with eight SATA ports, 8-channel audio (using a modified ALC1200 codec), and included Wi-Fi. That’s a more generous collection of features at the same price point. If you need the extra SATA ports and Wi-Fi, the Asus will be the better choice on that front.

But if you’re going to be using Ethernet, and don’t need a full cadre of SATA connectors, your choice may come down to aesthetics. On that front, the Aorus Elite’s theme agnostic approach won’t offend anyone and likely not wow them either. And if you like this board’s looks and would like wireless connectivity, the X570 Aorus Elite Wi-Fi costs about $10 extra, or $209.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Asus TUF Gaming X570-Plus Wi-Fi Review: Solid Features for $200

Joe Shields — Fri, 15 Nov 2019 19:47:15 +0000

Like the Gigabyte X570 Aorus Elite we recently reviewed, the X570-Plus Wi-Fi also hails from the budget end of AMD’s pricier new X570 platform and is priced at a penny under $200 / £233.99 at Newegg at time of publishing. It comes with PCIe 4.0 support, dual PCIe 4.0 M.2 slots, Wi-Fi and a USB 3.1 Gen 2 Type-C port out back, among other features.

Asus’ TUF lineup has changed from the ultra-robust, heavy shielding it was known for in years past and has evolved more toward gaming-centric boards with protection on individual parts such as the PCIe and DIMM slots. ESD guards, additional surge protection measures and military-grade components are still a part of the TUF lineup, but the additional hardening went beyond what was necessary for most use cases. These changes have made the Asus TUF Gaming X570-Plus Wi-Fi the second-least-expensive board in the Asus X570 product stack just missing the mark to be our best motherboards pick in the budget X570 category.

The TUF Gaming X570-Plus Wi-Fi’s $200 price will help buyers who want to purchase the flagship chipset and all that it offers, while leaving room in their budget for other important parts. Asus accomplishes this by not using ‘value adds’ like an integrated rear IO plate or loads of RGB lighting. The X570-Plus Wi-Fi handled overclocking our Ryzen 7 3700X without a complaint and performed well in our benchmarks at stock speeds, making it a good base to build a new AMD Ryzen 3000 series system.

Like other X570 motherboards, the Asus TUF Gaming X570-Plus Wi-Fi supports both Ryzen 2000 and Ryzen 3000 series processors. It includes eight SATA ports and four DIMM slots capable of supporting up to 128GB of DDR4 RAM, although curiously, overclocked memory speed support is not listed. For networking and audio, we find a Realtek L8200A GbE NIC and Realtek ALC S1200A audio codec (albeit an Asus’ tweaked version), which is capable of 7.1 surround and DTS ausio. Below is a complete list of specifications from Asus.

Read our How To Choose A Motherboard guide to help narrow down your buying options.

Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	12+2 phase (doubled - 7 phase, actual)
Video Ports	HDMI 1.4bDisplayPort
USB Ports	USB 3.1 Gen 2 (10 Gbps): 3x Type-A, 1x Type-CUSB 3.1 Gen 1 (5 Gbps): 4x Type-A
Network Jacks	(1) Gigabit Ethernet
Audio Jacks	(5) Analog + SPDIF
Legacy Ports/Jacks	✗
Other Ports/Jack	✗
PCIe x16	(1) v4.0
PCIe x8	✗
PCIe x4	(1) v4.0
PCIe x1	(2) v4.0
CrossFire/SLI	AMD CrossfireX
DIMM slots	(4) DDR4
M.2 slots	(1) PCIe 4.0 x4 / SATA + PCIe(1) PCIe 4.0 x4 / SATA + PCIe
U.2 Ports	✗
SATA Ports	(8) 6Gb/s
USB Headers	(1) v3.x Gen2, (2) USB v2.0
Fan Headers	(6) 4-Pin
Legacy Interfaces	PS/2
Other Interfaces	FP-Audio, RGB-LED, TPM
Diagnostics Panel	✗
Internal Button/Switch	✗ / ✗
SATA Controllers	✗
Ethernet Controllers	Realtek L8200A
Wi-Fi / Bluetooth	Intel Wireless-AC 9260
USB Controllers	✗
HD Audio Codec	Realtek ALC S1200A
DDL/DTS Connect	✗ / Yes
Warranty	3 Years

Included accessories are minimal, as we would expect on a budget level motherboard, but the basics are covered. Here’s a list of what ships in the box along with the board.

User’s manual
I/O Shield
Support / driver DVD
Asus 2T2R Wi-Fi antenna
2x SATA cables
Screw for M.2 slot
TUF Gaming sticker
TUF certification card

As far as looks go, the X570-Plus Wi-Fi looks the part of recent Asus TUF Gaming based boards. The PCB is jet-black with a lined pattern making its way from the bottom-right corner through the left VRM area and rear IO. The rear IO shield has TUF Gaming branding on top with some yellow accents scattered throughout the board.

The DIMM slots alternate black and grey, in keeping with the overall visual theme of the board, giving some accent to the all-black PCIe slots. Additionally, the top slot is protected with Asus Safeslot metal wrapping. Other connectors and slots are black, except for the RGB headers.

On the RGB LED front, the TUF Gaming has a minimalistic approach. To the right of the chipset heatsink, where we’d normally find the SATA ports, is where the LEDs are located. The LEDs themselves are on the bottom side of the board and shine through the lined pattern making for an attractive effect. Control over the integrated lighting and any strips attached to the headers are handled by the company’s Aura Sync software.

The X570-Plus Wi-Fi shouldn’t have any issues matching most build themes. It does indeed have a bit of the yellow color and branding that will stand out a bit, but they are accents more than dominant features. The pattern across the middle of the board is going to be the most polarizing aesthetic feature, as some prefer a more plain appearance.

Focusing in on the top portion of the motherboard, we can see a better view of the VRM heatsinks, shroud, and some of the headers found there. We won’t find RGBs under the plastic IO shroud, but the TUF branding is represented on this shroud, letting everyone know where the board came from. In the accessory stack, Asus also includes a couple of stickers for the battery as well as on the chipset fan hub, just in case you wanted to go all-in on the TUF branding.

The VRMs are covered by decent-size heatsinks which did the job at stock, Precision Boost Overdrive (PBO) and while overclocking. Asus states a 12+2 VRM setup, but the board has a ‘true’ rating of 4x3 + 2, since the controller, the ASP 1106GGQW is a 6-phase unit in 4+2 mode. Power is fed to the VRMs through a required 8-pin EPS connector, plus an optional 4-pin which will provide more than enough power for the Ryzen 3 CPU lineup. I’m not sure how overclocking would go on the beefier chips, especially the 3950X, but the TUF board held up just fine with a 3700X.

To the right of the socket area are four DIMM slots in that black/grey color scheme mentioned earlier. Just above them, we can see two fan headers (CPU and CPU_OPT), along with a standard 4-pin RGB header in white. All six fan headers on the board support both PWM and DC (4-pin and 3-pin) fans. The fan header count is more akin to a mid-range board than a budget model. To the right is the 24-pin ATX connector which feeds power to the board. The second (of three) RGB headers -- this one is addressable RGB -- is located just above the ATX connector.

Last in this area is the debug LED, which lights up during the POST and boot process. There are four LEDs, DRAM, CPU, VGA, and Boot. If there is a problem when the system is on its way up, wherever the problem is the LED will stay lit. This a useful tool for troubleshooting issues before entering Windows and a less-expensive alternative to a two-digit debug LED which shows codes. This is a nice feature for this price point.

On the bottom half of the board, the left side houses all the audio bits. The Realtek S1200A 7.1 channel chip is hidden under the metal Faraday cage with the TUF symbol on top. Below that are five Chemicon Japanese audio caps. The audio bits are separated from the rest of the motherboard to further reduce EMI and improve sound quality. At this level, users will not typically find op-amps and high-quality audio, but for most, the mature ALC 1200 will be sufficient.

The PCIe area consists of two full-length slots and two x1 slots. The primary GPU slot is protected by the Asus Safeslot, with metal surrounding the grey connector, while the others are black. As far as bandwidth goes, the primary GPU slot runs at PCIe 4.0 x16 while the secondary full-length slot runs at PCIe 4.0 x4 speeds. The x1 slots run at, you guessed it, x1 speeds. This is a typical configuration for this class of board and the X570 chipset.

Also found in this location are two M.2 slots. The top slot sits above the primary GPU slot while the second is below the secondary PCIe slot and has a heatsink. Both slots support PCIe 4.0 x4 NVMe as well as SATA-based drives and will fit M.2 modules up to 110mm in length. If you use an NVMe based drive, either PCIe 3.0 or 4.0, install it under the heatsink, as fast drives tend to run hot and can throttle in heavy use scenarios.

The chipset heatsink takes up a bit of real estate and like many X570 boards has a small fan to keep the 11W chip below it cool. The fan was inaudible over the video card fans in our setup, so there are no worries there. To the right and below the chipset heatsink are eight SATA3 6 Gbps ports. Four of the slots are closer to mid-board, while the other four are located on the bottom of the board -- an unusual setup which should still be easy for cable management. Where the SATA ports are typically found, directly to the right of the chipset heatsink, is where we find the sole RGB LED location and its diffused light shining through the PCB.

Across the bottom are several headers which include the 3rd RGB header, front panel USB header, along with another (of six) fan headers. There is nothing out of the ordinary to report here, so here’s a bulleted list of the other headers.

Front Panel Audio
Serial Port/COM connector
Fan header
2x USB 2.0 headers
Fan header
Front panel header
Clear CMOS jumper

Last but far from least is the rear IO. Unlike the Gigabyte X570 Aorus Elite we recently reviewed, the Asus board here uses the less-expensive IO plate instead of a more-attractive integrated unit. This shouldn’t matter to most as it is the rear IO and typically rarely seen.

On the rear IO itself, there are a total of seven USB ports, three of which are USB 3.1 Gen 2 (the Type-C port and the two aqua-colored Type-A ports). The other four Type-A ports are USB 3.1 Gen 1 flavor. If you have a PS/2 mouse or keyboard, there is a port for that as well. Also located on the rear IO are the Wi-Fi antenna headers, the Realtek L8200A LAN port, as well as a 5-plug audio stack with SPDIF. If you’re using an AMD APU and need video outputs, HDMI and DisplayPort here have that covered.

Software and Firmware

Asus’ software world revolves around AI Suite 3 (AIS3). AIS3 gives access to functionality such as system monitoring, power savings and overclocking as well as fan control and other fine adjustments. System monitoring is located across the bottom and covers CPU frequency, Voltage, temperature and fan speeds, giving the user a nice graphical readout of the state of their PC’s union.

AIS3 is divided up into different sections which cover different areas. These include Digi+ VRM, EPU, TurboV EVO, Fan Expert 4, and EZ Update. Users tend to have a love / hate relationship with this software, depending on who you ask. At times, for a hardcore enthusiast who works generally in the BIOS, AIS3 can get in the way of pushing things, so in general many advanced users will stick to the BIOS.

The Digi+ VRM section gives users access to control phases for the CPU and SOC as well as Load Line Calibration and current capability adjustments from within windows. These options help to stabilize the system when overclocking. What was entered is what was displayed so things here worked fine.

The EPU section is straightforward and displays options for power plans such as the amount of time it takes for the monitor to shut off as well as the time set for the PC to enter sleep mode. It includes three different modes to adjust -- Performance, Power Saving, and Away Modes. Users are able to tune what the fans do as well as how much the vcore lowers in power saving situations. This section is useful for those who may not want to dig into the power savings with a fine-toothed comb, but still need to make a few adjustments.

Next is the TurboV EVO section. Here you are able to adjust the CPU ratio and a multitude of voltages for overclocking purposes including VDDCR CPU and SOC Voltage, DRAM voltage and others. There is an auto-tuning tab which will automate the overclocking process with a touch of a button. A third tab allows for video card overclocking from here instead of a 3rd party application which some users can benefit from.

Next in up AIS3 is Fan Expert 4. As the name describes, this section is for fan control. It presents four preset options (silent, standard, turbo and full speed) as well as being able to set custom curves for each. I prefer using this utility as opposed to the BIOS if only for the better-looking interface. The BIOS offers a bit more fine-tuning, however.

Also included in AI Suite 3 is PC Cleaner (works like disk cleaner), EZ Update to update for updating drivers, as well as a system information option.

AI Suite 3 covers the gamut for monitoring and adjusting important functionality in your PC, sitting in the tray ready for use and isn’t much of a bother for most people. The application is a useful Windows-based tool and may provide some relief for those who may be intimidated working in the BIOS, though advanced users may skip it altogether.

Asus’ application to control RGB LEDs is Asus Aura Sync. The program is able to control the integrated RGB LEDs on the motherboard along with any products attached which support Aura Sync including graphics cards, DRAM, and any LED strips using the motherboard headers. Users are able to control the LEDs using 12 preset patterns as well as customizing each to some extent, be it the speed of the effect or how the color is displayed. You can also quickly disable the lighting as well through the app (and BIOS).

Firmware

Asus’ BIOS on the TUF series starts off in EZ Mode which displays useful information as well as having a few options to edit. The BIOS scheme uses a black background with blue highlights, differing from their ROG themed boards which are black and red.

EZ Mode displays details on the installed CPU and memory, fan speeds, storage, temperature and voltage for the CPU as well as an option for adjusting boot order. Users are able to access QFan control to set up fan speeds and profiles and even enable XMP/DOCP profiles from here.

In Advanced mode, we’re greeted by the familiar setup of headings across the top, along with some monitoring on the right side. The headings are My Favorites, Main, Ai Tweaker, Advanced, Monitor, Boot, Tool, and Exit.

My Favorites section is a place where you can customize what’s on the page with your own options. By default, it comes populated with memory frequency, voltage options, SATA and Onboard device configuration as well as boot options. Many, especially overclockers who tend to manipulate the most options, will populate this area with the most frequently used options in the BIOS so the most common functions are on one screen.

The Main section is informational for the most part, displaying details about the BIOS and CPU. Additionally, this is where users are able to set the system language, date and time.

Ai Tweaker is where the fun starts and the overclocking options are found. While there is a bit of redundancy on some items throughout the BIOS, Asus does a good job of putting the more commonly used options in one place. Within the section, the main page gives easy access to the CPU and BCLK ratios along with the major voltage options used in overclocking. Inside this section are sub-headings for Precision Boost Overdrive, DRAM Timing control, as well as Digi+ VRM for managing power and load line calibration functions.

The Advanced heading is where we find CPU, SATA, Onboard device, USB, and NVMe configuration options. Also within this section is the redundant part of Ai Tweaker with AMD Overclocking. Both the Gigabyte X570 BIOS and the Asus BIOS had the same section and the same disclaimer about doing damage to the PC, making me wonder if this is something AMD had board partners add in the BIOS. Inside of this section is where users can change PBO, voltages, and the DDR/Infinity fabric frequency and timings as well.

Inside the Monitoring section, we find information on the CPU temperatures (package and core) and motherboard temperature as well as fan speeds and voltages for the CPU and the major rails from the power supply. At the bottom of the page, we find Q-Fan configuration and is where to adjust fan speeds and profiles at the BIOS level.

Inside Q-Fan control is where adjustments of all the attached fans or pump would be handled. It displays a fan curve with three preset modes: silent, turbo, and full speed to choose from. In addition to the presets, users can create their own custom curve for each header when selecting the manual option.

The Asus BIOS over the past couple of generations has been one of the better and most ergonomic UEFI’s. While there is always going to be some redundancy, it is kept to a minimum. Options for common functions are easily found and in logical places. We don’t have any complaints about this BIOS.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

How We Test

Biostar X570GT8

Gigabyte X570 Aorus Elite

Gigabyte X570 Aorus Pro Wi-Fi

The test systems are as close as we can to running the same specifications. Though memory may be different brands, the speed and primary timings are the same as well as the GPU. We use as an updated W10 64-bit OS (1903) with all threat mitigations applied.

Test System Components

Sound	Integrated HD audio
Network	Integrated gigabit networking
Graphics Driver	GeForce 413.36

Benchmark Settings

Synthetic Benchmarks and Settings
PCMark 10	Version 2.0.2115 64Essentials, Productivity, Digital Content Creation, MS Office
3DMark	Version 2.9.6631 64Firestrike Extreme and Time Spy Default Preset
Cinebench R15	Build RC184115DEMOOpenGL Benchmark - Single and Multi-threaded
Cinebench R20	Version RBBENCHMARK281795Open GL Benchmark - Single and Multi-threaded
Application Tests and Settings
LAME MP3	Version SSE2_2019Mixed 271MB WAV to mp3: Command: -b 160 --nores (160Kb/s)
HandBrake CLI	Version: 1.2.2Sintel Open Movie Project: 4.19GB 4K mkv to x264 (light AVX) and x265 (heavy AVX)
Corona 1.4	Version 1.4Custom benchmark
7-Zip	Version 19.00Integrated benchmark
Game Tests and Settings
*Ashes of the Singularity: Escalation*	Version 1.31.21360High Preset - 1920 x 1080 / 2560 x 1440Crazy Preset - 1920 x 1080 / 2560 x 1440
*F1 2017*	2017 Season, Abu Dhabi track, RainMedium PresetUltra High Preset

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark and Final Analysis

All standard benchmarks and power tests are performed using the CPU’s stock frequencies (including stock AMD Turbo), with all of its power-saving features enabled. Optimized defaults are set in the BIOS and the memory set. The memory is manually set up to run at DDR4 3200 MHz (base spec for Zen 2) @ 16-18-18-38 primary timings.

Synthetic Benchmarks

In our synthetic set of tests, the Asus TUF Gaming X570-Plus Wi-Fi performed well, mixing it up with the other X570 motherboards. All results were within general run variance difference with no anomalous data points. In general, PBO showed some improvement across most tests, but not much overall.

3D Games

Game results continue to show a very tight set of results without any appreciable differences. PBO didn’t do much for gaming, but did show an almost 5% gain in Ashes at 1080p using the ‘crazy’ settings.

Timed Applications

Our timed The timed applications also show little difference between the boards. Enabling PBO showed notable improvements here performing on average a bit over 4% better than stock in these tests.

Overall Performance

Overall performance differences between the boards we tested were negligible, outside of the PBO results which showed gains in timed applications, but otherwise nothing notable. The X570-Plus Wi-Fi’s worst showing was in productivity where it showed 6% less performance in those tests. Creativity testing showed it was 2% faster there, so it's a give and take it seems (that and PCMark’s consistency isn’t the greatest).

Power & Relative Energy Efficiency

On the power consumption front, the Asus TUF Gaming X570-Plus Wi-Fi idled at 68W, with load power reaching 143W. With PBO enabled, we saw 221W in our Prime 95 testing, nearly 80W more than stock. If you are the type of user interested in saving some power, leave PBO disabled as the performance gains are simply not worth the notable power increase.

Overall efficiency proved to be good here with a positive 7.6% result at stock. Enabling PBO kills that with a large power increase for not even a 1% overall performance bump.

Overclocking

Overclocking on this board yielded 4.224 GHz using 1.343V on the core. While the clock speed is a bit higher than what was achieved on the X570 Aorus Elite, this was due to spread spectrum and the floating BCLK as we used the same 42.25 multiplier. Anything above this voltage left us with temperatures above 90C, too hot for comfort. Regardless, anything above this multiplier at this voltage caused an error in stress testing.

Load voltage was fairly stable with LLC set to auto. With a BIOS setting of 1.343V, load in Windows turned into 1.328V. Raising the LLC to 2 ended eliminated the droop and we ended up at 1.328V which was similar to the Gigabyte overclocking results.

We successfully loaded up our GSKill Trident Z Neo 4x8GB DDR4 3600 16-16-16-36 sticks without issue here as well. Beyond that value, the memory divider hits 1:2 situation and overall performance tends to drop without much-increased speeds. So we aren’t pushing it past that point. AMD said DDR4 3600 is the sweet spot and we're able to reach that without issue on this board.

Overall, the board clocked well and brought the chip to its limit. This is the second board we’ve overclocked this CPU on so far and were met with the same result. Perhaps a higher-end board with a more robust VRM could help things, but the main issue is getting those temperatures in order.

Final Thoughts

The Asus TUF Gaming X570-Plus Wi-Fi ($200) passed all of our tests with flying colors both at stock and when overclocked with PBO and manually. The feature set versus the similarly priced Gigabyte X570 Aorus Elite has it as the preferred board between the two, even more so if you’re in need of integrated Wi-Fi and a USB 3.1 Gen 2 Type-C port on the back.

Other features include the full complement of eight SATA ports (the Aorus Elite had six), dual PCIe M.2 slots (with one heatsinked) and a VRM capable of driving our Ryzen 7 3700X to its thermal limits while not melting the heatsinks attached. If a front panel USB 3.1 Gen 2 Type-C port is a requirement, the Gigabyte board is your only option at the sub $200 price. Another value-added feature on this board is the debug LED which is not typically found on entry-level boards.

The Asus TUF Gaming X570-Plus Wi-Fi is a competent motherboard which starts off at a very reasonable price. Performance against similarly priced and more expensive boards is, for all intents and purposes, the same and even in our overclocking tests. Between the TUF and the Aorus Elite, the Asus is the more feature-rich option. If you’re after rear USB-C and Wi-Fi, while keeping your board budget tight, look no further than the Asus TUF Gaming X570-Plus Wi-Fi.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

ASRock X570 Aqua Review: Feature-Packed, Liquid-Cooled

Thomas Soderstrom — Fri, 15 Nov 2019 19:46:28 +0000

Features and Layout

If it’s just high-end quality and commonly used features you’re looking for in an AMD-based X570 motherboard, you can probably find a board with most of them for half the price of ASRock’s $1,000 X570 Aqua. But then you won’t get a built-in monoblock (multi-device liquid cooling water block) at that price, or likely Thunderbolt 3. The X570 Aqua is designed for custom cooling enthusiasts who want to flaunt their expensive high-end components, and being the best product is only half that battle. Aesthetics matter when you’re spending this much on a motherboard.

ASRock X570 Aqua Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	"EATX" (10.5"-deep)
Voltage Regulator	14 Phases
Video Ports	HDMI, DisplayPort IN, Thunderbolt 3
USB Ports	10 Gbps: (2) Type-C (via Thunderbolt 3)5Gb/s: (6) Type A
Network Jacks	10GbE, Gigabit Ethernet, (2) Wi-Fi Antenna
Audio Jacks	(5) Analog, (1) Digital Out
Legacy Ports/Jacks	(1) PS/2
Other Ports/Jack	Thunderbolt 3 (40Gb/s), BIOS Flashback
PCIe x16	(3) v4.0 (x16/x0/x4, x8/x8/x4)
PCIe x8	✗
PCIe x4	✗
PCIe x1	(3) v2.0
CrossFire/SLI	3x / 2x
DIMM slots	(4) DDR4
M.2 slots	(2) PCIe 4.0 x4 / SATA
U.2 Ports	✗
SATA Ports	(8) 6Gb/s (four via ASM1061 controllers)
USB Headers	(1) v3 Gen2(2) v3 Gen1(1) v2.0
Fan Headers	(5) 4-pin
Legacy Interfaces	System (Beep-code) Speaker
Other Interfaces	FP-Audio, ARGB LED, (2) RGB LED
Diagnostics Panel	Numeric
Internal Button/Switch	Power, Reset, CLR_CMOS / ✗
SATA Controllers	(2) ASM1061 PCIe 2.0 x1, Integrated (0/1/10)
Ethernet Controllers	Aquantia AQC107 PCIe x4, WGI211AT PCIe
Wi-Fi / Bluetooth	Intel AX200 802.11ax (2.4 Gb/s) / BT 5.0 Combo
USB Controllers	JHL7540 Thunderbolt 3 PCIe 3.0 x4
HD Audio Codec	ALC1220
DDL/DTS Connect	DTS Connect
Warranty	3 Years

Update Nov. 15: Samples are still available from Newegg but not from Amazon. With a limit of one per purchase, the number of samples remaining from the original 999 appears to be a closely guarded secret.

So few motherboards include a monoblock for custom liquid cooling that it’s not even addressed in our standard specs template, yet it’s the most expensive feature to be found on the X570 Aqua. These low-volume parts are individually machined on CNC equipment rather than being cast or cut-to-length from profile-match extrusions, which is why the ones we’ve seen for previous products typically start at $200. Such an item would almost double the price of a typical X570 board, so if this were merely a $500 motherboard, some of you could just read the Pros/Cons/Verdict and click the buy button. But, of course there’s much more to the X570 Aqua than its custom cooling abilities.

To begin with, all the stuff that looks like silver-painted plastic isn’t -- it’s aluminum. Everything from the decorative port shroud to the filler panel that fits between the M.2 heat spreaders is, at least in part, aluminum. The decorative pieces are covered in the stuff (over a plastic frame), while the functional pieces are aluminum throughout.

Peeling away two of those pieces, we find the X570 Aqua’s other two headline features, its AQC107 10Gb Ethernet connection and the JHL7540 40Gbps Thunderbolt 3 controller. Intel’s i211AT Gigabit Ethernet controller sits between them, and a special DisplayPort pass-through connector for Thunderbolt video (more on that later) is seen above the Aquantia controller.

While M.2 heat spreaders are generally optional and typically don’t substantively alter drive performance (NAND actually runs better warm), the upper M.2 slot cover (shown center in photo below) is also the heatsink for the 10GbE controller, and that makes it a mandatory part. If your drive doesn’t fit under a heat spreader (typically because it already has one), it will need to go into the lower M.2 slot. And that slot is limited by both its shorter 80mm exposed length and its PCH-based connection. Only the top slot gets 120mm support and the CPU I/O’s four direct pathways.

The custom monoblock is also seen above, where we find that everything but the CPU interface has a mirror finish. The CPU portion itself has a fine grain to better-hold thermal pastes that might otherwise pull away as it shrinks: we’ve seen this on untouched three-year-old builds, and most users will probably want to keep such a complicated installation together for a long time. We noticed that ASRock’s technicians had some difficulty with the thermal pads that cover the MOSFETs, so we made sure to reposition everything perfectly before doing our installation upside down to avoid similar issues.

Even the DisplayPort on the I/O panel is an input for Thunderbolt pass-through, as ASRock sells the only graphics cards that have an internal Thunderbolt output, and those cards are designed for this board. Other I/O features include two Type-C connectors with full Thunderbolt 3 support, six USB3 Gen1 outputs (5Gb/s), the network ports for those above-mentioned Ethernet controllers, a pair of Antenna jacks for the factory-installed AX200 Wi-Fi 6 module, five analog audio jacks, a digital optical audio output, a PS/2 keyboard/mouse port, a USB BIOS Flashback button, and an HDMI port that is an actual output for AMD’s Socket AM4 APUs.

The top view presents a familiar layout with three PCIe x16 slots, three PCIe x1 slots, and triple-slot spacing between the first two x16 slots to support oversized graphics card coolers that are more than two slots thick. The sixteen CPU pathway division also applies in the usual x16 to x8/x8 modes if cards are detected in the second long slot, but ASRock went out of its way to make sure that the third slot’s four PCH lanes didn’t exclude any of the motherboard’s other features. The first step in that direction may have been to eliminate the third M.2 storage slot seen on a few other boards, but those four lanes were already needed by the Thunderbolt 3 controller. What to do?

ASRock starts by reducing its eight SATA ports to six PCH lanes by putting four of its ports on a pair of legacy ASM 1061 PCIe 2.0 controllers. Yes, that means that only the other four ports can support four devices at full speed, and it also means that only those four ports can be RAIDed together, but the next step is an even bigger potential complication.

The real trick to how ASRock serves so many slots simultaneously, and the real reason why its x1 slots and SATA controllers are PCIe 2.0, is that the firm uses ASM1187e PCIe 2.0 x1 to x7 smart switch to connect all of these. While the lack of a suitable PCIe 4.0 replacement isn’t surprising (given the thermal problems we’ve seen on AMD’s own controllers), we were surprised not to see ASRock use a PCI 3.0 version such as the ASM2812 for this task. Had the upper x1 slot been eliminated (since it’s rarely used due to being so close to the primary graphics card slot) we would think that even the four-device ASM2806 may have sufficed.

The X570 Aqua’s bottom edge features front-panel audio, trusted platform module, RGB, addressable RGB, front-pane USB 2.0 and 3.0, PWM fan, and legacy PC speaker/3-pin power LED headers, plus a status code display and buttons for power/reset/CLR_CMOS. A second USB 3.0 is found beside a USB3 Gen2 front panel and another four-pin fan header at the middle of the board. Three additional fan headers are placed along the board’s top edge, and a second RGB header is located at the top/front corner.

One thing you’re not paying for here is a back plate. Reviewers tend to like these because they ease testing outside of a case, but the practical function for completed builds is limited at best.

The X570 Aqua includes a driver/application disc, documentation, a legacy SLI bridge, a tube of thermal paste and replacement thermal pads, a dual-band Wi-Fi antenna, four SATA cables, M.2 and several replacement monoblock screws, and a special internal cable for DisplayPort to Thunderbolt passthrough using one of ASRock’s specially-designed graphics cards. Depending on whether or not the special ASRock cable fits their card's Mini DisplayPort output in the correct orientation, users who decide to do that passthrough externally may need to supply their own cable.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Firmware, Software and Overclocking

Firmware and Software

The current X570 Aqua firmware has no EZ-mode interface, and we probably shouldn’t expect one given the board’s elite-enthusiast target market. The OC Tweaker menu affords us most of the settings we need to push our CPU and DRAM to respective limits, along with five registers to store custom settings for future reference.

The Tool menu includes an RGB LED submenu, which may work better for many users than the included Polychrome Sync software. Other tools include an SSD overwriter and access to the board’s Instant Flash integrated firmware update utility.

Four of the X570 Aqua’s five fan headers are switchable between PWM and voltage-based fan RPM control, with the CPU fan header having only PWM. Users can choose between several fan profiles, or configure a custom slope using basic arithmetic.

ASRock’s A-Tuning works, according to our readings, to allow users to configure their overclock through Windows. Its System Info tab reports a different CPU thermal reading than the one from AMD’s software, though the one AMD uses can be found here as SB TSI CPU .

The version of Polychrome Sync included on the installation disc functions, but its memory settings are so laggy that we often found the memory displaying the previous pattern after applying the change. Frustratingly, the update offered by ASRock’s APP Shop wasn’t compatible with this board. Hopefully ASRock fixes this lighting software issue sooner rather than later.

Overclocking

ASRock X570 Aqua

Asus ROG Strix X570-E Gaming

ASRock X570 Taichi

We’re using most of the hardware from our first X570 review to compare the X570 Aqua to our first four boards, but the original Fractal Design Celsius S24 isn’t designed to be used on this monoblock, so we switched it out for an MCP35X. Given the extra voltage regulator and PCH heat that the radiator would be required to control, we likewise updated that to a Coolstream XE 240 with a pair of Vardar 2200RPM fans. A tubing kit from Bitspower and a few additional fittings from Alphacool brought it all together.

The X570 Aqua ties for first in CPU overclocking with the Asus X570-E Gaming and MSI X570 Ace, but the Ace beats it in DRAM OC. We also noticed the CPU-Z is now reporting a dip in core voltage under Prime95 small-FFTs, regardless of the level of droop compensation set, though the highest stable speed remained consistent with those previously-tested boards. Full-CPU-load wattage for the entire system fluctuated between 224 and 234 watts.

Performance is the point of overclocking, and the X570 Aqua makes a clean sweep with a 3% advantage in memory bandwidth.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark Results and Final Analysis

Gigabyte’s GeForce RTX 2070 Gaming OC 8G and AMD’s Ryzen 7 3700X update the hardware configuration of our most-recent X470 test system, while a newly configured test suite brings all the compatibility benefits of Microsoft’s latest Win10 patches.

Benchmark Results

We start our benchmarks with synthetics in hopes of determining any performance anomalies in individual components, but the only thing that stands out in the charts is a miniscule advantage in PCMark Productivity.

Moving through the test, we also find that the X570 Aqua bumped our Cinebench results up a level, but dropped to last place in MP3 and H.264 encoding. The board’s overall performance is dead-on average.

Power, Heat and Efficiency

We found that the alternative cooling configuration needed to connect the X570 Aqua’s monoblock consumed an extra eight to 10 watts, so we deducted 10W from the readings when comparing systems that used the less power-hungry closed-loop cooler. Even then, the extra components of the X570 Aqua required extra power.

As we’ve seen in the past, the cooling advantage of this monoblock is limited to components other than the CPU. We use the highest continuous reading in these charts, and while the uncooled chokes of the other boards ran far hotter than the MOSFETs, both of these component groups are addressed by the X570 Aqua’s monoblock.

The X570 Aqua consumes a great amount of power at stock settings, and the only thing keeping these results from looking even worse is that the previous ASRock board had already dragged down the efficiency average. So if power consumption is key for you, you may want to avoid ASRock altogether in your X570 build.

Final Thoughts

We first show a value chart that cheapskates can use to make fun of big spenders, in that it doesn’t address the value of any added features.

With that out of the way, we can’t think of any reason for a motherboard like the X570 Aqua to cost more than $500, sans monblock. Meanwhile, Bitspower is selling monblocks for other boards for around $200. So anyone who buys the X570 Aqua is paying for something in addition to the motherboard and monoblock. Perhaps it’s the fancier trim that covers much of the monoblock’s surface? Or perhaps they’re merely paying for exclusivity, with ASRock labelling each production board as one of 999. That would be 999, plus ours, plus whatever other review sites got one, plus whatever units the company is keeping on hand for firmware development, memory validation, and so forth. If you’re one of those people who likes to pay for exclusivity, we won’t stand in your way.

The X570 Aqua is a nice board apart from its price and its PCIe 2.0-connected parts, the latter of which probably isn’t a concern to a target market full of extreme enthusiasts. The board keeps its voltage regulator and PCH nicely cooled with only the noise of the liquid cooling system the user chooses to install. It has the full Thunderbolt 3 experience built in, it counts 10GbE among its dual networking, and tops that off with a Wi-Fi 6 controller. The speedy networking and Thunderbolt additions likely add quite a bit to the board’s asking price as well.

In terms of missing features, the only things we would really ask for is an updated RGB app and a few more LEDs around the monblock's main window and outlet port. It’s not that all of us are big fans of RGB, but if you’re going all-in on a $1,000 motherboard, you might as well go all-out on the lighting so you can see what you spent your money on, right?

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Get the AMD Ryzen 7 3700X for $25 Off

Zhiye Liu — Fri, 18 Oct 2019 13:22:56 +0000

AMD Ryzen 7 3700X (Image credit: Newegg)

The season of black friday deals is starting. Newegg is currently selling the AMD Ryzen 7 3700X CPU for $304.99, saving you $25.

Get the AMD Ryzen 7 3700X for $304.99.

With its eight cores, 16 threads and 36MB of total cache, the Ryzen 7 3700X is a great processor for gamers and enthusiast that require decent firepower. The chip is based on AMD's Zen 2 microarchitecture, which means you get to enjoy groundbreaking features like 24 PCIe 4.0 lanes and DDR4-3200 memory support right out of the box.

The Ryzen 7 3700X flaunts a 3.6 GHz base clock and a 4.4 GHz boost clock. The octa-core part is rated for 65W, and it's accompanied with AMD's Wraith Prism CPU cooler, which comes with all the RGB goodness. However, we do recommend you pick a third-party cooler if you plan to overclock the processor.

Should You Buy This CPU?

Be sure to check out our in-depth AMD Ryzen 7 3700X review before opening your wallet for this deal.

You can also review our CPU buying guide for help with your decision. To see where this processor ranks among others currently available, including from rival Intel, check out our CPU hierarchy page. And for other CPUs we love, see the best cheap CPUs, our favorite gaming CPUs and favorite CPUs for productivity performance.

AMD's Ryzen 3000 Boost-Fixing BIOS Leaks Out, We Test With Ryzen 9 3900X and Ryzen 7 3700X

palcorn@outlook.com (Paul Alcorn) — Tue, 10 Sep 2019 02:00:02 +0000

(Image credit: Tom's Hardware)

AMD's unreleased firmware, which the company says will fix the boost behavior of its Ryzen 3000 processors, has leaked onto the Chiphell forums. We grabbed the download and did a round of testing to see if the new BIOS and SMU fix the boosting behavior of the Ryzen 9 3900X and Ryzen 7 3700X processors.

We have to caution, however, that this is a leaked beta BIOS revision that may not be in its final state, so we'll have to take the results with a grain of salt. In either case, we do see some improvements that fall in line with our expectations for the Ryzen 7 3700X, but we also spotted an odd performance regression with the Ryzen 9 3900X, indicating this firmware is a work in progress.

AMD's Ryzen 3000 series processors landed two months ago, bringing a new level of performance and value for the mainstream desktop as the company took the lead in the race to the leading-edge 7nm node, the first time in its history that it had managed to beat Intel to a denser manufacturing process. But the company's triumphant moment has been marred by persistent reports that the chips aren't achieving their rated boosts speeds, an issue thrust into the spotlight by a recent survey conducted by YouTuber Der8auer in which a surprising number of respondents reported they weren't reaching their rated boost clocks.

That was followed by Intel citing a report that claims reliability is behind AMD's apparent, but not proven, reasons for reducing its chips' frequencies.

AMD announced this week that it had identified an issue with its firmware that reduces performance in some situations and that it would update the community on an incoming fix on September 10.

We dug deep into the issue with tests that suggest AMD had altered the boost behavior of its processors after launch, leading to less aggressive boost behavior if the chip surpasses the 75C threshold.

First we'll look at the "what," to see if the boost frequencies are in fact fixed with this new leaked firmware, and then we'll took a look at the "how" to see the changed behavior that brings the issue under control.

Hitting The Boost Switches

For the first round of tests, we followed the general testing methodology we outlined in our first investigation of Ryzen 3000's boost behavior. That round of testing found that AMD's Ryzen 3000 processors come with a mix of both faster and slower cores, with the slower cores unable to reach the rated boost specification. To help mitigate the issue, AMD uses the new Windows 10 scheduler to target workloads at the fastest cores first.

The beta MSI BIOS we're using for our tests comes from the Chiphell forums, and it wasn't released through MSI's official channels, meaning there is a chance this isn't the actual BIOS that MSI will release to fix the issue. More news on the official fix will come tomorrow, September 10, 2019.

We ran a series of single- or lightly-threaded tests in rapid succession. The test begins with five iterations of a LAME workload (~35 seconds apiece) that are inherently single-threaded. This is followed by one run apiece of POV-RAY and Cinbench R20, both in single-core testing mode. AMD processors downshift based on the power requirements of the instructions from the task, so these single-threaded tests give us the best chance of capturing single-core boost activity. We're using MSI's X570 Godlike motherboard and AMD-provided chips for testing.

Ryzen 7 3700X Boost Frequencies

Here we plotted the frequency of all eight cores on the left axis, and the temperature (red line at the bottom of the chart) on the right axis. The Ryzen 7 3700X processor is running at its stock settings and a Corsair H115i cooler is running at full speed.

This is the latest version of publicly-posted motherboard firmware for the MSI X570 Godlike motherboard. Here we can see the Ryzen 7 3700X tops out at 4.375 GHz during the run. While this does fall short of the 3700X's rated 4.4 GHz boost, it is by a relatively slim margin. However, the shortcomings vary based on silicon quality, and many users have reported much larger deltas with the 3700X (up to ~250 MHz).

We applied the new ComboPI1.0.0.3ABBA AGESA firmware, and as you can see, the Ryzen 7 3700X now reaches its rated 4.4 GHz across the board. We'll dive in deeper on how AMD rectified the issue shortly.

Ryzen 9 3900X Boost Frequencies

Our tests with the Ryzen 9 3900X don't show the across-the-board improvement we expected, which may be due it still being a beta version.

Here we can see the Ryzen 9 3900X with the older ComboPi1.0.0.3ABB AGESA code. This is the last publicly-posted firmware for the X570 Godlike motherboard. We can see that the chip tops out at 4.575 GHz during the run, with the workload migrating among the cores during the test. That's only 25 MHz short of the chips' spec, but many users have reported up to 300MHz deltas, and more.

With the new firmware the chip peaks at 4.625 GHz during the opening moments of the test. The chip settles to 4.6 GHz during the LAME tests, then runs at 4.55 GHz during the POV-RAY portion of the test. Oddly, the chip drops to a lower threshold during the Cinebench run at the tail end of the test, only reaching 4.425 GHz during that portion (yellow lines).

While we see a higher peak boost, the chip runs at a lower frequency for the majority of the test. This might be a poor implementation of the firmware for this particular motherboard, or could be due to the beta nature of the BIOS. We'll have to wait until newer firmwares are released for this, and other, motherboards to get the full picture. We've pinged MSI for comment to see if the company can reproduce this result.

	Ryzen 7 3700X Original Firmware	Ryzen 7 3700X Fix	Ryzen 9 3900X Original Firmware	Ryzen 9 3900X Fix
LAME (lower is better)	14.016s	13.937s	13.578s	13.438s
POV-RAY Single-Thread Test (higher is better)	257.35 PPS	259.11 PPS	266.77 PPS	266.76 PPS
Cinebench Single-Thread Test (higher is better)	505.44	509.63	525.342	513.32

Even with the working fix with the Ryzen 7 3700X, the faster firmware provides only a marginal performance improvement with our chip. This is largely because our sample already came close to the rated specifications, and users with chips that fall short by a larger margin will experience more of a performance uplift.

The Ryzen 9 3900X doesn't experience as much uplift, registering only a slight improvement in the LAME encoding score, and essentially tying the older firmware in the POV-RAY tests. More importantly, we see a performance regression during the Cinebench test, indicating that this firmware may not be tuned for the Ryzen 9 3900X yet.

Changed Temperature Thresholds

Because the Ryzen 9 3900X exhibited an odd performance regression, we decided to focus on the Ryzen 7 3700X for this salvo of tests. We'll follow up with more testing for the Ryzen 9 3900X when the official firmwares land.

Our most recent testing focused on whether or not AMD had changed the settings of the SMU, a small unit inside the processor that overrides configuration parameters, to reduce the boost frequencies. Dialing back the temperature thresholds for boost activity reduces overall clock speed during extended workloads, which can be used to reign in clock speeds. One industry source claims these adjustments were made to increase the chips' longevity, but while it appears that AMD adjusted the boost parameters, we can't conclusively say it was to extend chip longevity.

We began the tests with all fans and the pump on a Corsair H115i running at full speed. We then kicked off a single-threaded Cinebench test to expose the maximum boost attainable with our Ryzen 7 3700X sample. We allowed this test to run for 60 seconds so the chip could settle into its 'natural' state during the workload, then unplugged the fans and pump and allowed the chip's temperature to rise to 95C. This is the maximum temperature rating of AMD's 7nm processors, which is a lowered range compared to the previous-gen's 100C. That means AMD doesn't have as much thermal headroom to play with.

This testing technique allows us to record changes to the frequency as temperature increases. We did our best to isolate all parameters, and due to that nature of this testing, the cooling solution and ambient temps aren't a factor. These are the same tests we ran in our recent piece, but we're using a different motherboard for this round of testing.

Here we see the test results with the BIOS provided to reviewers for the first round of Ryzen 3000 testing. Again, we plotted the frequency of all eight cores on the left axis, while the temperature is plotted on the right. The temperature reading is the rising red line, and we've added markers to note where the temperature first reaches 75C, 78C, and 80C, which are the focus areas. This BIOS comes with AGESA version 1.0.0.3A and SMU version 46.37.0.

The chip remains comfortably above 4.2 GHz as it moves between 70C and 80C.

Here we can see the latest version of the firmware posted to MSI's site. This test shows the chip dialing back frequency during the focus area, cutting it to a flat 4.2 GHz from 75C to 80C. That results in less aggressive boosting activity during extended workloads. This changed behavior is likely one of the root causes for the Ryzen 3000 boost issues.

We generated these results with the new beta BIOS and SMU version that fixes the boost frequencies for the Ryzen 3 3700X. With older motherboard firmwares, the chips would drop into different power states at the 75C and 80C thresholds. Now the chip stays above 4.2 GHz from 75C to 78C, indicating that Shamino's mention of a new middle-frequency limit was probably accurate.

That means there is more to this fix than just dialing the firmware back to the same limits as the first round of "reviewer BIOS's," which were faster than the BIOS's made public after launch.

We also spotted that MSI added a new Collaborative Power and Performance Control 2 option to its BIOS. This is a software feature that manipulates Ryzen 3000's power states from within the operating system. This is similar to Intel's Speed Shift technology and reduces power state transition latency from 30ms to 1ms, which ultimately saves power and boosts efficiency. The feature comes enabled in the latest AMD chipset drivers and the Windows 10 May update (and newer).

We enabled the feature for the previous tests, but disabled it for this final test. Here we see that the chip doesn't appear to boost correctly with the feature disabled. The presence of this new setting implies that AMD has also made adjustments to this feature, as well.

Thoughts

Oddly enough, the fact that our Ryzen 7 3700X sample is already of good quality, barely missing the rated speeds even with the older firmwares, works against us. The performance uplift with the new BIOS is minimal, but the changes to the thermal thresholds indicate that the new firmware should correct the boost behavior for 3700X's of lower quality.

Unfortunately, we'll have to wait until tomorrow for the official word from AMD on the matter. While this BIOS revision does deliver some of the expected improvements in boost activity, at least with our Ryzen 7 3700X sample, we'll wait until the official release before we come to any firm conclusions.

We'll dive in deeper with these tests, and add frequency and voltage scaling, as well as a broader spate of real-world application testing, as soon as we receive the new firmwares. This firmware appears to be a work in progress, but shows that the bugs are being ironed out and should be fixable. Stay tuned.

Gigabyte X570-I Aorus Pro Wi-Fi Review: Ryzen 3 ITX on the Cheap

Joe Shields — Tue, 03 Sep 2019 13:00:00 +0000

Features and Specifications

Gigabyte’s X570-I Aorus Pro Wi-Fi is a compact, Mini-ITX board made for small-form-factor builds that’s capable of handling anything from an HTPC to a full-fledged gaming rig, depending on the hardware installed. It includes dual M.2 slots, fast RAM support, as well as a USB 3.1 Gen 2 Type-C port in back, rivaling some full-size ATX alternatives.

The X570-I also includes a solid 8-phase digital VRM, WiFi 6 support, 7.1 channel Realtek ALC1220-VB premium audio codec, and fast memory support up to DDR4 4400(OC). Priced at $219.99 on Newegg.com, it undercuts the ITX ASRock X570 Phantom Gaming-ITX/TB3 that we recently reviewed by about $20.

Gigabyte’s Aorus boards are the company’s gaming and enthusiast lineup, usually including features such as RGB LEDs, metal “armor” on the DIMM and/or PCIe slots, electrostatic discharge (ESD) guards, along with more of a focus on styling. The X570-I Aorus Pro Wi-Fi embodies the Aorus ethos, while also offering an array of functionality at a very reasonable price point. If ITX isn’t for you, Gigabyte’s X570 lineup includes all sizes and a wide range of price points, from the entry-level X570 UD to the flagship X570 Aorus Xtreme offering a bit of something for everyone. We saw most of the company’s X570 lineup for the first time at Computex 2019 earlier this year.

Like other X570 boards, the Gigabyte Aorus X570-I Aorus Pro Wi-Fi supports both Ryzen 2000 and Ryzen 3000 series processors and includes four SATA ports, two PCIe 4.0 x4 M.2 slot on the back. Its two DIMM slots are capable of supporting up to 64GB of DDR4 RAM, with overclock speeds up to a fast DDR4 4400 MHz. For networking and audio, we find an Intel GbE NIC and Realtek ALC1220-VB audio codec which runs 7.1 surround. Below is a complete list of specifications from Gigabyte.

Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	ITX
Voltage Regulator	8 Phase (6+2)
Video Ports	HDMI 2.0 DisplayPort
USB Ports	USB 3.2 Gen 2 (10 Gbps): 1x Type-A (red) USB 3.1 Gen 1 (5 Gbps): 4x Type-A
Network Jacks	(1) Gigabit Ethernet
Audio Jacks	(3) Analog
Legacy Ports/Jacks	✗
Other Ports/Jack	✗
PCIe x16	(1) v4.0
PCIe x8	✗
PCIe x4	✗
PCIe x1	✗
CrossFire/SLI	✗
DIMM slots	(2) DDR4 - DDR4 4400(OC)
M.2 slots	(2) PCIe 4.0 x4 / SATA + PCIe
U.2 Ports	✗
SATA Ports	(4) 6Gb/s
USB Headers	(1) v3.x Gen1, (1) USB v2.0
Fan Headers	(2) 4-Pin
Legacy Interfaces	✗
Other Interfaces	FP-Audio, 2x RGB-LED headers
Diagnostics Panel	✗
Internal Button/Switch	✗ / ✗
SATA Controllers	✗
Ethernet Controllers	Intel GbE
Wi-Fi / Bluetooth	Wi-Fi 6 - Wireless 802.11ax / Bluetooth 5.0
USB Controllers	✗
HD Audio Codec	Realtek ALC 1220-VB
DDL/DTS Connect	✗ / ✗
Warranty	3 Years

Like all boards, Gigabyte includes an accessory stack with the purchase of the board. These stacks have been shrinking over the years, but Gigabyte still provides us with what we need to get started. Below is a list of what is included in the box with this board.

User Manual
Support/driver DVD
2T2R Wi-Fi antenna
Two SATA cables
Thermal pad for M.2 drive
Gigabyte sticker
RGB LED extension cable

The board itself is black all around, including the connectivity ports and VRM heatsink with its brushed-aluminum finish. The rear IO sports an integrated IO plate giving the inexpensive board a more premium feel. The chipset heatsink doubles as the first M.2 slot and comes with a fan to help keep the chipset and M.2 drive below (assuming you’ve installed one) cool. This stacking shouldn’t be an issue to keep both the chipset and M.2 module cool, but isn’t optimal. But again, given the size of this board, there isn’t a whole lot of room for features that take up as much space as an M.2 drive.

Both the PCIe and DIMM slots are reinforced by Gigabyte’s Ultra Durable PCIe and Memory Armor, protecting the slots from heavy components. The chipset heatsink itself has a lined portion as well as brushed-aluminum styling, which shows off the familiar Aorus falcon branding. RGB illumination comes from eight LEDs on the right side of the board and is controlled by the company’s RGB Fusion 2.0 software.

Overall, the styling here is reserved (especially considering the garish Aorus boards from a few years ago) and will fit with almost any build theme. If the included RGB lighting isn’t enough, there are additional headers onboard to connect to.

For full-size boards, we normally split it up into the top and bottom half and focus on each. But with a Mini-ITX board, there really isn’t a point as the board is so small.

Focusing in on the left side to start, we can see the VRM heatsink and integrated rear IO plate dominating that are. The VRM heatsink has a lot of mass and kept the power bits underneath running cool during stock and overclocked testing. Outside of the brushed-aluminum finish, we see the Aorus name in chrome on the top.

Sending power to the VRM is a single 8-Pin connector, located in the top-left corner next to one (of two) fan headers. This delivers power to what Gigabyte says is an 8-phase VRM. In this case, it is a true 8-phase VRM, not using phase doublers to get there and including a high-quality Infineon IR35201 8-phase (6+2) controller. This setup proved to handle stock and overclocking our Ryzen 7 3700X with ease and should handle the higher core count chips as well.

To the right of the socket are the armored DIMM slots, which support up to DDR4 4400 (OC). This isn’t quite as high as the 4533 MHz rating we saw on the ASRock ITX board, but this board doesn’t have the integrated circuit (IC) clearance issues we saw on ASRock’s ITX board. And clocking memory much above 3600MHz on this platform results in very minimal performance gains (at best) anyway. The DIMM slots on the Aorus board use a single-sided locking mechanism, which is likely a cost-cutting measure. But the single-side setup is actually is my preferred setup, versus both sides locking.

To the right of the socket, we see the 24-pin ATX power connector, front panel header, four SATA3 6 Gbps ports (supporting RAID 0, 1, 5, and 10), along with USB 3.0 and USB 2.0 headers. Flanking the DIMM slots towards the bottom are the two RGB LED headers (3-pin ARGB and 4-pin) supporting standard 5050 RGB strips. This is a curious location for these headers, but AIBs do what they need to do to shoehorn features into these compact boards with extremely limited real estate.

Also in that area is the second fan header. Note that either fan header supports both PWM- or DC- controlled devices. We would like to have seen one more fan header on the board, but again, space is tight. Any connected fans can be controlled through the Smart Fan 5 software in Windows or from the BIOS. Both worked without issue in our testing.

The bottom portion of the board is taken over by the large chipset and M.2 heatsink, located just above the full-length PCIe 4.0 x16 slot. Using the latest BIOS (F4j), the chipset fan remained quiet during our testing and kept the chipset at reasonable temperatures.

Last, to the left of the chipset heatsink is the front audio header, along with a Trusted Platform Module (TPM) header.

We don’t talk about the back of motherboards much, as typically the only items worth noting are any phase doublers or perhaps an I/O chip for monitoring. In this case, the board sports an integrated base plate for increased rigidity. It’s also where the second M.2 slot is located, this one without a heatsink. Both M.2 slots support PCIe and SATA-based modules up to 80mm length.

Overall, Gigabyte’s board layout is as good as it can be considering the lack of physical space at play here. Two M.2 slots on a board this size is quite good, and likely will be useful to more users than a Thunderbolt 3 port like that found on the more-expensive ASRock X570 ITX board.

The rear IO consists of an integrated IO panel and continues the black theme, giving it a more premium look than the typical flimsy snap-in IO panels. Ports on the back consist of two HDMI 2.0 ports and a DisplayPort for video output (for use with AMD’s APUs). As for USB, there’s a total count of six, with two USB 3.2 Gen 2 ports (Type-A red, and Type-C), along with four USB 3.0 ports -- blue, with the Q-Flash Plus port white. To the right of this port is the Q-Flash Plus button. We see the Intel-based LAN port, WiFi 6 antenna 2T2R connectors, and the three-plug audio stack. I have to admit I was a bit surprised not to see the full 5-plug plus SPDIF outputs here. But again, most people will likely be plugging in stereo or 2.1-chanel audio with a couple of speakers and a sub.

Outside of the audio stack, there’s plenty of connectivity around back. While six USB ports aren’t the most we’ve seen, it should be enough for a small form factor board to get by, especially when also using the front panel headers.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Software and Firmware

Software

Moving on to software, Gigabyte offers users a plethora of applications, including RGB control, system monitoring and overclocking, bios updates, and more. Organizing all these applications is a program called App Shop, which is a single interface with links to the other Gigabyte software, Windows settings, as well as some third-party software.

The App Shop loads into the tray and when needed, clicking on the icon brings up the screens seen below, allowing easy access to whatever board-related settings or controls you need. If you do not like a bunch of icons on the desktop, this can certainly help.

I downloaded and installed a couple of applications that I find useful to look at a App Shop bit deeper. In this case, we have @BIOS, Easy Tune, RGB Fusion 2.0, and SIV.

@BIOS is a simple Windows-based application designed to update the BIOS. It displays information about the BIOS flash memory size and type along with the current version. Users can update from Gigabyte servers or from a file located on your PC.

One really unique feature of this software is the Face Wizard section, where you can upload your own image to be used instead of the BIOS splash screen, taking system customization to another level.

The Easy Tune application is where users are able to see a sort of state of the union of the system, including CPU and memory speeds, along with temperature and voltages. Although it is informational, there is also plenty of functionality that comes along with Easy Tune.

The first section is labeled Smart Boost and gives basic canned settings of “Default,” where the CPU has one core at 3.6 GHz, and “OC” where all cores are boosted to 3.8 GHz. While this works, it’s better to use PBO or manual overclocking and customize from there.

For overclocking, we would use the Advanced CPU OC section. This section contains both CPU ratio and BCLK values, which can be edited. There are several voltage options to change as well, including CPU Vcore and SOC, DRAM, VDDP and VDD18, which are all important when pushing your CPU or memory overclocks.

The Advanced DDR OC is where you adjust memory frequency or enable XMP profiles. There isn’t much going on in the memory section, but that’s best edited from the BIOS anyway. The last section, Advanced Power, is where to change VCore current protections, PWM phase control, as well as CPU and SOC Loadline Calibration values.

All in all, Easy Tune works as described. I was able to push the overclock a bit on the CPU from within Windows, preventing any time wasted from rebooting in the BIOS. But the memory functions do require a reboot for proper memory training.

Next up is the SIV (System Information Viewer) application. This tiny app displays detailed information about the clock domains, CPU, Motherboard, and Memory.

SIV also incorporates Smart Fan 5, controlling the system fans. The auto section shows four preset fan modes (quiet, standard, performance, and full speed) while the advanced section is where custom curves are set. It also sports a hysteresis setting to minimize a fan ramping up or down if the temperature is on the bubble.

In the System Alert tab, SIV is able to send the user alerts as well, if thresholds are crossed. And there are several, from PSU voltages to CPU and motherboard voltage, along with more familiar temperatures such as CPU, chipset, or VRMs. If monitoring things down to that level is how you roll, the X570-I Aorus Pro Wi-Fi has you covered.

Gigabyte’s weapon of choice for RGB illumination control is arena is RGB Fusion 2.0. This lightweight application is able to control the integrated RGB LEDs, as well as any compatible 5050 RGB LED strips when connected to the two onboard headers.

The application allows you to choose which device(s) to change, and displays 10 different patterns including static, game, pulse, flash, double flash, color cycle, music, random, wave, and the all-important off setting. Within many of these, we’re able to change the color, speed and brightness of the patterns.

Firmware

Moving on to the firmware, we’ve seen in previous X570 Gigabyte boards that the company has improved the overall look and feel. Gigabyte has seemingly consolidated items to make the BIOS a bit more ergonomic and user-friendly, by grouping like items together. Being an Aorus SKU, there is a black background with orange accents on the top and bottom, with the lettering in white and quite legible.

By default (after a fresh install of the latest UEFI), we are greeted by the Easy Mode version of the BIOS. Easy Mode is both informational as well as offering a bit of functionality. It displays details on the motherboard and the installed BIOS, the CPU and RAM, as well as a SATA/PCIe/M.2 modules. Easy Mode also covers CPU speed, temperatures and voltage, along with memory frequency and voltage, system/PCH/VRM temperatures as well. The boot sequence is also able to be changed from this screen.

Inside Advanced Mode, we see the more typical style, with headings across the top and the information/editable fields below. Across the top are Favorites, Tweaker, Settings, System Info, Boot, and Save and Exit.

The Tweaker section is where the overclocking magic happens. Most (if not all) of the settings you need to push these CPUs to the limit, are found in this section and within a sub-heading or two. You’ll find CPU overclocking options such as clock ratio and BCLK, Memory settings including XMP and a manual section for individual timing control as well as all the necessary voltages.

Sliding to the right, the Settings section is where adjustments can be made to platform power, IO ports, AMD CBS, as well as AMD’s own overclocking section that the company injects into board partner UEFIs. In addition to these options, here is where you’ll find PC Health as well as Smart Fan 5 for the BIOS.

When looking at the System Information section, you’ll find it’s mostly informational, covering the BVIO, processor, LAN MAC address and other system information. Q-Flash Plus can also be accessed from this section as well.

Boot, along with Save and Exit, are pretty self-explanatory.

Overall, I do like how Gigabyte lays out its BIOS, making it easy to read and efficient. Most everything needed is organized where you’d expect it, making using the BIOS a pleasant experience.

Last but not least is Smart Fan 5 from the BIOS. The differences from the Windows version aren’t substantial. In addition to being able to set custom fan curves, you are able to set the temperature input (what sensor is used to speed up/slow down the fan) and a fan stop mode, which is good for when silence is paramount.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

How We Test

We’ll be comparing the Gigabyte X570-I Aorus Pro WiFi to the ASRock Z570 Phantom Gaming-ITX/TB3 we recently reviewed, as they are both Mini-ITX X570 size boards. We’ve also included the Asus TUF Gaming X570-Plus Wi-Fi as a data set as well. Just note that it’s a larger full-ATX model.

Comparison Products

ASRock X570 Phantom Gaming-ITX/TB3

Asus TUF Gaming X570-Plus Wi-Fi

Gigabyte X570-I Aorus Pro Wi-Fi

Test System Components

CPU	AMD Ryzen 7 3700X
CPU Cooling	CLC 240
Graphics	Asus RTX 2070
Memory	G.SKILL Ripjaws V Series 16GB (4 x 4GB)
Memory	G.Skill Trident Z RGB (4x 8GB)
Power Supply	EVGA G3 750W
SSD	OCZ RD400

Drivers

Sound	Integrated HD audio
Network	Integrated gigabit networking
Graphics Driver	GeForce 413.36

Benchmark Settings

Synthetic Benchmarks and Settings
PCMark 10	Version 2.0.2115 64Essentials, Productivity, Digital Content Creation, MS Office
3DMark	Version 2.9.6631 64Firestrike Extreme and Time Spy Default Preset
Cinebench R15	Build RC184115DEMOOpenGL Benchmark - Single and Multi-threaded
Cinebench R20	Version RBBENCHMARK281795Open GL Benchmark - Single and Multi-threaded
Application Tests and Settings
LAME MP3	Version SSE2_2019Mixed 271MB WAV to mp3: Command: -b 160 --nores (160Kb/s)
HandBrake CLI	Version: 1.2.2Sintel Open Movie Project: 4.19GB 4K mkv to x264 (light AVX) and x265 (heavy AVX)
Corona 1.4	Version 1.4Custom benchmark
7-Zip	Version 19.00Integrated benchmark
Game Tests and Settings
*Ashes of the Singularity: Escalation*	Version 1.31.21360High Preset - 1920 x 1080 / 2560 x 1440Crazy Preset - 1920 x 1080 / 2560 x 1440
*F1 2017*	2017 Season, Abu Dhabi track, RainMedium PresetUltra High Preset

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark and Final Analysis

All standard benchmarks and power tests are performed using the CPU’s stock frequencies (including stock AMD Turbo), with all of the power-saving features enabled. Optimized defaults are set in the BIOS and the memory set manually to run at DDR4 3200 MHz (the base spec for Zen 2) @ 16-18-18-38 primary timings.

Synthetic Benchmarks

In our synthetic set of tests, the Gigabyte played nice, winning some and losing some compared to the other boards on the charts. Most results were within general run variance, outside of perhaps the MS Office scores, where enabling Precision Boost Overdrive (PBO) on this board yielded a 5% performance loss. Outside of that result, PBO showed only a slight gain in timed applications. Stock results were on par with others.

3D Games

Our game results have continued to show minimal differences, with all results sitting within 1%.

Timed Applications

The timed applications also showed the biggest difference here between the stock setting and PBO, with the latter showing around a 4% improvement in timed applications.

Overall Performance

Overall performance differences between the boards we tested were not much at all. The Gigabyte performed as well as all the other boards, within a couple of percent here and there. Only productivity showed nearly a 4% increase.

Power and Relative Energy Efficiency

Idle power use was low 66W, even when PBO enabled. Load wattage was read at 142W, while PBO managed to show less. Apparently, default settings have the boost doing better in this regard.

With that, overall efficiency on this board in default mode was 7% higher than the other boards in the charts.

Overclocking

Overclocking on our Gigabyte ITX board yielded the familiar 4.25 GHz clock using 1.35V (with 1.35V set in the BIOS). As per usual, the next tick up takes too much voltage, even for our Corsair H150i to handle on this chip.

The VRM provided stable voltage according to software. We set 1.35V in the BIOS and the LLC set to Turbo yields a slight Vraise / increase in load voltage from what was set in the BIOS. When at stock/optimized defaults, it’s on auto and allows for some vdroop.

On the memory side, the Gigabyte handled our GSkill Neo sticks set to DDR4 3200 CL16 and running the XMP settings at DDR4 3600, all while keeping the magic 1:1 ratio AMD prefers. We didn’t test any higher to the rated DDR 4400 since your mileage may vary depending on the quality of the IMC in the CPU as well as the sticks used.

In the end, the X570-I Aorus Pro Wi-Fi managed to overclock our 3700X without issue using similar voltages as the other boards we tested. With the VRM setup as is, we expect it to handle the 3900x withoutissue as well.

Final Thoughts

Our second little board that could, the Gigabyte X570-I Aorus Pro Wi-FI, presented itself as a solid board throughout testing. In the optimized default setting, the performance results melded well with all of the data sets we’ve captured so far. With PBO enabled, we saw a slight increase in performance in the timed tests, but most others stayed the same or even performed ever so slightly worse. To get the most out of PBO on any board, it seems like some additional tweaking is needed, assuming your cooler can handle it.

Regarding features, the mini-ITX board managed to squeeze in two M.2 slots where the more expensive ASRock X570 ITX board has just one. SATA support is the same, with a total of four ports that should be enough for most users, especially considering the two M.2 slots. The power delivery on this board proved to be plenty capable with our mid-range 3700X and should do well with higher core count chips as well due to the parts used and non-doubled power phases.

The Aorus Pro board should easily fit into most build themes, and includes some RGB lighting accents. If you plan to use additional RGB strips, two onboard headers will help with that, although their placement is a bit odd due to real estate limitations. The rear IO panel is integrated, like most of Gigabyte’s X570 lineup, and gives the board a premium look and feel, avoiding dealing with the typically flimsy IO panels.

As far as comparing it head to head with the ASRock X570 Phantom Gaming-ITX/TB3, about the only tangible difference can be found in the Thunderbolt 3 capability of the ASRock versus the two M.2 slots on the Gigabyte. Both are plenty capable of driving the CPU to their thermal limits power-wise. If thunderbolt or dual M.2 slots are a requirement, both are very good motherboards for the money and your choice is made for you.

But more people will probably find a use for the two M.2 slots than Thunderbolt, and the Gigabyte board is priced around $20 cheaper ($219.99 vs $239.99). With its comprehensive feature set, low price, and solid performance, the Gigabyte X570-I Aorus Pro Wi-FI should be the go-to ITX board on X570 for those who don’t need Thunderbolt 3.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

AMD Ryzen 3700X and 3900X Shortages Still Persist Almost Two Months After Launch

mc@matthewconnatser.net (Matthew Connatser) — Mon, 26 Aug 2019 22:14:02 +0000

(Image credit: AMD)

It was to be expected that the Ryzen 7 3700X and Ryzen 9 3900X would be in high demand; the former is $70 cheaper than the 3800X for about the same performance, and the latter is the world's first mainstream 12-core CPU that also happens to be AMD's best gaming CPU (though not by a massive margin). What is unexpected is the ongoing shortage with the 3700X and 3900X that has not entirely gone away since July 7th. These new CPUs have only been available in small quantities since launch and have been selling out almost immediately, leading to price gouging on eBay.

The shortage is so bad that third parties are selling the 3700X and 3900X at inflated prices. The 3700X is being sold for almost as much as a Ryzen 7 3800X at retailers like Amazon and eBay while the 3900X has been going for as much as $750 (the MSRP of next month's Ryzen 9 3950X which has 16 cores) on Amazon, with most sellers on Amazon and eBay pricing it around $600. Today, you can find 3700Xs at most retailers, but on Amazon they are only up for preorder and will only arrive at the end of August at the earliest.

Other Ryzen SKUs, however, seem to have escaped these supply issues, most notably the 3800X, which is basically the same as the 3700X but binned a little better and $70 more. Perhaps AMD has intentionally constrained the supply of the 3700X to encourage impatient people to just buy the 3800X. On the other hand, the Ryzen 5 3600 doesn't seem to have ever gone out of stock (which would force buyers to choose the 3600X), so perhaps AMD's supply issues are entirely down to unprecedented demand.

Sadly, there doesn't really seem to be an obvious solution for AMD or buyers other than just waiting or buying what's available right now (whether it's at MSRP or not). It's not easy for AMD to just increase production on these CPUs, which have a unique supply chain and require a 12nm IO chiplet from GlobalFoundries and one or two 7nm core chiplets from TSMC. AMD also uses the 7nm core chiplets for its EPYC Rome data center processors that offer up to 64 cores, which could be a factor as the company ramps up its data center lineup.

There's also the matter of the 3900X and 3950X requiring two compute chiplets, unlike the 3800X and below which require just one. Unfortunately, it remains unclear when we will see widespread availability of the Ryzen 7 3700X and Ryzen 9 3900X.

ASRock X570 Phantom Gaming-ITX/TB3 Review: Full-Featured, Compact

Joe Shields — Mon, 26 Aug 2019 13:00:00 +0000

Features and Specifications

We’ve reviewed quite a few full-size (ATX) X570 motherboards at this point, and our current favorite there is the Asus ROG Strix X570-E Gaming. Now it’s time to shift focus to ITX form factor boards, for those looking to build something more compact. The first of these smaller models we’ll be looking at in depth is the ASRock X570 Phantom Gaming-ITX/TB3. As its name suggests, the miniature board comes with a Thunderbolt 3/USB capable Type-C port, which is rare even on full-size boards, let alone ITX options like we’re looking at here.

The Phantom Gaming-ITX/TB3 includes a robust 10 Phase VRM, 7.1 channel Realtek ALC 1220 audio, integrated Wi-Fi 6 abilities, and one of the highest memory speed support listings we’ve seen, at DDR4 4533+(OC). Priced at $239, it lands near the budget side of things (remember that X570 boards tend to be pricier than their X470 counterparts overall), but still offers quite a bit in the tiny package.

The Phantom Gaming lineup is, as its name implies, the gaming product line from ASRock. The goal of this line, according to the company, is to provide top of the line gaming products to gamers, professionals, and PC enthusiasts. There are three boards from ASRock in this family. The entry-level X570 Phantom Gaming 4, X570 Phantom Gaming X (which we will have a review of soon as well), and the Phantom Gaming-ITX/TB3 we are looking at now. Outside of these boards, ASRock has a full lineup of X570 boards, from entry level to flagship.

Like other X570 boards, the ASRock X570 Phantom Gaming-ITX/TB3 supports both Ryzen 2000 and Ryzen 3000 series processors and includes four SATA ports, a single PCIe 4.0 x4 M.2 slot on the back and two DIMM slots capable of supporting up to 64GB of DDR4 RAM, with overclock speeds up to a whopping DDR4 4533 MHz. For networking and audio, we find an Intel I211-AT GbE NIC and Realtek ALC 1220 audio codec which runs 7.1 surround. Below is a complete list of specifications from ASRock.

Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	10 Phase (doubled 4+1 phase actual)
Video Ports	HDMI 1.4bDisplayPort
USB Ports	USB 3.1 Gen 2 (10 Gbps): 2x Type-A, 1x Type-C (Supports 40 Gb/s Thunderbolt protocol) USB 3.1 Gen 1 (5 Gbps): 2x Type-A
Network Jacks	(1) Gigabit Ethernet
Audio Jacks	(5) Analog + SPDIF
Legacy Ports/Jacks	✗
Other Ports/Jack	✗
PCIe x16	(1) v4.0
PCIe x8	✗
PCIe x4	✗
PCIe x1	✗
CrossFire/SLI	✗
DIMM slots	(2) DDR4 - DDR4 4533+(OC)
M.2 slots	(1) PCIe 4.0 x4 / SATA + PCIe
U.2 Ports	✗
SATA Ports	(4) 6Gb/s
USB Headers	(1) v3.1 Gen1, (1) USB v2.0
Fan Headers	(3) 4-Pin
Legacy Interfaces	✗
Other Interfaces	FP-Audio, RGB-LED, Thunderbolt 3
Diagnostics Panel	✗
Internal Button/Switch	✗ / ✗
SATA Controllers	✗
Ethernet Controllers	Intel I211AT
Wi-Fi / Bluetooth	Wi-Fi 6 - Wireless 802.11ax
USB Controllers	✗
HD Audio Codec	Realtek ALC1220
DDL/DTS Connect	✗ / ✗
Warranty	3 Years

Features

The included accessories for this little board provide most of what we’d expect, and what the average consumer will need to get started. Here’s a list of what ships in the box, along with the board.

Quick Installation Guide
Support DVD
2T2R Wi-Fi antenna
2x SATA cables
1x screw for M.2 slot
ASRock sticker

Quite frankly, there isn’t much room on the board with all its features for styling cues, as the available real estate is obviously a lot smaller ATX. To that end, we don’t see any stenciled patterns. The only design features are on the rear IO cover, VRM heatsinks, as well as the RGB lighting located across the bottom of the board by the PCIe slot.

The rear IO cover doubles as the VRM heatsink for the left bank of power bits. It’s black and grey, sporting a brushed-aluminum finish in the middle with the Phantom Gaming branding on there as well. The heatsink on top is tall and thin. But with half of these phases dedicated to the SOC, it shouldn’t have an issue with overclocking.

The chipset fan reminds me of the X58 days, with the large heatsink on the then-discrete Northbridge, that had heatsinks and a fan to keep the hot-running part cool. Here we see a triangle-shaped cooler for the PCH and what looks to be a 40mm fan underneath. With this BIOS, the fan is audible over the GPU, a case fan, and the Corsair H150i AIO in use in stock form. It isn’t particularly loud, but it is easily heard. With all the other boards we have looked at so far, outside of powering on, the chipset fans were not audible during our testing. So if you’re bothered by fan noise, you should either look elsewhere or wait a bit and check forums to see if a future BIOS update fixes this issue.

Most SFF builds are hidden inside small cases without windows. For any that do have windows, the board will mesh with most any build theme as the only colored accent is the Phantom Gaming name on the rear IO cover. The RGB LEDs are bright and illuminate the backside and bottom of the board. If the six LEDs are not enough, two additional strips (one regular, the other addressable), can be added via headers.

For full-size boards, we normally split it up into the top and bottom half and focus on each. But with an Mini-ITX board, there really isn’t a point, as the board is so small.

Starting off on the left with the rear IO cover, we get a better look at the brushed-aluminum finish, along with the Phantom Gaming branding and red accents, which slice their way through the back portion of the cover. The grey portion is used as a heatsink for the left VRM bank as well as the chipset heatsink via heat pipe connection. While it may not have the surface area we’re used to seeing, it's beefy. Both heatsinks did get warm during testing, but nothing out of the ordinary.

Feeding power to the VRMs is a single 8-pin EPS connecter, located between the rear IO cover and top VRM heatsink. This feeds power to what ASRock mentions is a 10 phase VRM. The power delivery consists of very good parts, including an Intersil ISL69147 controller in 4+2 mode, with the CPU phases doubled (by ISL6617A doublers). The Dr. Mos design uses the latest Smart Power stage technologies with current and temperature monitoring of each phase, which ASRock says delivers smoother and neater power to the CPU. The CPU power delivery is very good, in particular for such a small board. There shouldn’t be any issues with higher-wattage Ryzen chips.

In the top-right corner, we find both RGB headers (4-pin and 3-pin addressable), along with two of the three fan headers. The third fan header is located on the bottom portion of the board also next to the DIMM slots. The fan headers are of the hybrid variety and support both DC- and PWM-controlled fans. Control over the fans is covered in the BIOS or through the Phantom Gaming Tuning app and the FAN-Tastic Tuning section.

While the header count is low, one needs to consider the lack of real estate on the board, as well as the fact that the chassis these boards fit in generally have less room for fans in the first place. In other words, the count should be adequate when using an appropriately sized case for the board.

The two DIMM slots are black and do not come with reinforcement. The board will support up to 64GB of DDR4 with speeds up to DDR4 4533+ when overclocking. This rating is the highest we have seen so far. But with the memory we have, we won’t be able to test that high. With smaller boards like this, the memory traces are typically shorter, allowing for better memory overclocking capabilities.

The curiosity here is due to all of the IC’s found just above them. Typically, this area is clear except for perhaps a cap or two. Here we see a fan header and other various bits on top. The other curious bit is that even though it is rated for DDR4 4533, the fastest memory kit on the qualified vendor list is rated at DDR4 4266 and that is one kit. The next highest value is DDR4 3600. That said, the board handled our GSkill Neo kit at 3200MHz and its XMP rating of 3600 Mhz without issue.

On the right edge of the board is the 24-pin ATX connector, front panel USB 3.0 header, and four SATA3 6 Gbps ports. The SATA ports support RAID 0, 1, and 10 if you are looking for a bit more speed or parity.

Towards the bottom we can see the large chipset heatsink and fan, along with headers shoe-horned between it and the DIMM slots. We see the front panel header, USB 2.0 and TPM headers here. Across the bottom is the Realtek ALC1220 chip and just below that is the front panel audio header. We don’t find EMI shielding on these IC’s, likely due to a lack of room for it.

Next is the single PCIe 4.0 x16 slot. The slot is reinforced with ASRock’s Steel Slot technology (metal) providing extra anchor points for heavy graphics cards, and additional signal stability according to the company.

So where is the M.2 slot? On the back. The small board has space for just one PCIe 4.0 x4-based drive up to 80mm in length. It does NOT support SATA based M.2 modules. Any SATA drives will need to connect via the four standard SATA ports. Being located on the back of the board, the NVMe M.2 slot does not come with a heatsink, nor is there much room for one between it and your case. So if you’re considering one of those speedy PCIe 4.0 drives with the thick heatsinks, you should probably look elsewhere.

Before we wrap this section up, take a look around the socket area. Notice we don’t see the typical AM4 mounting hardware in place, nor the mounting locations. What you see are actually the Intel mounting holes for 115x socket, a mutant of a solution if you will. This peculiar implementation was done for compatibility reasons. ASRock says that while there are plenty of CPU coolers that work with AM4, some do not support AM4, with most of those coolers being low profile and designed specifically for ITX boards. However, those coolers do support Intel’s mounting. By making this switch, ASRock has effectively improved the cooler availability for the board. That said, it still means if you don’t already have a compatible cooler to carry over from a previous build, you’ll have to buy one, rather than installing the cooler AMD ships in the box. This will probably cause confusion with buyers who aren’t sure exactly what they’re getting into with this particular board.

The rear IO plate on the Phantom Gaming-ITX/TB3 is integrated and implements a similar design to what is seen on the rear IO cover on top, with black on the edges and grey in the middle. The rear IO includes five total USB ports with three ports supporting USB 3.1 Gen 2 (10 Gbps) speeds. The Type-C port doubles as a Thunderbolt 3 port, with the full 40 Gbps throughput. Outside of that we see a legacy PS/2 combo port for a keyboard or mouse, the Wi-Fi antenna connections, a clear CMOS button, and video outputs in the form of DisplayPort and HDMI 2.0. Additionally, we see the Intel LAN port as well as the 5-plug audio stack plus a S/PDIF connection.

The rear IO includes the basics for a board of this class. The rare feature is the Thunderbolt 3 port. That said, five USB ports of any type is a fairly low count and can easily be used up today, so be aware of that limitation if you regularly plug lots of accessories and peripherals into the back of your PC.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Software and Firmware

Software

On the software side, ASRock gives users a few useful applications for system monitoring and overclocking with the Phantom Gaming Tuning program, RGB control, and even an ‘app shop’ for easy downloading and installation of ASRock apps and other 3rd party applications.

ASRock’s App Shop is a small-footprint application giving users convenient access to their own apps including the Polychrome RGB LED utility, XFast LAN, Restart to UEFI, and the app charger. In addition to the ASROck apps, some third-party applications including Chrome and Norton Security can also be downloaded from here.

Also within this application, you can access the latest BIOS and drivers for the system. This section displays a list of drivers/BIOS and the current version and shows the latest version available. Simply select which to update (or use the update all function) and it will update your drivers.

Overall, the application was useful for a first-time update situation and its role for one stop updating. I let it update any drivers needed and it was successful in doing so.

Next up is the Phantom Gaming Tuning application. As the name implies, this program is used to tune your system and offers monitoring capabilities as well. It starts off in the Operation Mode screen, which allows users to select between different performance modes, including Power Saving, Standard, and Performance Modes.

Overclocking capabilities are handled in the OC Tweaker section. Here we have access to CPU frequency and voltage, SOC and DRAM voltage, among other secondary voltages. Unlike other similar applications from the board partners, ASRock doesn’t give a CPU multiplier and BCLK adjustments. In order to change the CPU speed you need to enter a specific clock like 4225 MHz. Outside of not having that kind of granular control, the few changes I made with it in Windows (clocks and voltage) worked without issue.

For monitoring, the Phantom Gaming Tuning application lists several domains including clocks, fan and temperature as well as voltages. Here again we do not see BCLK listed, but a simple clock speed. CPU, motherboard and PCH temperature sensors are listed here, along with any fans which happen to be plugged in. We can see the SB fan spinning at over 5K RPM here. Critical voltages including Vcore, CPU VDD, DRAM, and others are listed, along with the three major rails from the power supply.

Last but not least is FAN-Tastic Tuning. This section is where you can apply custom fan curves for each fan. Simply jump in and run the fan test (finds the min/max speeds of the attached fans/pumps), then select the fan you would like to control using the dropdown in the upper left, and tweak to your heart’s content.

Overall, I like the Phantom Gaming Tuning application. It worked without issue in all of its functionality and provides system monitoring. Though it was easy to set clocks, I do wish there was more granularity in overclocking, as in options for a CPU multiplier and BCLK instead of simply entering a clock value. That said, I can see how this can be better, especially for those looking for a more simple setup.

ASRock’s Polychrome Sync application is used to control the RGB ecosytem on the motherboards as well as any attached compatible devices. It will read your environment and add access to any devices which can be controlled through the software. In total, there are over 15 different preset modes/patterns that can be applied to the RGB lighting. You can also customize the color and speed of many of these modes.

Polychrome worked well out of the gate and for the screenshot you see below. However, upon a reboot and bringing up the application again, it did not recognize the memory and sync it in the ecosystem as it did previously. No system changes (BIOS updates, software updates) were done in the meantime so we aren’t sure what happened there.

Firmware

Jumping into the ASRock BIOS, we’re greeted by a fairly standard setup with headings across the top and data on the remaining part of the screen. Theme wise, the Phantom Gaming-ITX/TB3 has a mostly black background with a red/maroon accent sweeping in from the center to the upper right corner with any writing in white. One thing that we noticed on this UEFI is the lack of an ‘Easy Mode’. So far, all vendors and boards we have tested so far included one up until now. Outside of that minor quibble, it was smooth sailing all around with this BIOS.

Digging deeper, the first section we’ll discuss is Main. This screen is purely informational, covering the UEFI version, Processor type, speed, and microcode, as well as the total memory installed.

The bulk of the work for an overclocker will be handled in the OC Tweaker section. Here we can find access to the CPU details from SMT modes, memory speed and timing adjustments, as well as voltage functionality. Like the Windows-based Phantom Gaming Tuning software, we do not find a BCLK or CPU multiplier function in the BIOS, either. In other words, you’ll need to manually input the clock speed in MHz instead of using a multiplier or BCLK value for finer tweaks. Other than that, all of the functions needed to overclock your Ryzen 2/3 processor are located in this spot.

There are plenty of adjustments for DRAM, including all the primary, secondary, and tertiary timings and of course the ability to set XMP mode. Support is listed for DD4 4533+ when overclocking, so there are high hopes from ASRock on its abilities. As we mentioned earlier, the Mini-ITX size boards tend to overclock better due to shorter trace routing and improved signaling. But as always, your mileage may vary.

Inside the Advanced section is where users are able to configure the CPU, Onboard devices (HD audio, WAN/BT, PS/2, etc), storage, as well as having that second AMD Overclocking sub-section we’ve seen in each BIOS so far.

Within the AMD Overclocking area, there is both redundant and more granular options for the DDR and Infinity Fabric, PBO, SOC and other voltages. I find reaching this CPUs maximum can be achieved without going into this section, but it can be useful for other things such as manually configuring PBO options.

The Tool heading is where you’ll find BIOS adjustments for RGB LEDs, SSD secure erase and NVMe sanitization tools. This is also where you can flash the UEFI through Instant Flash.

Inside the H/W Monitor portion, you get a system status of temperatures, fan speeds, voltages, and power supply voltage. Below these readings is where to find fan control. The fans have speed options from silent to full speed, along with the ability to customize and create your own fan curve. Unlike some firmwares, this one doesn’t have a fancy GUI. Still, setting a custom curve was straightforward. Additionally, the board has the ability to select a temperature source to react on, either the CPU or motherboard.

The Security and Boot sections are self explanatory, with nothing sticking out as missing here. If you need to set a system password at the BIOS level, Security is where it is handled. Adjusting anything with regards to the boot process, including boot order, time outs, and fast boot, is located in the Boot section.

The BIOS in ASRock’s Phantom Gaming-ITX/TB3 looks good and worked well for our testing. Outside of the odd lack of BCLK and CPU multiplier control, placement of all the options felt logical and easy to access.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

How We Test

We’ll be comparing the ASRock Z570 Phantom Gaming-ITX/TB3 to Gigabyte Z570-I Aorus Pro Wi-Fi (review upcoming), as they are both Mini-ITX size boards. We’ve also included the Asus TUF Gaming X570-Plus Wi-Fi as a data set as well. Just note that it’s a larger full-ATX model.

Comparison Products

ASRock X570 Phantom Gaming-ITX/TB3

Asus TUF Gaming X570-Plus Wi-Fi

Gigabyte X570 Aorus Pro Wi-Fi

Test System Components

Sound	Integrated HD audio
Network	Integrated gigabit networking
Graphics Driver	GeForce 413.36

Benchmark Settings

Synthetic Benchmarks and Settings
PCMark 10	Version 2.0.2115 64Essentials, Productivity, Digital Content Creation, MS Office
3DMark	Version 2.9.6631 64Firestrike Extreme and Time Spy Default Preset
Cinebench R15	Build RC184115DEMOOpenGL Benchmark - Single and Multi-threaded
Cinebench R20	Version RBBENCHMARK281795Open GL Benchmark - Single and Multi-threaded
Application Tests and Settings
LAME MP3	Version SSE2_2019Mixed 271MB WAV to mp3: Command: -b 160 --nores (160Kb/s)
HandBrake CLI	Version: 1.2.2Sintel Open Movie Project: 4.19GB 4K mkv to x264 (light AVX) and x265 (heavy AVX)
Corona 1.4	Version 1.4Custom benchmark
7-Zip	Version 19.00Integrated benchmark
Game Tests and Settings
*Ashes of the Singularity: Escalation*	Version 1.31.21360High Preset - 1920 x 1080 / 2560 x 1440Crazy Preset - 1920 x 1080 / 2560 x 1440
*F1 2017*	2017 Season, Abu Dhabi track, RainMedium PresetUltra High Preset

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark and Final Analysis

All standard benchmarks and power tests are performed using the CPU’s stock frequencies (including stock AMD Turbo), with all of its power-saving features enabled. Optimized defaults are set in the BIOS and the memory set. The memory is manually set up to run at DDR4 3200 MHz (base spec for Zen 2) @ 16-18-18-38 primary timings.

Synthetic Benchmarks

In our synthetic set of tests, the ASRock performed as expected, winning some and losing some compared to the other boards on the charts. All results were within general run variance, outside of perhaps the MS Office scores where the ASRock was a couple of percent slower than the Gigabyte ITX board and the Asus. In general, PBO (Precision Boost Overdrive) showed negligible improvements over stock (where PBO is set to Auto, note). So it seems like ASRock and the board’s optimized defaults work well. You may be able to get more out of it making custom PBO settings.

3D Games

Our game results have continued to show minimal differences, with all results within 1%.

Timed Applications

The timed applications also show little difference between the boards in optimized default form. Enabling PBO showed no improvements.

Overall Performance

Overall performance differences between the boards we tested were not much at all. The ASRock X570 Phantom Gaming-ITX/TB3 performed as well as all the other boards. PBO yielded nothing tangible, much as we’ve seen with the competition.

Power and Relative Energy Efficiency

Idle power use for the ITX/TB3 was the lowest at 65W, even when was PBO enabled. Load wattage, alternatively, was by far the highest, hitting 211W while in optimized default mode. This tells us the AMD limits are bypassed and some enhancements seem to be built in to the board. This didn’t really play out in performance, however. Other boards accomplished the same performance using roughly 25% less power.

With that, overall efficiency on this board in default mode was almost 12% lower than the other boards. If you are trying to save power, this isn’t the board to do it, at least not without some tweaking of the settings.

Overclocking

Overclocking our Ryzen 7 3700X CPU on this board yielded a 4.25 GHz clock with 1.325V (1.35V set in the BIOS). Jumping up to the next multiplier on this same voltages ended up in a failure. More voltage ended up in throttling, while less voltage was a fail in a much quicker time. This is simply the end of the road for this processor with ambient cooling.

The VRM proved to send relatively stable voltages (according to software). When setting 1.35V in the BIOS, we ended up at 1.325V under load with LLC on auto. When using optimized defaults, it reads as level 3, but when using a fixed voltage, it automatically switched to level 1, the highest. There was still a bit of vdroop, but nothing to worry about.

For memory, the ASRock board handled manually setting our GSkill Neo sticks to DDR4 3200 CL16 as well as running the XMP settings at DDR4 3600. It also did so using the 1:1 ratio for optimal performance. We didn’t test the highest rated OC setting of 4533 MHz. But as we’ve said elsewhere, AMD says 3600 is the sweet spot. Stepping up much above that won’t gain you much in the way of substance, other than bragging rights.

Overall, the board was able to reach the same clocks on the processor as competing boards, with similar voltage.

Final Thoughts

Overall, the Mini-ITX ASRock X570 Phantom Gaming-ITX/TB3 proved to be a good board throughout our testing. In its ‘default’ state, the results blended in with the others seamlessly, as we would expect. In this stock configuration, PBO was set to auto. But when enabled, it really didn’t do much over the optimized settings. When manually overclocked, the board reached the same clock speed as the other boards without issue.

On the features front, the tiny board packed in at least one of everything found on the larger boards including four SATA ports, a single M.2 PCIe 4.0 x4 slot, and of course the USB 3.1 Gen 2 Type-C port, which doubles as a Thunderbolt 3 port with the full 40 Gbps bandwidth. The power delivery uses quality parts and kept cool while running the CPU at 4.25 GHz with all cores and threads enabled on our Ryzen 7 3700X.

If looks are a part of the equation, the simple design and RGB LEDs across the bottom allow the board to fit with any build them you like without sticking out like a sore thumb. The rear IO panel is already mounted on the board, and is also able to slide a bit for even better fit in your case, a nice value add as most are locked in place.

The ASRock X570 Phantom Gaming-ITX/TB3 is priced at $239 on Newegg, with its only competitor in this form factor being the Gigabyte X570-I Aorus Pro Wi-FI priced less at $220. The major difference between these boards is the Thunderbolt 3 capabilities of the ASRock, and some video outputs where the Gigabyte ITX board has more. Outside of that, performance between the two is too close to name a winner. But if you use any Thunderbolt 3-connected devices (or think you might in the future), this is the hands down choice for an ITX board. Just note that if you’re planning on installing a fast PCIe 4.0 SSD, the rear mounting of the M.2 slot means you’ll have to do without a fancy heatsink, which could also mean slower performance under sustained loads.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Gigabyte X570 Aorus Pro Wi-Fi Review: Well-Rounded Value

Joe Shields — Thu, 22 Aug 2019 13:00:00 +0000

Features and Specifications

The Gigabyte X570 Aorus Pro Wi-Fi is a low-to-mid-range board that packs a lot of features for its $270 / £251 price tag. (Remember that X570 boards tend to cost more than previous-generation X470 offerings, thanks in part to PCIe 4.0 support.) The Aorus Pro Wi-Fi includes dual PCIe 4.0 x4 M.2 slots, integrated rear IO, Wi-Fi 6 802.11ax integration, a robust VRM, as well as a premium Realtek ALC1220 audio codec, making it a well-rounded board for the price.

Gigabyte aims its Aorus-badged lineup at the gaming and enthusiast segment, with models usually including extras like RGB LEDs, armor on the PCIe and/or DIMM slots, ESD guards, a solid system monitoring/cooling ecosystem and generally more focus on styling. The X570 Aorus Pro Wi-Fi embodies this, while sitting in the lower end of the line’s product stack, with a couple of budget boards the only lower-priced options (we also reviewed the $200 X570 Aorus Elite) in the lineup.

Like other X570 boards, the Gigabyte X570 Aorus Pro Wi-Fi supports both Ryzen 2000 and Ryzen 3000 series processors and includes six SATA ports, a pair of PCIe 4.0 x4 M.2 slots, and four DIMM slots capable of supporting up to 128GB of DDR4 RAM with overclock speeds up to DDR4 4400 MHz. For networking and audio, we find an Intel I211-AT GbE NIC and Realtek ALC 1220 audio codec which is capable of 7.1 surround. Below is a complete list of specifications from Gigabyte’s website.

Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	12+2 phase (doubled - 6+2 phase actual)
Video Ports	HDMI 2.0
USB Ports	USB 3.1 Gen 2 (10 Gbps): 1x Type-A, 1x Type-CUSB 3.1 Gen 1 (5 Gbps): 4x Type-A USB 2.0: 4x Type-A
Network Jacks	(1) Gigabit Ethernet
Audio Jacks	(5) Analog + SPDIF
Legacy Ports/Jacks	✗
Other Ports/Jack	✗
PCIe x16	(1) v4.0
PCIe x8	(1) v4.0
PCIe x4	(1) v4.0
PCIe x1	(2) v4.0
CrossFire/SLI	AMD CrossfireX, Nvidia SLI
DIMM slots	(4) DDR4 - DDR4 4400(OC) Max
M.2 slots	(1) PCIe 4.0 x4 / SATA + PCIe(1) PCIe 4.0 x4 / SATA + PCIe
U.2 Ports	✗
SATA Ports	(6) 6Gb/s
USB Headers	(1) v3.x Gen2, (2) v3.x Gen1, (2) USB v2.0
Fan Headers	(7) 4-Pin
Legacy Interfaces	✗
Other Interfaces	FP-Audio, RGB-LED, TPM
Diagnostics Panel	✗
Internal Button/Switch	✗ / ✗
SATA Controllers	✗
Ethernet Controllers	Intel I211-AT
Wi-Fi / Bluetooth	Wi-Fi 6 - Wireless 802.11ax
USB Controllers	✗
HD Audio Codec	Realtek ALC 1220-VB
DDL/DTS Connect	✗ / Yes
Warranty	3 Years

Included accessories are minimal, as is the norm now with most budget boards. That said, most of what you need to get started is included. Here’s a list of what ships in the box, along with the board.

User’s manual / Installation guide
Support / driver DVD
2T2R Wi-Fi antenna
4x SATA cables
2x screws for M.2 slot
Aorus badge
G-Connector
4-pin RGB extension cable

In terms of style, this Aorus board has a black PCB along with black heatsinks, IO covers, and M.2 heatsinks. All the slots are black, with the two primary full-length PCIe slots and all four DIMM slots using metal reinforcement Gigabyte calls Ultra Durable Memory/PCIe Armor. There is a lined pattern running from the bottom-left corner to the upper right, with a similar design molded in the beefy aluminum IO cover.

The board’s only RGB accents are found in the IO cover as well as a line down the left side, in the audio line separating the audio bits from the rest of the board. Any other lighting will have to come from the onboard headers and RGB strips (sold separately) or your memory, video card, fans, case, and whatever else includes RGBs, which today is nearly everything.

Overall, the board will work in most build themes, as there aren’t really any obnoxious design cues that will stand out strongly. Any bright lighting will have to come from other sources as what is integrated on the board will be more for accent purposes than a bright focal point -- thank you, Gigabyte. The brushed aluminum design on the heatsink also fits the more refined aesthetic the board carries overall.

Looking closely at the top half of the board, we start off on the left with the aluminum IO cover and VRM heatsinks. The left left VRM heatsink uses a finned style, while the top uses a tacting more about mass than surface to remove the heat. This configuration makes sense considering the SOC portion, which will output less heat, is located on the top set of VRMs, while the left side is all CPU. Sending power to these are a required 8-pin and optional 4-pin EPS plug.

When analyzing the socket area, we can see a total of 14 phases for the CPU and SOC flanking the left and top of the processor. The VRM is divided into a 12+2 configuration, which is controlled by a quality Infineon IR35201 8-phase controller working in 6+2 form, with the CPU phases doubled by Infineon IR3599’s in doubler mode. In simper terms, the VRM is made from solid parts and is more than adequate for stock operation and overclocking the Zen 2 lineup.

Located across the top are three (of seven total) fan headers, with a system fan to the left of the VRM heatsink and to the right, two CPU fans headers. On the far right of the board are three more system fan headers. All fan/pump headers on the X570 Aorus Pro Wi-Fi are of the 4-pin variety and will control both DC and PWM devices using the company’s Smart Fan 5 software. Seven headers is the most I’ve seen on a board of this class.Frankly, it’s more than I’ve seen on plenty of more-expensive boards as well.

In the upper-right corner are two (of four) RGB headers with a 3-pin 5V on the left and 4-pin 12V on the right. The 3-pin supports a standard 5050 addressable LED strip with a 5A (5V) while the 4-pin supports 5050 RGB LED strips with a max of 2A (12V). The integrated RGB as well as supported devices connected to the headers are controlled by Gigabyte’s RGB Fusion 2.0 software. The integrated RGB on the top half of the board is located in the IO cover as a thin line below the Aorus branding.

Around these headers on the right side of the board is the Q-Flash button. Pressing this tells the system to boot using the specific USB port on the back for BIOS flashing without a CPU. This is a useful feature for upgrading a BIOS to a next-generation CPU, so the board is able to boot without having an older CPU handy. That said, there’s no guarantee that AMD will stick to the AM4 socket and / or make its Ryzen 4000 CPUs backwards compatible, whenever they arrive.

Moving to the bottom half of the board, we can see the audio bits, PCIe and M.2, as well as the chipset cooler and SATA ports. Starting with the audio, the Realtek ALC1220-VB chip is hidden beneath the Amp-Up Audio faraday cage, while below it in and to the right are the what the company calls high-end audio caps with the Chemicon in yellow and WIMA FKP2 capacitors.

Included is a smart headphone amp that automatically detects the impedance of your headset, setting it up properly. The VB series audio controller keeps a high signal-to-noise ratio, 110/114db(A) for the front and rear respectively, for vibrant sound through the microphone. For a product this far down the stack, it’s good to see a premium audio codec and parts used. The second RGB-lit section is found in the audio separation line between the board and audio bits, and lights up the underside of the board.

In the middle, we’re greeted by a total of three full-length PCIe slots and two M.2 ports in between. The two primary PCIe slots (those with armor) support PCIe 4.0 x16 and x8 respectively. With this comes CrossfireX and SLI support. The bottom full-length slot (without the armor) runs at PCIe 4.0 x4, with the two x1 slots rocking PCIe 4.0 x1.

Around the PCIe slots are two M.2 slots, with each having its own heatsink. Both support PCIe 4.0 x4 and SATA M.2 modules up to 110mm in length. Due to the available bandwidth on this platform, using both M.2 slots in either mode does not affect the SATA ports. One thing I would like to have seen here, since there are only two M.2 locations, is for the second slot to be moved down so it doesn’t get the full wrath of the video card’s heat output as it will in its current position with a dual slot (or greater) video card installed.

After the PCIe slots, we can see the large chipset heatsink and fan with its brushed-aluminum finish and Aorus eagle flexing proudly next to it. The fan, though smaller than the one found on the Biostar X570GT8, was only audible on initial spin up in our testing. Granted, we perhaps aren’t pushing it to its limits with multiple PCIe 4.0 M.2 devices. But in normal operations we could not hear the chipset fan. The BIOS also offers manual control over the fan as well.

Just above this is the front panel USB 3.1 Gen 2 header for fast chassis connected USB connectivity. In somewhat of a rare find in this class motherboard, we find both rear IO and front panel 3.1 Gen 2 headers. At this price point (and lower), we’ve only seen boards with one or the other.

To the right are six SATA3 6 Gbps ports which are oriented horizontally. These ports support RAID 0, 1, and RAID 10. Above these slots, just off the upper-right corner of the chipset heatsink, is the debug LED. There are four LEDs on the board for CPU, DRAM, VGA, and BOOT. The appropriateLED will stay lit during POST if there is trouble. If the motherboard doesn’t come with a two character debug LED like we saw on the Biostar X570GT8, these are the next best thing to have for figuring out what went wrong on boot. Given the general decline of the beep code speaker, some kind of visual debug indicator is a key feature to look for on any board.

Across the bottom are several headers which include the third and fourth RGB headers, front panel USB, along with more fan headers. We didn’t find anything exceptional here, but here’s a bulleted list of the other headers.

Front Panel Audio
RGB and aRGB headers
TPM header
2x USB 2.0 headers
Sys fan header
2x USB 3.0 headers
Front panel headers

Last but far from least is the rear IO. Gigabyte uses an integrated rear IO plate across most of its X570 lineup, and the Aorus Pro WI-Fi isn’t an exception. We see 10 USB ports -- 4x 2.0, 2x 3.1 USB 3.1 Gen2 Type-A and Type-C, and 4x USB 3.1 Gen1 ports -- quite a large number that should satisfy most users. Outside of the USB ports, we see the Wi-Fi antenna hookups, the HDMI 2.0 port, Intel LAN port and a 5-plug plus S/PDIF optical plug for audio.

The rear IO is fully featured with plenty of USB ports to go around. The integrated IO plate makes things a bit easier when installing the motherboard and gives it a premium appearance as well.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Software and Firmware

Gigabyte’s software is centered around its App Center application. This program is a one-stop shop for all of the Gigabyte applications, Windows settings, and other third party software. As you install Gigabyte applications such as Easy Tune, RGB Fusion 2.0, @Bios, On/Off Charge and others, they will be placed in the first screen of the app for ease of access. The App Center app sits in the tray until called upon and is a good way to keep all the motherboard-associate applications you use in a single display.

The first Gigabyte application we’ll dig our claws into is Easy Tune. This program is used to monitor the system, including temperatures, speed, and voltages, as well as overclocking. It is divided up into sections across the top for each function. These sections are Smart Boost, Advanced CPU OC, Advanced DDR OC, Advanced Power, and Hotkey. All the monitoring information sits on the bottom.

Inside the Smart Boost section, you can select two different options, “Default” and “OC.” The latter takes all cores and boosts them to 3.8 GHz. Oddly enough there are four total options, but the ECO and Auto Tuning sections can’t be selected. With a Ryzen 3000 CPU, I would simply use Precision Boost Overdrive (PBO) before using any of these profiles.

The Advanced CPU OC section is where overclocking from within Windows is accomplished. Inside are two sections, frequency and voltage, which deal with BCLK and CPU ratio along with major voltages necessary for overclocking. This includes CPU Vcore, VCORE SOC, CPU VDDP, DRAM voltage, and more. Once you have the options set, you can create profiles and save them for loading at a later point.

Next up is the Advanced DDR OC section. Here there isn’t much to do, with only two options being presented: Memory Frequency and XMP Setup Profile. The memory frequency is a simple dropdown which shows a memory multiplier to choose from. The XMP Profile dropdown lists any XMP profiles that are on your memory sticks.

When clicking on the Advanced power section, we’re greeted by additional power options, including current protection, PWM phase control, as well as Loadline calibration (LLC) control for the Vcore and SOC. After fiddling around a bit with the Vcore LLC, I found the turbo setting to keep the voltage close to where it was set. When left on auto, we saw around 0.05V vdroop from what was set in the BIOS to load in windows.

Overall, Easy Tune has come a long way from its origins so many generations ago. The software is clean and has plenty of options to push the limits in Windows on this board, though I would have liked the ability to control fans through here as well. The information Easy Tune presents is easy to read and the application is generally useful, in particular for those who like to tweak their system outside of the BIOS.

Gigabyte’s RGB control application is RGB Fusion 2. The application is a lightweight dashboard displaying the current RGB colors and schemes as well as letting you tweak them. Control includes the integrated RGB lighting on the board, RGB strips attached via the headers, as well as memory, coolers, RGB-lit video cards, and any other compatible RGB device. There are eight different preset patterns (Static, Pulse, Flash, Double Flash, Color Cycle, Music, Random and Game) with many able to be customized further (adjusting color, speed and brightness).

RGB Fusion 2 worked well controlling both the integrated RGBs and the GSkill Neo Memory we used for testing. Its interface is also easy to read, simple and gets the job done.

Firmware

Jumping into the Gigabyte BIOS, you’re first greeted by its EZ mode, which displays useful information about the system. It sports a black background with orange accent colors, letting you know it’s part of the Aorus theme.

EZ Mode displays details about the CPU and Memory frequency and voltage, CPU/VRM/chipset temperatures, BIOS version, fan speeds, and even the boot order. There are also convenient buttons on the right to access Advanced mode, Smart Fan 5, Q-Flash and Favorites. This screen is set up well with a few options to change, such as boot device order and enabling XMP. Much more than that and you will need to access Advanced mode.

Pressing F2 solves that issue, bringing us to Advanced Mode. Here you’ll find all the options you were looking for--or at least most. From overclocking to fan speed, all other settings can all be edited from the advanced BIOS. Across the top are headings for each section. Starting from the left is Favorites, Tweaker, Settings, System Info., Boot and Save & Exit.

Starting off in Tweaker, this is where all the overclocking and system performance magic happens. You’ll have access to everything needed to push Ryzen 3000 CPUs to their limits (for whatever that may be worth on these CPUs). Options such as CPU BCLK and multiplier control, XMP profile and memory timings, voltages and VRM settings are all in one place. Each part (CPU, Memory, VRM) has its own dedicated section for dealing with the details of their functions.

The Advanced Memory sub-section has enough timing and other options to make an average user’s head pop off. Primary, secondary, and tertiary timings are all listed here among a slew of other options. Inside the VRM section we find Loadline Calibration settings, VCore current protection and PWM phase control, all of which can help with running a stable overclock.

The Settings section is where to access platform power settings, IO Ports (audio, USB, LAN, SATA, etc), RGB status/settings and an even more detailed AMD Overclocking area. Some of these options are duplicated in the Tweaker section, but here one can manually adjust the Infinity Fabric frequency and dividers, along with Gear Down mode for using odd CL values for memory. The X570 Aorus Pro Wi-Fi has a lot of overclocking options to meddle with, that’s for sure.

Also within the Settings section is PC Health and Smart Fan 5. PC Health simply lists the major voltages for the CPU and DRAM along with three PSU voltages (3.3V, 5V, 12V), while Smart Fan 5 gives access to the fan control application.

The Boot Section and Save & Exit don’t have anything we haven’t seen before and is where users can change boot behavior and drive options. The latter is where to save and load any profiles in the BIOS.

Smart Fan 5 is able to control any three- or four-pin fan or pump on each of the board’s seven headers. Within these settings, you can set up fans to respond to different temperature inputs such as the CPU, PCIe, or VRM temperatures which, is a great option to have for cooling. In addition, there is an external 2-pin header for a temperature probe that can be used as well. You can select from three different profiles or create custom curves for each fan.

Smart Fan 5 is one of the more comprehensive temperature monitoring and fan control options from all of the board partners. It offers users plenty of flexibility and options to control an entire system of fans and pumps from the BIOS.

Gigabyte’s firmware has been improving in both layout and appearance over the past couple of generations. And while it was never in bad shape, what we see now in X570 is a refined layout that’s easy to use and looks good while you’re troubleshooting or tweaking. Where you expect items to be, they are there and not hidden multiple levels down.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

How We Test

We’ll be comparing the Gigabyte X570 Aorus Pro Wi-Fi to the Biostar X570GT8 we recently reviewed since it is similarly priced. We’ve also included the Asus TUF Gaming X570-Plus Wi-Fi and the Aorus X570 Elite, both of which are more bodget-focused options, priced around $200.

Comparison Products

Asus TUF Gaming X570-Plus Wi-Fi

Biostar X570GT8

Gigabyte X570 Aorus Elite

The test systems are as close as we can get to running the same specifications. Though memory may be from different brands, the speed and primary timings are the same, as well as the GPU. We use as an updated W10 64-bit OS (1903) with all threat mitigations applied.

Test System Components

Sound	Integrated HD audio
Network	Integrated gigabit networking
Graphics Driver	GeForce 413.36

Benchmark Settings

Synthetic Benchmarks and Settings
PCMark 10	Version 2.0.2115 64Essentials, Productivity, Digital Content Creation, MS Office
3DMark	Version 2.9.6631 64Firestrike Extreme and Time Spy Default Preset
Cinebench R15	Build RC184115DEMOOpenGL Benchmark - Single and Multi-threaded
Cinebench R20	Version RBBENCHMARK281795Open GL Benchmark - Single and Multi-threaded
Application Tests and Settings
LAME MP3	Version SSE2_2019Mixed 271MB WAV to mp3: Command: -b 160 --nores (160Kb/s)
HandBrake CLI	Version: 1.2.2Sintel Open Movie Project: 4.19GB 4K mkv to x264 (light AVX) and x265 (heavy AVX)
Corona 1.4	Version 1.4Custom benchmark
7-Zip	Version 19.00Integrated benchmark
Game Tests and Settings
*Ashes of the Singularity: Escalation*	Version 1.31.21360High Preset - 1920 x 1080 / 2560 x 1440Crazy Preset - 1920 x 1080 / 2560 x 1440
*F1 2017*	2017 Season, Abu Dhabi track, RainMedium PresetUltra High Preset

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark and Final Analysis

All standard benchmarks and power tests are performed using the CPU’s stock frequencies (including stock AMD Turbo), with all of its power-saving features enabled. Optimized defaults are set in the BIOS and the memory set manually to run at DDR4 3200 MHz (the base spec for Zen 2) @ 16-18-18-38 primary timings.

Synthetic Benchmarks

In our synthetic set of tests, the Gigabyte X570 Aorus Pro Wi-Fi performed well, mixing it up with the other X570 motherboards. All results were within general run variance difference with no anomalous data points. The Aous Pro Wi-Fi exeled in productivity testing, running 2% faster (which isn’t much, but that was the biggest anomaly). In general, Percision Boost Overdrive (PBO) showed some improvement across most tests, but managed to choke in productivity, running slower than stock form.

3D Games

Our game results have continued to show minimal differences. PBO didn’t do much for gaming, jut as we saw with other X570 results.

Timed Applications

The timed applications also show little difference between the boards in optimized default form. Enabling PBO showed some improvements here, performing on average a bit over 3% better than stock in these tests.

Overall Performance

Overall performance differences between the boards we tested were not much at all. The Aorus Pro Wi-Fi performed well, with marks mixing in with the X570 family we’ve tested. PBO yielded an ever so slight performance advantage overall, though the productivity result with it enabled was 2% lower -- thanks for helping, PCMark! The key here is if PBO is worth the power increase for what amounts to barely measurable performance increases overall.

Power & Relative Energy Efficiency

Idle power use for the Pro Wi-Fi was at 70W, even with PBO enabled. Previous reviews had this board at 80W, but we have since added the latest BIOS and AGESA, which helped our idle power draw . Load wattage hit 150W from the wall at stock, while with PBO we saw almost 210W.

The overall efficiency is 3.5% better than the average, but will be hardly noticeable in performance or on your electric bill. Enabling PBO kills that with a large 22% power increase for no overall performance increase in this testing.

Overclocking

Overclocking our Ryzen 7 3700X CPU on the X570 Aorus Pro Wi-Fi turned in a result of 4.216 GHz at 1.35V when using the 42.25x CPU multiplier. It reads 4.216 instead of 4.225 GHz due to the BCLK and spread spectrum floating mostly around 99.8 MHz. I tried to run 42.75 multiplier at the same voltage and it failed 24 minutes into the stress test -- so close! Adding more voltage would have pushed the temperature up well over the 90C where it peaked at the lower setting, so this was the end of the overclocking road. This result is comparable to the other X570 boards we’ve tested recently.

Voltages when overclocking were relatively stable. With LLC set to auto, we set 1.35V in the BIOS and received 1.30V when under load. Setting LLC to Turbo eliminated the vdroop, bringing the voltage to 1.356V on load (according to CPUz).

On the memory side of things, our Aorus Pro Wi-Fi with the latest BIOS (F4i dated 7/31) didn’t have any issues running 32GB at CL16. It set the 1:1 ratio as expected with this speed and setup.

In the end, the board took our CPU where the other boards did and at similar voltage levels. We think a board with a better VRM may be able to take this CPU a bit further, but have so far been thwarted in our efforts at this level. We’ll be looking at some higher-end X570 offering soon. Perhaps those will be able to push this CPU more.

Final Thoughts

Our Gigabyte X570 Aorus Pro Wi-Fi went through all of our tests without issue at stock (optimized defaults) as well using PBO. Our overclocking went without issue as well, with the board able to support our 3700X CPU just as well all the others before it, topping out at the same 42.25x multiplier.

Features wise, the Pro Wi-Fi runs the gamut for a model in this price range, including both front and rear (Type-C port) USB 3.1 Gen 2 capabilities (along with eight other USB ports), heatsinks both of the M.2 slots, Realtek ALC 1220-VB premium audio, seven fan/pump headers and a robust VRM and heatsinks, plus Wi-Fi. I would like to have seen eight SATA ports, as there are “just” two M.2 ports. But then it’s unlikely many builders will try to shove more than eight drives into a board that borders on budget territory (for X570).

The Aorus Pro Wi-Fi looks good in all black and has a tasteful implementation of RGB LEDs. If what is integrated isn’t enough, four additional RGB headers are ready for more blinking lights. And the primary PCIe slots are wrapped in Gigabyte Armor, a nice contrast against the other black parts -- so long as you can see them.

The BIOS is easy to work with and has all the options an overclocker needs to take their CPU and to its thermal limits. Our GSkill Neo memory, all 32GB at DDR4 3600, also worked without issue and is plug and play with this BIOS.

In the end, the Gigabyte X570 Aorus Pro Wi-Fi checks all the boxes for a capable motherboard, and then some for its price point. It’s one of the only boards in this class which includes both rear IO and front panel USB 3.1 Gen 2 support. So if that’s a requirement, this is the motherboard to do it. If that isn’t a requirement, there are less expensive options worth considering. But for the money, the X570 Aorus Pro Wi-Fi should be on your short list in the $250-$270 X570 price bracket.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Biostar Racing X570GT8 Motherboard Review: Affordable M.2 Excess

Joe Shields — Mon, 19 Aug 2019 13:00:00 +0000

Features and Specifications

In our recent deep-dives into a couple of the least-expensive X570 motherboards (the Asus TUF Gaming X570-Plus Wi-Fi and the Gigabyte X570 Aorus Elite), we saw good results for boards in the roughly $200 price range. But now it’s time to step up just a bit and check out the $230 Biostar X570GT8 (current UK pricing ranges from under £200 to nearly £300, likely due to stock availability issues). The Biostar GT8 includes three PCIe 4.0 M.2 slots, USB 3.1 Gen 2 Type-C port on the rear IO, RGB LEDs, and a 12-phase VRM designed to handle the latest high-end Ryzen 3000 series CPUs.

Biostar’s motherboard options are typically limited in both the Intel and AMD camps, often with only a couple of boards coming out for most of the chipsets. At the time of this writing, the X570GT8 is the only X570 board available from the company, hailing from the 4th generation Racing series line. On the older X470 chipset, the company has a total of four boards, including an Mini-ITX option. So we do expect to see other X570-based motherboards from Biostar in time.

The Biostar X570GT8’s $230 MSRP places it in the lower range of all X570 boards. We had an overall positive experience in building and testing, although our overclocking results were just a tik lower than the other X570 motherboards we looked at so far.

Performance was where we expected it to be, trading blows with other X570 boards, so no complaints there. The BIOS is a little different than the other AIBs, with the tweaking section (O.N.E) at the far right instead of the left side where we normally see it. If you are using multiple PCIe NVMe drives, the three full speed slots and heatsinks are a welcome sight.

As with other boards on this platform, the X570GT8 supports both Ryzen 2000 and Ryzen 3000 series processors. It includes six SATA ports and four DIMM slots capable of supporting up to 128GB of DDR4 RAM at rated speeds to DDR4 4000(OC). For networking and audio, we find an Intel I211AT NIC and the premium Realtek ALC1220 S1200A audio codec. Below is a complete list of specifications from Biostar.

Specifications

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	12 phase/8+4 (4+2 doubled actual)
Video Ports	HDMI 1.4bDisplayPortDVI-D
USB Ports	USB 3.1 Gen 2 (10 Gbps): 1x Type-A, 1x Type-CUSB 3.1 Gen 1 (5 Gbps): 4x Type-A
Network Jacks	(1) Gigabit Ethernet
Audio Jacks	(5) Analog + SPDIF
Legacy Ports/Jacks	✗
Other Ports/Jack	✗
PCIe x16	(1) v4.0
PCIe x8	(1) v4.0
PCIe x4	(1) v4.0
PCIe x1	(2) v4.0
CrossFire/SLI	AMD CrossfireX
DIMM slots	(4) DDR4
M.2 slots	(3) PCIe 4.0 x4 / SATA + PCIe
U.2 Ports	✗
SATA Ports	(6) 6Gb/s
USB Headers	(2) v3.x Gen1, (2) USB v2.0
Fan Headers	(5) 4-Pin
Legacy Interfaces	PS/2
Other Interfaces	FP-Audio, RGB-LED, TPM
Diagnostics Panel	Debug LED
Internal Button/Switch	Power / Reset / Reset CMOS
SATA Controllers	✗
Ethernet Controllers	Intel i211AT
Wi-Fi / Bluetooth	✗
USB Controllers	✗
HD Audio Codec	Realtek ALC1220
DDL/DTS Connect	✗ / ✗
Warranty	3 Years

The included accessories are minimal (no Biostar racing stickers?!?) but the company includes what you need to get started. Here’s a list of what ships in the box, along with the board.

User’s manual
I/O Shield
Support DVD
4x SATA cables

When looking at the X570GT8’s styling, it follows the company’s existing racing line, but with a new “lightning strikes” design. The PCB is black, with a grey design feature running throughout most of the board including on the M.2 heatsinks. The chipset fan is larger than we have seen on other boards, though the design of the heatsink itself a simple rectangle with the fan in the middle. The rear IO and audio shroud is where the integrated RGB LEDs are located.

The VRM heatsinks look like they will do the job, but are smaller than on some other less-expensive boards. On top of these are more of the same design accents we see on the bottom part of the board. All of the DIMM slots and PCIe slots are black, matching the board with the two primary PCIe slots using reinforcement.

The black and white board shouldn’t have an issue meshing with most build themes. The conservative use of RGB lighting is a plus for some. If you need more, the board also has a couple of RGB headers (moe on that later). Any RGB illumination is controlled through Biostar’s Racing GT Evo software and the Vivid LED DJ section.

Zooming in on the top half of the motherboard, there’s a fair bit to talk about. Starting on the side we see a shroud covering the rear IO bits. Uniquely, the shroud is made out of aluminum, where most are plastic. Biostar says this helps reduce EMI of the underlying parts. Also located on the shroud is the Racing branding which is illuminated from below by RGB LEDs.

We can see the dual 8-pin (required) and 4-pin (optional) EPS connectors up here, which sends power to the 12-phase VRM. This board uses an Infineon 8 phase controller running in 4+2 mode using phase doublers on the CPU side to reach 8 phases. On paper, this board shouldn’t have any issues overclocking the Ryzen 3000 CPUs. The heatsinks are capable, but note that the top middle motherboard mounting hole is covered by the heatsink. Using eight screws is plenty, but this was a design oversight.

To the right of the socket and VRM area are four DIMM slots, which use a single-sided locking mechanism to keep the memory secured. Memory support is up to 128GB across those four slots with speeds up to DDR4 4000 when overclocking. Your mileage may vary as far as how high memory can go as it depends on the sticks used as well as the quality of the IMC on the chip.

Also by the DIMM slots is one of five fan headers on the board. The second is located just above the top PCIe x1 slot. The fan headers are of the hybrid variety,supporting both PWM- and DC-controlled fans.

On the far right side of the board is the 24-pin ATX connector to feed power to the motherboard. Above that is the 2 character debug LED, helpful for troubleshooting any boot issues. This type of debug LED is gives more information about the error than the simple ‘dummy’ lights we saw on the less-expensive X570 boards. Above that are three buttons: one for power, the second for reset and the third clear the CMOS. As someone who benchmarks on an open bench table, these buttons are invaluable. For the majority who use a case with the motherboard inside, these can be convenient when troubleshooting, but aren’t otherwise likely to be used often.

Last but not least are two RGB headers in the upper-right corner. The top is a 3-pin 5V addressable header which connects up to 300 individually addressable RGB LEDs, with a maximum power rating of 3A (5V). The 12V LED connector supports 5050 RGB LED strips, also with a 3A (12V) rating. Control over the attached strips is managed by the Vivid LED DJ software.

Moving on to the bottom half of the X570GT8, the left side where the audio sits is covered with a shroud -- or as biostar calls it, “audio armor.” Inside the audio armor is the second location of on-board RGB LEDs. The white portion of the pattern is illuminated through LEDs connected to the shroud/armor. Below this is where the premium Realtek ALC1220 audio chip sits, along with what the company calls “double Hi-Fi” AMP IC for headphones. Compared to the budget X570 boards we’ve reviewed, it’s nice to see high-end audio on a motherboard again, though we do expect it at this level of board.

The PCIe area is a bit more busy here, with three full-length PCIe slots and three x1 slots. The primary slots are reinforced with Biostar’s meal “armor,” which helps prevent slot shearing or cracking under the weight of heavy cards, and can also minimize EMI. The top runs at a full PCIe 4.0 x16, while the second slot runs at a maximum of x8 mode. The last full-length slot runs at x4 (note that these speeds apply when running 3rd gen Ryzen CPUs). The three 1x slots run at x1 speeds.

Between the PCIe slots are three, yes three, M.2 slots. All of these slots are able to run PCIe 4.0 x4 speeds. PCIe M2_1 supports only PCIe M.2 modules while PCIe M2_2 and M2_3 support both PCIe and SATA drives. Slots M2_1 and M2_3 support up to 80mm modules with M2_2 supporting the larger 110mm drives. All slots are able to give the full PCIe 4.0 x4 bandwidth without losing any SATA ports. While many higher-end boards have three M.2 slots, not all of them come with heatsinks as these do, and it’s a welcome feature aesthetically, as well as providing some welcome cooling for hot-running NVMe based drives.

Moving to the right, we then see the chipset heatsink and fan. On the other X570 boards I’ve tested to date, the fan is quite small. Here, the fan is a bit bigger and also completely open, exposing the whole fan. There are fins on the top and bottom of the heatsink for more surface area. This setup isn’t the most appealing to the eye, but does the job and does so quietly.

To the right of the heatsink area are six SATA3 ports. The chipset supports eight total. But because of the three M.2 slots, two were taken away. This prevents any necessary sharing of bandwidth. I like this setup as these days M.2 drives, be it SATA or PCIe NVMe based, are becoming more common, making the six SATA ports here more than adequate for most builds.

Something also worth noting is the LN2 switch found near the bottom-right corner of the chipset heatsink. When enabled, this will force the CPU to run at 800 MHz, which the manual says is to avoid unexpected system shutdown. While this is a cool feature on a lower-cost board such as this, this board isn’t likely to be the weapon of choice for sub-ambient overclocking and really pushing limits.

On the very bottom edge of the board are several different headers and buttons including USB, fan, CMOS jumper and more. There isn’t anything exceptional to share here, but we list them all below.

Front Panel Audio
2x Fan headers
CMOS jumper
Dual BIOS switch
2x USB 2.0 headers
USB 3.1 header
USB 3.2 header (fast charge)
Front panel header
Front panel header
Clear CMOS jumper

Moving on to the rear IO area, one of the first things I noticed is the Biostar X570GT8 does not include an integrated IO plate. We’ve seen Gigabyte boards step up and add these, even in one of its lowest priced boards. That said, the IO plate included in the box is black with the “racing” name on it, and it looks good when in place.

Ports on the rear IO include video outputs, USB, network, and the audio stack. Surprisingly, we see three different video outputs here, DVI-D, DisplayPort and HDMI. These are used only if an APU (like the Ryzen 5 3400G is in the socket). There are a total of four USB 3.1 Gen 1 (5 Gbps) Type-A ports and two USB 3.1 Gen 2 ports -- one of the latter is Type-A and the other Type-C. We can also see the Intel LAN port as well as a legacy PS/2 port back here. The audio stack contains five 7mm plugs and an S/PDIF plug as well.

I like the 10 Gbps Type-C port out back, but would like to see more USB ports in general. The three video ports take up lots of space, especially given that they’re only ever going to be used by a subset of builders, who could probably get by with one or two video connectors anyway.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Software and Firmware

On the software side of things, Biostar uses a similar one-stop shop app as its competitors with its Racing GT Evo program. This application provides users with system information including clock, motherboard, memory, and processor details, access to system volume, preset performance profiles, RGB LED and fan control, along with a hardware monitor and overclocking capabilities. Outside of that the company offers a Lightning charger utility for fast charging devices, as well as an e-hotline utility designed to quickly send information to Biostar support for troubleshooting.

We’ll start off with the RGB control section in GT Evo, called Vivid LED DJ. As the name implies, it controls the integrated LEDs, as well as any compatible strips or other RGB items plugged into the board. There are options for color control, on/off as well as four presets (permanent, shine, breathe, and sparkle).

A.I. Fan is where users are able to control any attached fan or pump speed. The section displays CPU and system temperatures as well as fan speeds. Users are able to select either DC or PWM control or can leave it on auto. There are three fan speed presets: aggressive, quiet, full on, and then a manual option where you set the custom curves. The A.I. Fan section worked without issue, though it didn’t contain advanced functionality such as the ability to select different temperature sources or hysteresis.

The Hardware Monitor portion displays information about CPU and system temperatures, along with fan speeds and voltages of both the system and power supply.

In the overclocking and overvolting section within GT Evo, users are able to adjust the major voltages, including CPU Core and CPU SOC, DDR, DDR VPP, VDDP Run voltages, as well as the chipset. It provides plenty of voltage options, but the good news stops there.

For CPU overclocking options, oddly enough, there are none here. It lists the CPU and memory speeds along with the BCLK and CPU ratio limit, but none can actually be adjusted. You aren’t able to actually adjust anything related to clock speeds here, which is quite unusual. It makes me wonder even more why the company added an LN2 switch, despite not not providing the ability to overclock within windows -- it feels like an oversight.

Outside of not being able to overclock, the software worked well, displaying relevant information as well as controlling the fans and RGB LED illumination.

Firmware

When accessing Biostar’s BIOS, you’re greeted with a familiar setup of headings listed across the top and monitoring information on the left side. The firmware uses a grey background with red highlights, matching the GT Evo windows software and “racing” theme of the line. It isn’t the best looking-UEFI we’ve seen, but will most certainly do the job.

The BIOS does not have a simplified “easy mode,” so what you see is what you get. On the left side is a system summary, including CPU and RAM speed along with listing their current voltage. It also displays the CPU temperature and system date and time. In the middle is where the different sections are located with a legend on the right.

The first section we see is Main, which is mostly informational, displaying information about the BIOS, total installed memory, and the date and time. Pretty standard stuff.

Our next section to the right is Advanced. Inside this section is where you control things like SATA, CPU, USB, CSM, and NVMe configurations. Also located here are ACPI settings, a hardware monitor, PCI subsystem settings and AMD CBS. Anything needed to configure onboard items is found here.

Inside the Chipset section we are able to see information about the south bridge and north bridge, as well as enabling or disabling the Intel PCIe NIC.

We’ll skip over the Boot and Security sections as those are self explanatory and don’t have anything worth noting.

The last section is named O.N.E. Here is where you find all of the options needed to overclock and tweak the CPU and memory. On the primary screen, we’re presented with BCLK and FCLK frequency, CPU ratio, Core and SOC voltages, Load Line Calibration and other secondary options. You’ll generally find what’s needed here, but not much more.

It’s a basic setup that could (and probably should) be refined both for appearance and organization, but most users won’t have any issues after looking around a bit. For example, inside the DRAM Timing Configuration sub-heading, there are a ton of memory timings, but it’s just one big list. I’d prefer these split to primary/secondary/tertiary sections, if only to break it up a bit.

Another minor quibble is the transparency of dialog boxes that pop up in the bios. It becomes confusing if you are enabling / disabling something and you see the words enable and disable on the background. These do not need to be transparent. Overall though, the BIOS got the job done, just not with the same slickness we’ve seen from other board partners.

Unfortunately this BIOS isn’t able to capture images when inside the fan section (press F5). That said, it looks no different than the A.I. Fan software and functions exactly the same. The same also goes for the Vivid LED DJ section which, like A.I. Fan, looks and functions the same in the BIOS but doesn’t allow for capturing images.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

How We Test

We’ll be comparing the Biostar X570GT8 to the Gigabyte X570 Aorus Pro Wi-Fi, which is priced a bit higher at $270, as well as the lower-priced Gigabyte X570 Aorus Elite and Asus TUF X570-Plus Wi-Fi.

Comparison Products

Asus TUF Gaming X570-Plus Wi-Fi

Gigabyte X570 Aorus Elite

Gigabyte X570 Aorus Pro Wi-Fi

The test systems are as close as we can get to running the same specifications. Though memory may be different brands, the speed and primary timings are the same, as well as the GPU. We use as an updated W10 64-bit OS (1903) with all threat mitigations applied.

Test System Components

Sound	Integrated HD audio
Network	Integrated gigabit networking
Graphics Driver	GeForce 413.36

Benchmark Settings

Synthetic Benchmarks and Settings
PCMark 10	Version 2.0.2115 64Essentials, Productivity, Digital Content Creation, MS Office
3DMark	Version 2.9.6631 64Firestrike Extreme and Time Spy Default Preset
Cinebench R15	Build RC184115DEMOOpenGL Benchmark - Single and Multi-threaded
Cinebench R20	Version RBBENCHMARK281795Open GL Benchmark - Single and Multi-threaded
Application Tests and Settings
LAME MP3	Version SSE2_2019Mixed 271MB WAV to mp3: Command: -b 160 --nores (160Kb/s)
HandBrake CLI	Version: 1.2.2Sintel Open Movie Project: 4.19GB 4K mkv to x264 (light AVX) and x265 (heavy AVX)
Corona 1.4	Version 1.4Custom benchmark
7-Zip	Version 19.00Integrated benchmark
Game Tests and Settings
*Ashes of the Singularity: Escalation*	Version 1.31.21360High Preset - 1920 x 1080 / 2560 x 1440Crazy Preset - 1920 x 1080 / 2560 x 1440
*F1 2017*	2017 Season, Abu Dhabi track, RainMedium PresetUltra High Preset

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark and Final Analysis

All standard benchmarks and power tests are performed using the CPU’s stock frequencies (including stock AMD Turbo), with all of its power-saving features enabled. Optimized defaults are set in the BIOS and the memory set. The memory is manually set up to run at DDR4 3200 MHz (base spec for Zen 2) @ 16-18-18-38 primary timings.

Synthetic Benchmarks

In our synthetic set of tests, the Biostar X570GT8’s results were right in line with the other X570 motherboards. All results were within general run variance difference with no anomalous data points. We didn’t test PBO separately here, as this board appears to have PB enabled by default.

3D Games

Game results continue to show a very tight set of results without any appreciable differences with the Biostar right in the middle of our data points. Nothing to worry about here.

Timed Applications

TIMED APPS ALBUM(image009 and 011)

Our timed applications also show little difference between the boards. In this case, the Biostar seemed to be just a hair slower in Corona and Handbrake, by a couple of percent.

Overall Performance

Overall, the Biostar X570GT8 performed well across the board. It was only in the timed application benchmarks where it showed almost a 2% difference. Users would be hard-pressed to notice such a small difference, but it is measurable.

Power and Relative Energy Efficiency

For power use, our Biostar used the most power under load, hitting 153W (3W more than the next highest), but showed decent idle power consumption (note this is still with the older chipset drivers -- some improvement is said to come with the latest that was released the day after I finished this review. According to our results, the X570GT8 was 3.2% less efficient than the other boards/datasets when taking performance into consideration. But that’s still a fairly minor difference.

Overclocking

Overclocking on the X570GT8 gave us a flat 4.0 GHz overclock with 1.29V on the core. That speed is less compared to both of the other boards by that .25 multiplier. No matter what voltage I used, I was not able to stabilize (get through a 30 min AIDA run) at higher speeds. Even with the better cooler and lower temperatures.

We successfully loaded up our GSKill Trident Z Neo 4x8GB DDR4 3600 16-16-16-36 sticks without issue here as well. What’s interesting is the motherboard set it to 1:2 ratio at this clock speed, which is lower than AMD specifies should be a 1:1 ratio. That said, switching the FCLK to 1800 MHz getting back to the 1:1 ratio proved to be stable. So it just took a little manual fiddling it to get there. At times we’ve seen some setups drop to 1:2 for stability and compatibility purposes, which is likely what happened here.

Overall, the board clocked well, though it could not reach quite the same level as the other boards tested recently. Even when using the same voltage or more than the other boards used, the Biostart just wouldn’t stabilize and errored out in testing. Perhaps a BIOS update will improve this result.

Final Thoughts

The Biostar X570GT8 ($230 MSRP) went through all of our testing and showed that it can hang with the other X570 boards I have reviewed so far. On the features side, we like the inclusion of three M.2 slots, but the icing on the cake on that front is that they all have heatsinks, which is something you don’t typically find in this price range. Due to the number of M.2 slots, Biostar chose to run with six SATA3 / 6 Gbps ports, avoiding any lane sharing if all three M.2 slots or all the SATA ports are populated. The board has a USB 3.1 Gen 2 Type-C port on the back as well, which is hit or miss in this price range.

Our overclocking adventure proved a bit disappointing, as we were not able to reach the 4.24 GHz here, which we saw on competing models. We were, however, able to set our 32GB DDR4 3600 memory kit to its XMP settings, but the board dropped the ratio to 1:2 by default. This wasn’t a big deal though, as all it takes is setting the FCLK to 1800 Mhz to match and get back to 1:1. Perhaps with further BIOS refinement we will see improvements on the overclocking front. The transparency issue in the BIOS making things a bit hard to discern was a bit confusing at first, as was the memory ratio dropping earlier than expected. But once we got used to how this board rolls, we were able to do most of what we expected with relative ease.

Overall, the Biostar X570GT8 shows promise and is a solid choice for an entry-level board, with a little extra. All the basic needs are met and it excels at M.2 storage, although Wi-Fi isn’t included. So if you need that feature at around this price point or a little less, consider the Asus TUF X570-Plus Wi-Fi instead. Outside of that, it’s tough to pin down a winner between these three budget boards as they all have their positives and negative points. But if you are looking for a board that has three heatsinked M.2 slots at a very reasonable price, the Biostar X570GT8 is easy to recommend.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Caseking Is Now Selling Binned Ryzen 3000-Series Matisse CPUs

Zhiye Liu — Sun, 11 Aug 2019 18:16:01 +0000

German computer hardware retailer Caseking has commenced selling pre-overclocked Ryzen 9 3900X, Ryzen 7 3700X and Ryzen 5 3600 processors for a small premium.

(Image credit: AMD)

AMD has done an excellent job of binning its Ryzen 3000-series, codenamed Matisse, parts to a point where there is little to no headroom left for manual overclocking. This has paved the way for companies, such as Silicon Lottery to sell overclocked Matisse chips for consumers that aren't fond of playing the silicon lottery. Caseking is the latest retailer to jump on the trend.

The pricing in the table was taken from the Caseking online store. Computer hardware over in Europe is subjected to value-added tax (VAT) and therefore is significantly more pricey. The standard VAT rate in Germany is 19%.

	Cores / Threads	Base Clock	All-Core Boost Clock	L3 Cache	TDP	Price (Euros)	Price (USD)
Ryzen 9 3900X @ 4.3 GHz	12 / 24	3.8 GHz	4.3 GHz	64MB	105W	€619	$700
Ryzen 9 3900X @ 4.25 GHz	12 / 24	3.8 GHz	4.25 GHz	64MB	105W	€599	$677
Ryzen 9 3900X @ 4.2 GHz	12 / 24	3.8 GHz	4.2 GHz	64MB	105W	€579	$655
Ryzen 9 3900X	12 / 24	3.8 GHz	?	64MB	105W	€529	$598
Ryzen 7 3700X @ 4.3 GHz	8 / 16	3.6 GHz	4.3 GHz	32MB	65W	€449	$507
Ryzen 7 3700X @ 4.25 GHz	8 / 16	3.6 GHz	4.25 GHz	32MB	65W	€429	$485
Ryzen 7 3700X @ 4.2 GHz	8 / 16	3.6 GHz	4.2 GHz	32MB	65W	€399	$451
Ryzen 7 3700X	8 / 16	3.6 GHz	?	32MB	65W	€349	$394
Ryzen 5 3600 @ 4.3 GHz	6 / 12	3.6 GHz	4.3 GHz	32MB	65W	€299	$338
Ryzen 5 3600 @ 4.25 GHz	6 / 12	3.6 GHz	4.25 GHz	32MB	65W	€279	$315
Ryzen 5 3600 @ 4.2 GHz	6 / 12	3.6 GHz	4.2 GHz	32MB	65W	€259	$292
Ryzen 5 3600	6 / 12	3.6 GHz	?	32MB	65W	€209	$236

Caseking is primarily offering overclocked versions of the Ryzen 9 3900X, Ryzen 7 3700X and Ryzen 5 3600 at 4.3 GHz, 4.25 GHz and 4.2 GHz. The Vcore for the overclocked chips is kept under 1.4V, but you can expect a variation of 30mV depending on the quality of your motherboard's power delivery subsystem.

Caseking's own King Mod team and overclocking guru Roman "der8auer" Hartung binned and tested each chip's stability with the Prime95 26.6 software with a FFT length of 1344 for at least one hour. Caseking urges its customers to pair the overclocked Matisse parts with a capable AMD X570-based motherboard. Although the stock Wraith Stealth CPU cooler is included, it's recommended you put the processor under water with a 280mm closed-loop liquid cooler as a minimum.

In general, the binned processors cost between 50 euros to 100 euros more expensive over the standard models. Caseking backs its overclocked parts with a limited two-year warranty.

Asus ROG Strix X570-E Gaming Review: More Fast USB, Lower Price

Thomas Soderstrom — Thu, 25 Jul 2019 13:00:00 +0000

Who needs eight 10Gbps USB ports on the I/O panel? With all of the X570 platform’s USB 3.x ports offering that bandwidth, a better question might be why Asus’s competitors (specifically the MSI MEG X570 Ace, Gigabyte X570 Aorus Master and ASRock X570 Taichi) are substituting some of those with 5Gbps ports. But who would be willing to give up one of the competitor’s three M.2 slots for four SATA ports? If that sounds like you, the ROG Strix X570-E Gaming ($330 / £326) beckons. With these features nailed down, the only remaining question is why Asus labels this board “gaming” rather than “pro.”

We've tested several X570 boards, including some models refreshed for AMD's new Ryzen 5000 CPUs but only a handful of models stand out enough to rank among our Best Motherboads list.

Visit our motherboard basics and motherboard buying guide to help you narrow down your board buying options.

Asus ROG Strix X570-E Gaming Specs

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	16 Phases
Video Ports	DisplayPort, HDMI
USB Ports	10Gbps: (7) Type-C, (1) Type A
Network Jacks	2.5GbE, Gigabit Ethernet, (2) Wi-Fi Antenna
Audio Jacks	(5) Analog, (1) Digital Out
Legacy Ports/Jacks	✗
Other Ports/Jack	BIOS Flashback Button
PCIe x16	(3) v4.0 (x16/x0/x4, x8/x8/x4)(*x2 mode when 2nd PCIe x1 is filled)
PCIe x8	✗
PCIe x4	✗
PCIe x1	(2) v4.0 (2nd shared with PCIe x16-3)
CrossFire/SLI	3x / 2x
DIMM slots	(4) DDR4
M.2 slots	(2) PCIe 4.0 x4 / SATA
U.2 Ports	✗
SATA Ports	(8) 6Gb/s
USB Headers	(1) v3.x Gen2, (1) v3.x Gen1, (2) v2.0, (1) AMD fan LED
Fan Headers	(7) 4-Pin
Legacy Interfaces	System (Beep-code) Speaker
Other Interfaces	FP-Audio, Asus NODE, Thermistor, (2) RGB LED, (2) ARGB LED
Diagnostics Panel	Numeric
Internal Button/Switch	✗
SATA Controllers	Integrated (0/1/10)
Ethernet Controllers	RTL8125AG PCIe, WGI211AT PCIe
Wi-Fi / Bluetooth	Intel AX200 802.11ax (2.4 Gb/s) / BT 5.0 Combo
USB Controllers	✗
HD Audio Codec	ALC1220
DDL/DTS Connect	✗
Warranty	3 Years

Asus ROG Strix X570-E Gaming Features

Motherboard designers typically go for obvious choices: When AMD announced that its latest platform would support one NVMe M.2 drive from the CPU and up to 16 high-speed connections from the X570 PCH, it was obvious that most manufacturers would deploy twelve of those PCH lanes as a second and third M.2 interface plus a PCIe x4 slot. Those designers were then left to figure out whether to use those final four lanes for SATA, USB3 or additional PCIe. And that’s where lane sharing that disables one interface to enable another begins. Asus took a different track in its ROG Strix X570-E Gaming: It has only two M.2 slots total.

The Strix X570-E Gaming also has eight SATA ports, whereas some competing models have shaved those down to four so that the other four lanes could be used for PCIe (typically a third M.2 slot). And just when you thought you’d at least get four lanes to the third x16-length PCIe slot, you realize that it gets kicked down to x2 mode whenever the second x1 slot is used. Most people won’t use the second x1 slot because of its location, but that notion makes us question why it’s even included on a gaming-focused motherboard.

Asus’s efforts appear more earnest on the I/O panel, where we find eight USB3 Gen2 ports. Gen1 ports wouldn’t make sense here from a chipset perspective, since the platform’s USB3 ports are all Gen2 compliant, yet several of Asus’ competitors have chosen to limit their I/O anyway. We’re happy to see Asus take the high road here, though we’d have still liked to see a pair of USB 2.0 ports for a keyboard and mouse -- connecting those to USB3 is a waste of the platform’s resources.

USB support is the big differentiator here, since Asus uses the same Realtek 2.5Gbps/Intel Gigabit Ethernet/802.11ax controller combo as similarly-priced boards from Gigabyte and MSI, but there are smaller differences such as the inclusion of DisplayPort and HDMI and the exclusion of a CLR_CMOS button on this Asus board, along with four more SATA ports and one less M.2 slot than those two competitors.

Perhaps it’s the association between gaming and overclocking that earns the Strix X570-E Gaming its name. From above we see sixteen chokes that are each tied to a 50A MOSFET in a 12+4 arrangement, meaning that users could push up to 600A of current to the CPU core. We also see three 4-pin fan headers at the top edge, three at the bottom edge, and one forward of the I/O panel’s audio jacks to help those who build for overclocking to keep everything cool. And let’s not forget the two RGB and two ARGB headers, repeated at the top and bottom of the board, that could be used to control fan lighting (in addition to RGB strips, of course).

Looking at the Strix X570-E Gaming’s lower half, we see that the PCH cover is mesh and secured with two screws. Unfortunately, that cover must be removed to access the forward screws of the two M.2-drive heat spreaders. Anyone who doesn’t need those heat spreaders can ease M.2 access by leaving them off, which then makes removing the PCH fan cover unnecessary.

Front-panel audio, Asus Node, thermistor, two USB 2.0 and one USB3 Gen1 dual-port, three fan, RGB ARGB, Intel-style front-panel button/switch, and a beep-code speaker header line the Strix X570-E Gaming’s bottom edge, while the single-port USB3 Gen2 front-panel header sits halfway up its front edge. Also found on the bottom edge is a two-digit status code display.

The Strix X570-E Gaming includes a multi-language user manual, driver and application disc, four SATA cables, a thermistor lead, and RGB and ARGB extension cables. Also included is a thank-you card, a Cablemod coupon, an ROG sticker sheet, several cable ties, a 2T2R Wi-Fi antenna, and a hanging doorknob card.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Firmware And Overclocking

Manual overclocking is achieved through the Ai Tweaker menu of the Strix X570-E Gaming’s Advanced mode GUI. Choosing D.O.C.P as the overclocking mode allows the board to select memory frequency and timings based on the module’s XMP programming prior to manual tuning.

Our Ryzen 7 3700X reached 4.20 GHz at 1.36875V and pushed our four Kingston/Hynix DDR4-2933 modules to DDR4-3733 at 1.353V, that last voltage measured at the slot and coming from the board’s 1.340V setting. Dropping to two modules allowed the same DIMMs to scale up to DDR4-4200.

We got to those high data rates by manually configuring 20-21-21-21-42 primary timings, which were chosen long ago based on the notion that we wanted to hit DDR4-4200 at a reasonably-quick one-latency cycle for every 200 MHz data rate.

The Digi+ VRM menu provides the CPU Load Line Calibration setting we needed to get our memory to stay near our 1.366V target at full CPU load. Its Level 5 setting perfectly matched our needs.

Software is required to control the Strix X570-E Gaming’s RGB lighting and headers, though users can turn all the lights off from the Onboard Devices Configuration submenu of the Advanced menu.

All seven of the Strix X570-E Gaming’s fan headers can be switched between PWM and voltage-based RPM control, and each can be set to a factory-programmed profile or manually configured. Asus’ Qfan Tuning adjusts the board’s programmed profiles to match the limits of each fan.

The Strix X570-E Gaming’s Tool menu includes a shortcut to an integrated firmware-flashing utility, an SSD erase tool, eight registers to store customized firmware settings and an import/export function to store and retrieve these on a USB flash drive.

Asus offers and EZ Mode interface to users who get lost in all the options of Advanced Mode. Toggling between GUIs is as easy as pressing F7 at the top of a keyboard.

Overclocking

We’re including all formerly-tested X570 motherboards, along with the X470 we started with, in our Strix X570-E Gaming evaluation.

Asus ROG Strix X570-E Gaming

ASRock X570 Taichi

Gigabyte X570 Aorus Master

Even the cheaper X570 Taichi—which still costs $300—has a range of CPU core voltage levels that far exceed the levels coolable with water, and that sets us up with a great way to compare hardware capability to motherboard stability.

Three boards reached our CPU’s liquid-cooled limit of 4.20 GHz, including the Strix X570-E Gaming. The Asus board took second place in memory overclocking with two modules installed, but it tied ASRock for last place when all four modules were in place.

Performance is the point of overclocking, and with memory being the only thing our Ryzen 7 3700X can overclock well, bandwidth shows that ASRock got the most punch for its data rate. Asus’s DDR4-3733 setting appears to be far less aggressive than ASRock’s, resulting in a 2.5% bandwidth deficit. Since each board adjusts its advanced timings automatically to provide stability when exceeding the memory’s XMP values, we assume that starting out with a DDR4-3733 kit would have given us different results.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark Results and Final Analysis

3DMark and PCMark

The Strix X570-E Gaming falls behind in the Physics score of Firstrike Extreme, but produces par performance in nearly every other test. Let’s see if that single difference is reflected at all in games.

3D Games

The Strix X570-E Gaming comes up in line with the competition again in our CPU and DRAM bottlenecked gaming titles. Perhaps we’ll find a difference in encoding applications?

Mixed Apps

We’ve seen enough competitive results from the Strix X570-E Gaming to dismiss its loss in only one synthetic benchmark as a likely hiccup within the benchmark itself. Will it stand out better in efficiency?

Power, Heat And Efficiency

The Strix X570-E Gaming scores here as the second-most power-hungry board, and a look back at our test notes reveals that it ran between the Taichi’s 4.1 GHz and the Aorus Master’s 3.9 GHz, and at 3.95 to 3.975 GHz, in Prime95. We’re not sure why it didn’t idle down to a lower number, though.

The Asus board had the second-highest full-load frequency and the second-highest full-load power consumption, and it also produced the second-highest thermal measurements. Concerning the voltage regulator, the results shown are from an infrared scanner that reported the highest temperature at the chokes: The Strix X570-E Gaming’s software reported the lowest MOSFET temperature at 10° over ambient, for what that’s worth.

Differences of less than half a percent are hard to track in individual benchmarks, but the average of these put the ROG Strix X570-E Gaming in second place to the X570 Taichi and farther ahead of upmarket models from Gigabyte and MSI. That small boost in overall performance loosens up the efficiency deficit of its relatively high energy use, so that it finishes between the Taichi and Aorus Master overall.

Final Thoughts

As the second-cheapest board in our lineup, the ROG Strix X570-E Gaming produces the second-greatest performance per dollar. With its 2.5GbE secondary Ethernet controller, WiFi 6 controller and bundled remote thermistor, it’s far closer to the X570 Aorus Master in features than to the X570 Taichi, and it beats all comers when it comes to USB3 Gen2 port count.

The Strix X570-E Gaming splits the difference in price between the Taichi and the Aorus Master, taking the trophy in features for the money. This, despite its lack of a third M.2 slot, since the Strix board focuses instead on having eight SATA ports. While it may be difficult for some of us to fathom substituting four SATA ports for a third NVMe interface, we’re sure that someone out there plans to build with more than four SATA, and no more than two M.2, drives.

That ideal buyer sounds more like power user than a gamer. But the marketing aim being a bit off doesn’t detract from this board’s features and abilities. The ROG Strix X570-E Gaming offers an advantage over competing X570 boards in features-per-dollar, making it easy to recommend, unless of course you need to install a trio of M.2 SSDs without the use of an expansion card.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

MSI MEG X570 Ace Review: Memory Speed Master?

Thomas Soderstrom — Fri, 19 Jul 2019 13:00:00 +0000

Specifications and Design

MSI’s MEG X570 Ace launched at $370 (and £360 in the UK), but it’s been tough to find in stock in the US in these early days after the Ryzen 3000 launch. But if you do manage to find it in stock and snatch one up, you’ll be rewarded with an overload of features, a large CPU voltage regulator, solid overclocking and a bunch of onboard RGB lighting and various cable headers.

MSI MEG X570 ACE Specs

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	14 Phases
Video Ports	✗
USB Ports	10Gbps: (1) Type-C, (3) Type A5Gb/s: (2) Type A; (2) USB 2.0
Network Jacks	2.5GbE, Gigabit Ethernet, (2) Wi-Fi Antenna
Audio Jacks	(5) Analog, (1) Digital Out
Legacy Ports/Jacks	(1) PS/2
Other Ports/Jack	BIOS Flash, CLR_CMOS Buttons
PCIe x16	(3) v4.0 (x16/x0/x4, x8/x8/x4)
PCIe x8	✗
PCIe x4	✗
PCIe x1	(2) v4.0 [1-active (shared)]
CrossFire/SLI	3x / 2x
DIMM slots	(4) DDR4
M.2 slots	(1) PCIe 4.0 x4, (2) PCIe 4.0 x4 / SATA
U.2 Ports	✗
SATA Ports	(4) 6Gb/s
USB Headers	(1) v3.x Gen2, (2) v3.x Gen1, (2) v2.0,
Fan Headers	(7) 4-Pin
Legacy Interfaces	System (Beep-code) Speaker
Other Interfaces	FP-Audio, TPM, (2) ARGB LED, Corsair LED, RGB LED
Diagnostics Panel	Numeric
Internal Button/Switch	Power, Reset, OC / ✗
SATA Controllers	Integrated (0/1/10)
Ethernet Controllers	RTL8125AG PCIe, WGI211AT PCIe
Wi-Fi / Bluetooth	Intel AX200 802.11ax (2.4 Gb/s) / BT 5.0 Combo
USB Controllers	✗
HD Audio Codec	ALC1220
DDL/DTS Connect	✗
Warranty	3 Years

In a market where $300-plus has become the entry point for enthusiast-class products, MSI’s MEG X570 Ace needs only outdo Gigabyte’s recently-reviewed X570 Aorus Master by a mere $10 in value to score a victory--at least in the US. Prices are flipped in U.K., where the MSI board is £20 cheaper than Gigabyte’s entry. But when everyone is pushing the same basic hardware in slightly different packaging, how does a brand or board stand apart?

The similarities between these early X570 boards are plentiful, from the triple M.2 slots to the 2.5GbE/Gigabit Ethernet combo, to the Intel WiFi 6 adapter and even the three metal-reinforced x16-length PCIe 4.0 slots that, in both cases, automatically switch from x16/x0/x4 to x8/x8/x4 modes when a card is detected in the center slot. And while the MEG X570 Ace has only four SATA ports, its Gigabyte competitor only has four active SATA ports when its third M.2 slot is filled. Heck, both boards even have a pair of buttons on the I/O panel to clear firmware settings and initiate flash mode.

The MEG X570 Ace has the same four USB3 Gen2 ports and two USB3 Gen1 ports on the I/O panel and the same selection of five analog audio jacks with one optical S/PDIF output as its Gigabyte competition, but the boards diverge in how they treat your legacy peripherals: MSI adds a PS/2 port to its pair of USB 2.0 jacks, whereas Gigabyte offered four USB 2.0 jacks. While people who do everything including printing and scanning might prefer the extra USB, those with a legacy keyboard or mouse will likely prefer the PS/2, leaving us no way to differentiate value here.

The 14 chokes that surround the CPU socket lead to 14 60A MOSFETs, 12 of which feed the CPU core: While this is technically better than the 50A MOSFETs on the competing board, we doubt users will actually be able to differentiate between the MEG X570 Ace’s 720 possible amperes and its competitor’s 600A. Those MOSFETs are cooled with a pair of machined-aluminum sinks rather than the competitor’s stacked-fin design, but using oversized electrical components assures that the voltage regulator will always be at a lower percentage of its capacity.

Perhaps that’s why MSI is also the first brand we’ve seen to connect its PCH heatsink to the voltage regulator via a heat pipe: As the lowest component on the chain, the PCH should receive the best cooling and may not even need its fan if the board is oriented upright in a traditional tower case.

Two of the MEG X570 Ace’s seven four-pin fan headers are found on the bottom edge, with one of the two ARGB cable and front-panel audio headers to the left, with two USB 2.0, USB3 Gen1, and USB3 Gen2 headers to the right. The second ARGB header is found in the front corner of the bottom edge by jumping past the Power/Reset buttons and the OC button that can select between eight Ryzen overclocking profiles.

Moving up that front edge, we find a legacy beep-code speaker and Intel-style button/LED headers, a two-digit status code display, the previously mentioned four SATA ports, and the board’s other USB3 Gen1 front-panel header.

Those USB3 ports on the bottom edge are the toughest problems we see with this layout, as both Gen1 and Gen2 cables are too stiff to tuck under the heatsink of a graphics card. Then again, we wouldn’t likely build with a third high-end card in the bottom x16-length slot, but would more likely put a storage adapter or NVMe drive there. And speaking of slots, this is where we find the board’s final hurdle: Both of its PCIe 4.0 x1 slots share a single lane, so that only one can be used--compared to the Gigabyte X570 Aorus Master, which only has one PCIe 4.0 x1 slot. At least here you have x1 card placement options.

The MEG X570 Ace’s box includes four SATA cables, an RGB LED splitter cable, Corsair RGB and ARGB extension cables, a Corsair RGB header to ARGB adapter cable, a 2T2R Wi-Fi antenna, M.2 screws, user manual and quick start guide, a sticker pack and a driver/application disc.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Firmware and Overclocking

MSI Click BIOS 5 remembers the user’s chosen interface version (EZ or Advanced mode) upon exit, so that tuners can more-quickly pick up where they left off. We left off at 4.20 GHz, unable to get our CPU to go any higher at up to 1.40V and finally backing down to 1.366V under heavy software load when higher settings proved unfruitful.

Our Hynix-based HyperX DDR4-2933 reached an alarming DDR4-4333 at full stability using the board’s 1.330V setting, which corresponded to a measured 1.354V at the DIMM slots. That’s a full 24mV over-voltage, which is why we’re forced to get out the meter in the first place, and it’s also why we’ve picked a DRAM voltage limit (1.355V) to prevent cheating in these comparisons.

Our memory overclock came at 20-21-21-21-42 timings, as switching to straight CAS 21 settings didn’t get give us an additional stability. CAS 21 straight timings were originally picked in hopes of pushing these modules to DDR4-4200, and 4333 certainly beats that. On the other hand, that achievement happened with only two DIMMs installed, and the full four-DIMM kit reached a mere DDR4-4000.

Two ways we found to get our core voltage to its optimally-stable 1.366V under heavy load were to start with 1.375V and select Mode 3 load line calibration, or to choose 1.3625V as the base and Mode 2 as the calibration level. Since the 1.375V gave us 1.384V at idle and the 1.3625 gave use 1.372V at idle, the latter option appears to be better.

Other OC menu items include CPU specifications and DRAM timings reports, and advanced CPU features settings that we didn’t need to touch to reach our overclock.

MSI’s M-Flash firmware update utility can be launched from within firmware, though it opens a separate GUI.

Up to six custom firmware configurations can be stored as user profiles on what space remains of the onboard flash ROM, and those profiles can also be exported or imported from a USB flash drive.

MSI’s Hardware Monitor menu is primarily a fan RPM mapping page, where users can select either PWM- or voltage-based control methods for each of the motherboard’s seven headers and assign custom curves or slopes to deal with various temperature readings.

MSI Board Explorer shows what’s connected to each slot, socket, or port simply by mousing to that location. We picked the port that our USB flash drive was plugged into and its description was accurate, though the cursor position wasn’t captured by MSI’s screenshot utility.

Overclocking

We’ve retained the hardware from our X570 Aorus Master Review to compare the MEG X570 Ace, adding data from our upcoming ROG Strix X570-E Gaming to expand the charts. It’s only fair, since we put the MEG X570 Ace’s data in the X570 Aorus Master review.

MSI MEG X570 ACE

ASRock X570 Taichi

Gigabyte X570 Aorus Master

The MEG X570 Ace’s 4.20 GHz CPU clock would have put it over all X570 comers, if not for the spoiler data from our upcoming review of the ROG Strix X570-E Gaming. And what good would that win over other X570 models have done if it only managed to tie the older X470 board?

Memory overclocking is the MEG X570 Ace’s competition killer, where it accomplishes around 200 MHz higher data rate than the average of its competitor’s, even after we adjusted the voltage to keep the competition fair. Yet performance is the point of overlocking, so how much bandwidth did it get?

Relaxing secondary and tertiary timings are one trick to achieving a high memory overclock, but a performance deficit results. That’s what appears to be going on in the overclocked bandwidth chart, where even the X570 Taichi’s lowly DDR4-3733 four-DIMM limit outperformed the mighty X570 Ace’s DDR4-4000 bandwidth. These are also best-case scenarios since Sandra’s memory bandwidth drops when only two DIMMs are installed: The Taichi’s DDR4-4000 two-DIMM test produced only 38 GBps, and the Ace’s DDR4-4333 produced only 37 GBps, according to our test notes.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark Results and Final Analysis

3DMark And PCMark

Miniscule performance differences displayed throughout the 3DMark and PCMark tests indicate that users are better off making their purchase decisions based on other criteria, such as connector availability and memory overclocking, rather than baseline performance.

3D Games

The point of motherboard benchmarks has become a search for problems rather than solutions, since most program performance is dictated by the hardware these boards share. The closest thing we see to a problem in gaming is that the MEG X570 Ace takes a marginal lead over the other boards at our lower test settings of Ashes, at both resolutions.

Mixed Applications

The MEG X570 Ace fairs well in 7.Zip’s integrated benchmark (higher is better), but falls behind nearly 4% in our Handbrake timed test (fewer seconds are better). That loss combines with a smaller one in Handbrake H.264 and class-average results in Lame and Corona to reduce the Ace’s timed application loss to less than 3%.

Power, Heat And Efficiency

The MEG X570 Ace pulls the lowest full-load power numbers, but does so by using a 1.064V CPU core at a 3.8 GHz clock rate. If those lower settings are affected by both workload intensity and duration, it could explain why the board lost in our lengthy H.264 performance test and was even more behind in our lengthier H.265 test.

MSI’s lower voltage and clock gave it the lowest CPU temperature. ASRock chose to push CPU clock to its default 4.1 GHz limit at firmware defaults, suffering both the power and thermal deficits as a result. Gigabyte and Asus boards use similar voltage to the X570 Ace, but at 3.90 and 3.95 GHz respectively.

Chokes are the hottest components on each of these boards’ voltage regulators, and since those are easily measured with an infrared thermometer, those results are shown. Software reported that the MEG X570 Ace had the highest MOSFET temperature at 26 degrees over-ambient, followed by the X570 Aorus Master at 23 degrees and X570 Taichi at 16 degrees over ambient. But we find our thermometers to be far less biased.

With a performance average that’s less than 1% below the class average and a power savings of nearly 10% of class average, the MEG X570 Ace is the most-efficient X570 board tested. The old X470 model saved a bit more power, but does so in part by having a less-elaborate chipset (with no PCIe 4.0 support).

Final Thoughts

The MEG X570 Ace is priced $10 higher in USA than the X570 Aorus Master, but it shouldn’t be. Even though it has a slightly larger voltage regulator and overclocks our memory better, it lacks some of the Gigabyte board’s extra features such as dual thermistor leads and accompanying onboard headers. Most of these boards features are identical in most other ways, though the MSI board ditches the pretense of six SATA headers for four (two of Gigabyte’s are disabled by the third M.2 drive). And Gigabyte ditches the pretense of two PCIe 4.0 x1 slots for one (only one of MSI’s x1 slots can be used at a time). Then again, some users will look at those extra connectors and see more installation flexibility.

Perhaps this is why MSI’s MEG X570 Ace is £20 cheaper than the X570 Aorus Master in UK, but what we’re seeing is two boards that are so similar in both features and price that neither overwhelms the other. MSI achieved a far higher DRAM O/C, but its class-leading OC had the lowest in-class bandwidth. And its paltry 25 MHz improvement in CPU clock is just that. We’d say pick your favorite based on whichever connector placement you prefer.

All that said, excellent bandwidth scaling over a wider range of data rates forces us to consider the MEG X570 Ace for an upcoming AMD memory deep dive, despite its competitive loss in maximum bandwidth. We’d love to hear your thoughts in our response thread below.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Gigabyte X570 Aorus Master Review: Expansion and M.2 Aplenty

Thomas Soderstrom — Wed, 17 Jul 2019 17:00:00 +0000

Specifications and Design

The price of AMD's X570-chipset motherboards may be off-putting to buyers accustomed to AMD’s low-cost story, and the lower cost of previous-generation X470 boards that, a lack of PCIe 4.0 support aside, are still viable options for AMD's new Ryzen 3000 processors. Gigabyte’s X570 Aorus Master competes in a high-end enthusiast segment that, thanks to the added cost of new technology, starts at around $300. Users who have adjusted their value expectations to current market conditions will find the $360 for this model reasonable, with our apologies to buyers in U.K. (where it’s £390).

Gigabyte X570 Aorus Master Specs

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	14 Phases
Video Ports	✗
USB Ports	10Gbps: (1) Type-C, (3) Type A5Gb/s: (2) Type A; (4) USB 2.0
Network Jacks	2.5GbE, Gigabit Ethernet, (2) Wi-Fi Antenna
Audio Jacks	(5) Analog, (1) Digital Out
Legacy Ports/Jacks	(2) USB 2.0
Other Ports/Jack	BIOS Flashback, CLR_CMOS Buttons
PCIe x16	(3) v4.0 (x16/x0/x4, x8/x8/x4)
PCIe x8	✗
PCIe x4	✗
PCIe x1	(1) v4.0
CrossFire/SLI	3x / 2x
DIMM slots	(4) DDR4
M.2 slots	(3) PCIe 4.0 x4* / SATA(*3rd M.2 consumes four-lane x16 slot)
U.2 Ports	✗
SATA Ports	(6) 6Gb/s (shared with PCIe M.2-3)
USB Headers	(1) v3.x Gen2, (2) v3.x Gen1, (2) v2.0
Fan Headers	(7) 4-Pin
Legacy Interfaces	System (Beep-code) Speaker
Other Interfaces	FP-Audio,TPM, (2) ARGB, (2) RGB-LED, TPM, (2)Thermistor Header
Diagnostics Panel	Numeric
Internal Button/Switch	Power, Reset / BIOS mode, IC selector
SATA Controllers	Integrated (0/1/10)
Ethernet Controllers	RTL8125AG PCIe, WGI211AT PCIe
Wi-Fi / Bluetooth	Intel AX200 802.11ax (2.4 Gb/s) / BT 5.0 Combo
USB Controllers	✗
HD Audio Codec	ALC1220
DDL/DTS Connect	✗
Warranty	3 Years

(Image credit: Gigabyte)

Given what we’ve seen from other brands and what we’ve learned about the extra cost of producing PCIe 4.0 motherboards, we were surprised to see this high-end Gigabyte Aorus model selling for an almost-reasonable $360. (Although be fair, the company's true X570 flagship is the $699 X570 Aorus Xtreme). With the Master, we have a hefty (1.5kg/3.3-pound) piece of gear packed with everything from extra USB3 Gen2 ports to dual Ethernet (including 2.5 Gbps) and even a 2.4 Gb/s Wi-Fi controller, triple M.2 slots that are all active at the same time as triple PCIe “x16” slots, and even a quiet fan, to compete for a high-end market that effectively begins at $300.

It’s not that Gigabyte added any USB controllers to get those four I/O-panel ports, but that it added the resources to wire them out in a way that at least one competitor didn’t. Nor did the firm figure out how to magically cool the X570 PCH without a fast fan, but it instead chose a default RPM-to-temperature profile that kept the thing nearly silent throughout our review. And it’s not as though Gigabyte added any expensive PCIe 4.0 bridges, since two of those three x16 slots are CPU based and share sixteen pathways, while the third has only four lanes from the PCH. It’s just that, as with the I/O panel USB configuration, the company put in a little extra effort and / or expense to make the features baked into AMD's chipset more-accessible.

The 2.5 Gbps Ethernet port is a nice addition though, particularly for those who have a 2.5GbE/5GbE router. It’s a Realtek RTG8125AG, for those who need to check compatibility.

In addition to the Wi-Fi, dual Ethernet and quad USB3 Gen2 ports, the I/O panel is filled out with two USB3 Gen1 and four USB 2.0 ports, an optical S/PDIF and five analog audio jacks, and a pair of buttons for updating firmware and clearing its settings. The audio is fed from an ALC1220 codec through an ESS Sabre 9118 reference DAC for improved clarity, and the WiFi 6 adapter is supplied by Intel for improved compatibility.

While we generally recommend having a pair of USB 2.0 ports on the I/O panel to interface a keyboard and mouse without eating heavily into chipset I/O resources, we’ve no clue what you'd do with the other two here. These could appeal to users who treat their gaming PC as a general-purpose machine with a printer and scanner, perhaps. But we'd still like to see more faster USB ports here.

Gigabyte wants buyers to know that its power is fed through fourteen chokes by 50A Infineon IR3556 MOSFETs from a 16-channel Infineon XDPE132G5C controller in a 12 (core) +2 (SOC) configuration. Those MOSFETs are cooled by a traditional stacked-fin heat pipe arrangement that’s been fitted with a plastic shroud to give it a more-modern appearance.

A row of voltage detection points is found between a pair of CPU fan headers and a pair of RGB/ARGB headers in the upper-right corner. Beneath those are power and reset buttons, a switch to disable dual BIOS mode, a selector switch for the two firmware ROM ICs, and a two-digit status code display.

There’s still no such thing as a free lunch, and the cost of a four-lane bottom PCIe 4.0 slot and a pair of PCH-based M.2 slots that don’t share resources is paid by two of the SATA ports being disabled when the lower M.2 slot is used. That still leaves four SATA ports active on the front edge, above which is the front-panel USB3 Gen2 header. Below these, a front-panel audio, ARGB, RGB, TPM, two dual-port USB 2.0, a fan, two USB3 Gen1, Intel-style front-panel LED/button, a PC Speaker and a 3-pin power LED header fill the bottom edge.

Much of the X570 Aorus Master’s weight comes from a steel panel that covers its back. This is perfect for testing the board without a case, but won’t do much (except add weight) to a finished build.

The X570 Aorus Master’s installation kit includes a multi-language manual, driver and application disc, four SATA cables, ARGB adapter and RGB extension cables, two thermistor leads, an internal microphone on an extension cable for noise-to-temperature (rather than RPM-to-temperature) fan programming, two Velcro cable ties, Gigabyte’s G-Connector front-panel lead bundler, a 2T2R Wi-Fi antenna with weighted magnetic base, a sticker pack, and a set of screws for securing M.2 drives.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Firmware and Overclocking

The X570 Aorus Master’s firmware defaults to its Advanced Mode interface, where its Tweaker menu has enough controls to set most overclocks. We reached a mere 4.175 GHz on our Ryzen 7 3700X, but the board pushed two of our DDR4-2933 modules to a stellar DDR4-4066. The shown DRAM voltage setting of 1.32V produced an actual reading of 1.348V at the slot, and the next higher setting (1.33V) would have violated the 1.355V limit we’re using to keep companies from cheating in that portion of our overclocking evaluation.

The Advanced Memory Settings sub-menu provides SPD information and a separate timings sub-menu, where we set 20-21-21-21-42 latency to give our modules enough room to hopefully reach DDR4-4200. The achieved DDR4-4066 is a good effort towards that goal.

Avoiding the dreaded “vdroop” phenomena under high software loads required setting the board’s VCore Loadline Calibration to Turbo mode, which pushed core voltage upward by around 5mV under load. Alternatively, the next lower setting allowed it to drop by around 15mV under load.

All seven fans can be manually adjusted or set to an automatic mode, and users can manually select between voltage- and PWM-based control for all seven headers or use auto mode to allow the board to detect whether the PWM connection is present. Included software allows the system to create a new fan profile based on noise rather than RPM.

Users who might be confused by the advanced GUI can switch to Easy Mode by tapping the prompt at the bottom of Advanced mode, or by using the keyboard’s F2 key.

Overclocking

We’ve retained the hardware from our first X570 motherboard review to compare the X570 Aorus Master, adding data from our upcoming MSI MEG X570 ACE review to expand the charts.

Frequency and Voltage settings	Gigabyte X570 Aorus Master	ASRock X570 Taichi	MSI MEG X570 ACE	Gigabyte X470 Aorus Gaming 7 WiFi
BIOS	F5e (07/04/2019)	P1.20 (06/20/2019)	1.20 (06/28/2019)	F40 (05/16/2019)
Reference Clock	100-300 MHz (10kHz)	100-200 MHz (1 MHz)	80-200 MHz (5 kHz)	100-300 MHz (10kHz)
CPU Multiplier	8.00-63.75x (0.25x)	22-63x (0.25x)	8.00-63.75x (0.25x)	8.00-63.75x (0.25x)
DRAM Data Rates	1333-2666/5000/6000 (267/66/100 MHz)	1866-2400/5000/6000 (267/66/100 MHz)	1600-2666/5000/6000 (266/66.7/100 MHz)	1333-5000 (66.67 MHz)
CPU Voltage	0.75-1.80V (6.25mV)	0.90-1.55V (6.25 mV)	0.90-2.00V (12.5 mV)	1.00-1.70V (6.25mV)
CPU SOC	0.75-1.80V (6.25 mV)	0.90-1.60V (5 mV)	0.90-1.55V (12.5 mV)	0.80-1.70V (6.25mV)
VDDP	Offset -0.2 to +0.70V (20 mV)	0.80-1.30V (10mV)	-	Offset -0.2 to +0.70V (20 mV)
DRAM Voltage	1.00-2.00V (10 mV)	1.00-1.80V (6 mV)	0.80-2.00V (10 mV)	1.10-2.00V (10 mV)
DDR VTT	0.44-0.98V (5 mV)	Offset -600 to 600 mV (10mV)	0.120-1.235V (5 mV)	0.83-1.66V (8.33 mV)
Chipset 1.05V	0.80-1.50V (20 mV)	1.00-1.20V (5 mV)	0.85-1.50V (10 mV)	1.05-1.41V (20 mV)
CAS Latency	8-33 Cycles	8-33 Cycles	8-33 Cycles	8-33 Cycles
tRCDRD/RDCWR	8-27 Cycles	8-27 Cycles	8-27 Cycles	8-27 Cycles
tRP	8-27 Cycles	8-27 Cycles	8-27 Cycles	8-27 Cycles
tRAS	21-58 Cycles	21-58 Cycles	21-58 Cycles	21-58 Cycles

The X570 Aorus Master ties the X570 Taichi in CPU overclocking, but we’re noticing that each newer review brings a new overclocking high. In this case, it’s Gigabyte’s memory overclock beating ASRock’s. And even though the X570 ACE shows an older firmware than Gigabyte, that update came to us later.

In fact, the inclusion of the X570 ACE data put a damper on the Aorus Master’s overclocking achievements, just as the Aorus Master’s results prevented a Taichi victory. But what does all the memory overclocking mean for performance?

Even though the MEG X570 ACE had by far the fastest DRAM data rates, the most effective use of overclocking goes to the X570 Taichi. The X570 Aorus Master hit a middling frequency, but only managed to turn that into the same performance level as the lower-clocking Taichi.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark Results and Final Analysis

3DMark and PCMark

As motherboards jockey for leadership across most of our 3DMark and PCMark tests, the result that stand out most is the X570 Aorus Master’s 4% deficit in the Application Start Up test of PCMark Essentials. We’ll see if it can make up some of that loss in the performance balance though other suites.

3D Games

The MEG X570 Ace gets the highest score at Ashes’ lower test settings, but the X570 Aorus Master beats all competitor’s by a slightly greater margin at the game’s higher settings. F1 2017 is a dead heat.

Mixed Apps

7.Zip shows a slight lead for the X570 Aorus Master in both reading and writing, but theX570 Taichi beats it in both Cinebench and Handbrake.

Power, Heat and Efficiency

The X570 Aorus Master crushes the X570 Taichi in power consumption, though it places third against the X570 Ace and its X470 predecessor. The reason for the difference is that it uses less voltage under loads this heavy, and runs up to 200 MHz slower.

The lower voltage allows both the board and voltage regulator to produce less heat, but the X570 Aorus Master still finishes second to the X570 Ace.

The X570 Taichi’s full-load power draw is so high that it skews the rest of the chart into positive efficiency numbers, though the X570 Aorus Master is the least positive of these.

Final Thoughts

The X570 Aorus Master costs $60 more than the X570 Taichi, and the onboard 2.5GbE controller for the second Ethernet port appears at a glance to be the only extra hardware. A closer look reveals an extra switche to disable dual-BIOS mode, but hardcore overclockers would rather not have the board’s active selection process in the specs sheet. We also get more cables, but can even those be added to the second Ethernet port to justify the extra $60?

For many buyers, the X570 Aorus Master achieves its greatest victory is in its combination of M.2 and PCIe slots that are all active at the same time, as opposed to the X570 Taichi sharing lanes between its third long PCIe slot and its third M.2 slot. Aorus Master buyers looking at that specific benefit will also note that filling the third M.2 slot knocks its SATA port count to four, but most enthusiasts prioritizing fast storage won't need more than four SATA ports.

Overall, the X570 Aorus Master appears to be a more-desirable board than some competitors, that also costs more. The combination of interface availability, added USB3 Gen2, and added 2GbE controller are arguably worth slightly more than the difference in price. But those features of course will of course only worth it to you if you're going to make use of them.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

AMD Ryzen 7 3800X Review: Core i7 Has a New Challenger

palcorn@outlook.com (Paul Alcorn) — Mon, 15 Jul 2019 22:45:00 +0000

Cranking it up to 105W

AMD's Ryzen 3000 series has landed, upping the ante with Intel in its high-stakes game for desktop PC market dominance with a well-rounded lineup of new chips that push mainstream platforms to higher core counts and more raw compute than we've ever seen. As a result, Intel's commanding presence in the enthusiast space is threatened in a way we haven't seen in over a decade.

We began with a look at the Ryzen 9 3900X and Ryzen 7 3700X last week and came away impressed, but our review left us feeling like something was missing.

That something is the Ryzen 7 3800X. AMD cranks the TDP dial up to 105W on this 8-core 16-thread chip, making it the high-performance counterpart to the 65W Ryzen 7 3700X, which is basically the same 7nm chip built with the Zen 2 microarchitecture, but with a lower TDP rating. That chip came away from our first look at the Ryzen 3000 series with an Editor's Choice award, going toe-to-toe with Intel's Core i7-9700K, so it's fair to say we have high hopes for the higher-performance model. AMD still hasn't sampled the chip to the press, so we bought one at retail to put it under the microscope.

The Ryzen 7 3800X slots in beneath the Ryzen 9 3900X, which comes with two 7nm compute die tied together with a 12nm I/O die to yield a 12-core 24-thread part. AMD has worked wonders to reduce the impact of this sort of multi-chip arrangement, but it's fair to assume that the Ryzen 7 3800X's single-compute-die design, paired with a higher TDP rating that facilitates more aggressive boost clocks, could actually rival the 3900X in some applications – games included.

	SEP (USD)	Cores / Threads	TDP (Watts)	Base / Boost Frequency (GHz)	L3 Cache (MB)	PCIe 4.0 Lanes
Ryzen 9 3950X	$749	16 / 32	105W	3.5 / 4.7	64	24
Ryzen 9 3900X	$499	12 / 24	105W	3.8 / 4.6	64	24
Ryzen 7 3800X	$399	8 / 16	105W	3.9 / 4.5	32	24
Ryzen 7 3700X	$329	8 / 16	65W	3.6 / 4.4	32	24
Ryzen 5 3600X	$249	6 / 12	95W	3.8 / 4.4	32	24
Ryzen 5 3600	$199	6 / 12	65W	3.6 / 4.2	32	24

And that's exactly what we've found. The Ryzen 7 3800X takes the basic ingredients of the Zen 2 microarchitecture, which brings an average of 15% more instructions per cycle (IPC) throughput, and 7nm process and melds them into a high-performance chip that is impressive across our test suite, especially when we factor in the competitive pricing, PCIe 4.0 interface, backward compatibility with most AM4 socket motherboards, unlocked overclocking features, and bundled cooler.

But we've also found that, after simple push-button overclocking, the Ryzen 7 3700X offers similar performance to the 3800X, even when it is also overclocked. But for $70 less. The Ryzen 7 3800X is an impressive chip and offers a better mixture of performance than Intel's Core i7-9700K, no doubt, but in this case, value seekers might opt for its less expensive sibling.

Ryzen 7 3800X

We covered the deep dive details of the Ryzen 3000 chip design in our AMD Ryzen 9 3900X and Ryzen 7 3700X review, so head there for more information on the 3800X's architecture, which is identical to the Ryzen 7 3700X.

The $399 Ryzen 7 3800X lands in the pricing gap between the $488 Core i9-9900K and the $374 Core i7-9700K. Of course, the -9700K slots in as the 3800X's natural competitor, and while it matches the AMD part with eight physical cores, Intel's trimming of the Hyper-Threading feature leaves it eight threads shy of the 3800X.

	Process	SEP / RCP (USD)	Cores / Threads	TDP (Watts)	Base Frequency (GHz)	Total Cache (MB)	PCIe Lanes	iGPU	Price Per Thread
Core i9-9900K	14nm	$488	8 / 16	95w	3.6 / 5.0	16	16 Gen3	Yes	$30.05
Ryzen 7 3800X	7nm	$399	8 / 16	105W	3.9 / 4.5	32	24 Gen4	No	$24.94
Core i9-9700K	14nm	$374	8 / 8	95W	3.6 / 4.9	12	16 Gen3	Yes	$46.75
Ryzen 7 2700X	12nm	$329	8 / 16	105W	3.7 / 4.3	16	20 Gen3	No	$20.56
Ryzen 7 3700X	7nm	$329	8 / 16	65W	3.6 / 4.4	32	24 Gen4	No	$20.56
Core i7-9700	14nm	$323	8 / 8	95W	3.6 / 4.9	12	16 Gen3	Yes	$40.38

The -9700K comes with a 95W TDP rating, whereas the 3800X weighs in with a 105W rating. Contrary to popular belief, these ratings aren't meant to quantify power consumption. Instead, they measure the amount of heat the chip dissipates under load, but both companies use different test methodologies. Intel specs TDP at the base frequency, thus ignoring peak heat output during boost activity, while AMD measures with all cores fully loaded. The only way to make real power comparisons is via power measurement, which we'll get to shortly. In either case, we expect that AMD's 7nm design will continue the trend of heightened power efficiency over Intel's 14nm parts. The 3800X also comes with a healthy serving of 32MB of L3 cache, while Intel's -9700K comes with 12MB.

As the higher-priced version of the Ryzen 7 3700X, the 3800X has higher base and Precision Boost frequencies of 3.9 and 4.5 GHz, respectively. That's a 300 MHz increase in base frequency and a 100 MHz bump to boost clocks, but the real advantage should lay in the higher Package Power Tracking (PPT) envelope, which is a measurement of the maximum amount of power delivered to the socket. The 3700X's PPT tops out at 88W, while the motherboard can pump up to 142W to the 3800X at peak performance. That opens up much more aggressive boost behavior, on both single and multiple cores, that could widen the performance gap beyond what we see on the spec sheet.

(Image credit: AMD)

Like the other Ryzen 7 and 9 chips, the 3800X comes with the capable Wraith Prism RGB cooler which is rated to dissipate up to 124W if you crank the fans up to high. Given the 3800X's maximum 142W PPT measurement, that means, at least on paper, that the Wraith Prism might come up a tad shy of dissipating the full heat output of the 3800X at stock settings.

Due to the dynamic nature of AMD's Precision Boost 2 algorithms, the chip will react based upon its environmental conditions, with thermal dissipation being a key variable that dictates performance. That means you could likely get better performance, even at stock settings, with a better cooler. The Wraith also won't provide much overclocking headroom. Consider buying a heftier cooler for overclocking or unleashing the full benefit of Precision Boost Overdrive (AMD's automated overclocking feature). We've flagged this for additional testing once we receive more mature BIOS revisions.

You can pair the Ryzen 3000 chips with the new X570 chipset to unleash the increased throughput of PCIe 4.0, a feature that Intel doesn't offer, or you can drop the processor into most previous-gen motherboards as a value alternative, but you'll lose PCIe 4.0 support.

DIMM Config	Memory Ranks	Official Supported Transfer Rate (MT/s)
2 of 2	Single	DDR4-3200
2 of 4		DDR4-3200
4 of 4		DDR4-2933
2 of 2	Dual	DDR4-3200
2 of 4		DDR4-3200
4 of 4		DDR4-2667

Ryzen 3000 chips support dual-channel DDR4-3200, a step up from the previous-gen's support for DDR4-2966. AMD has greatly improved its memory compatibility and overclocking capabilities, but you still have to abide by rules that dictate the maximum supported frequency based on DIMM type and slot population.

If you don't like those rules, you can simply bump up the voltage and try your hand at overclocking, or buy a higher-rated kit with a one-click A-XMP profile. As we know, the Zen microarchitecture profits heavily from improved memory performance, so higher-priced kits are a good investment that yield dividends, particularly in gaming.

(Image credit: AMD)

AMD has improved memory overclocking substantially, partly due to decoupling the Infinity Fabric from the memory clock. To sidestep the Infinity Fabric's maximum frequency of 2,000 MHz, which effectively constrains memory overclocking, AMD separated the memory and Infinity Fabric clock dependencies. The domains remain tied together at a 1:1 ratio up to DDR4-3600, but run at a 2:1 ratio beyond that transfer rate. This setting, which is also user-adjustable in the BIOS, improves memory bandwidth but comes with a latency penalty (~9ns). AMD says that the price/performance sweet spot lands at DDR4-3600. As per its usual policy, AMD supports up to 128GB of RAM and enables ECC support, but leaves ECC qualification and enablement to motherboard vendors.

MORE: Best CPUs

MORE: CPU Benchmark Hierarchy

MORE: All CPUs Content

Boost Clocks, Overclocking, Thermals and Test Setup

We observed our Ryzen 7 3800X hit it's 4.5 GHz boost clock sporadically, but like the Core i9-9900K's elusive 5.0 GHz boost, those moments were brief. This tracks well with with the boost clock behavior we've seen with the Ryzen 9 3900X and Ryzen 7 3700X. We're currently waiting for improved BIOS revisions and will update as necessary.

Manual Overclocking

We initially dialed in a 4.4 GHz overclock with the Ryzen 7 3800X with a relatively high 1.45V vCore, and while the configuration passed through our entire test suite, it couldn't pass through a new battery of AI tests we're preparing that uses various flavors of the AVX instruction set. As tantalizingly close as we came, we couldn't get the system 100% stable at 4.4 GHz, even with more intense voltages. We were pushing the limits of our Corsair H115i cooler, often running right at the maximum 95C specification of the processor, so we dialed our overclock back to 4.3 GHz for our testing.

Reaching 4.3 GHz was fairly straightforward: a 1.42 vCore paired with auto Load Line Calibration, uncorked power settings in the BIOS, and memory overclocked to DDR4-3600 with 14-14-14-36 timings proved rock solid throughout our full battery of stress and application tests.

We recorded average temperatures of 80C, 81.64C, and 84.8C during extended x264 encoding, x265 encoding, and y-cruncher workloads, respectively. Our maximum peak temperature of 91C came during our y-cruncher test, but it registered for roughly one second. Overall, temperatures during our test tracked well with the average measurements.

Security Mitigations

The new AMD-optimized Windows scheduler is only present in Windows 10 1903 and promises to expose gains in several types of applications. As such, we updated our test image to the latest version of Windows 10 available (18362.207). All of our test results come from the aforementioned operating system and include all publicly available security mitigations and the latest motherboard firmware revisions. Intel is currently impacted by Spectre, Spectre v4, Meltdown, Foreshadow, Spectre v3a, Lazy FPU, Spoiler, and MDS, while AMD is only impacted by Spectre and Spectre v4. AMD has added hardware-based mitigations for both variants of Spectre, which should reduce the performance impact, but the requisite patches for both companies have performance penalties, which are reflected here in our testing.

A Note on Multi-Core Enhancement (MCE)

MSI MEG X570 Godlike

The pricey Godlike board retails for around $800, but has the 14+4+1-phase power delivery subsystem to support aggressive overclocking.

The MEG X570 Godlike sits at the top of MSI's motherboard hierarchy. It also comes with a few nifty accessories like a 10Gb “Super LAN” Ethernet card and a PCIe Gen 4 Xpander-Z M.2 expansion card. That lets you add two more M.2 drives to complement the three M.2 PCIe Gen 4 M.2 ports on the board. You also get four PCIe 4.0 x16 slots, an RGB Mystic Light Infinity II mirror over the IO shroud, and a tiny OLED screen, alongside the two-digit LCD display for error codes.

Comparison Products

Intel Core i9-9900K

Intel Core i7-9700K

AMD Ryzen 7 2700X

Test System & Configuration
Hardware	AMD Socket AM4 (X570)AMD Ryzen 9 3900X, Ryzen 7 3800X, Ryzen 7 3700X, Ryzen 7 2700XMSI MEG X570 Godlike2x 8GB G.Skill Flare DDR4-3200Ryzen 3000 - DDR4-3200, DDR4-3600Second-gen Ryzen - DDR4-2933, DDR4-3466Intel LGA 1151 (Z390)Intel Core i9-9900K, i7-9700KMSI MEG Z390 Godlike2x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2667 & DDR4-3466AMD Socket AM4 (X470)AMD Ryzen 7 1800XMSI X470 Gaming M7 AC2x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2933AMD Socket SP3 (TR4)Threadripper 2920XMSI MEG X399 Creation4x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2933Intel LGA 2066Intel Core i9-7920XMSI X299 XPower Gaming AC4x 8GB G.Skill FlareX DDR4-3200 @ DDR4-2666All SystemsNvidia GeForce RTX 2080 Ti 2TB Intel DC4510 SSDEVGA Supernova 1600 T2, 1600WWindows 10 Pro (1903 - All Updates)
Cooling	Corsair H115iCustom Loop, EKWB Supremacy EVO waterblock, Dual-720mm radiatorsAMD Wraith Prism Stock CoolerEnermax Liqtech 240 TR4 II

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Power Consumption

Our power measurements, which we recently migrated towards a more efficiency-focused approach, revealed some interesting tidbits. Particularly in regards to both Precision Boost Overdrive and manual overclocking.

AMD's Precision Boost Overdrive (PBO) is an adaptive overclocking approach that allows the processor to communicate with the platform to modulate performance based on the motherboard's power delivery subsystem and thermal dissipation capabilities. The processor monitors Package Power Tracking (PPT), which is total socket power, and the Thermal Design Current (TDC) variable, which is the motherboard's maximum available sustained current. Electrical Design Current (EDC) also indicates the maximum current possible from the VRMs during peak/transient conditions.

105W CPU Limits	PPT
AMD IPM	142W	95A	140A
MSI X570 Godlike	1000W	490A	630A

AMD enables two options for PBO: IPM is AMD's default PBO setting, which is activated if you leave the PBO setting to 'Auto' in the Godlike's UEFI. But you can select 'Enabled' to activate a profile that's dictated by the maximum limits of the motherboard's power delivery subsystem. These limits vary by motherboard and are defined by the vendor. We chose the latter to unlock the full potential of PBO. As you can see in the table, this enables the most robust power delivery options available, kicking the socket's maximum power delivery up to 1000W, and is designed to offer the best of increased multi-core boost clocks while retaining the high single-core boost clocks.

You can also further tune the power delivery options with an Auto OC (AOC) feature. This new feature grants you some control over the maximum attainable boost clocks by allowing you to add up to an extra 200MHz to the maximum boost clock, but it isn't guaranteed that the processor will reach those speeds at all times, or under all conditions. Instead, the processor will still respect the limits imposed by the motherboard maker.

Unfortunately, we've found that the PBO+AOC feature often comes at the expense of performance in single-threaded workloads even though it is billed as retaining, and even heightening, single-core boost clocks. From a performance and power consumption standpoint, it is more comparable to our all-core 4.3 GHz overclock. This might be an issue with early AGESA versions, but for now, the feature actually results in less performance in single-threaded workloads with MSI's X570 Godlike motherboard.

We chose to go with the limits of the motherboard, noted on the charts below as PBO, and the all-core 4.3 GHz overclock we outlined on the prior page. It's noteworthy that our all-core overclock comes at the expense of the single-core 4.5 GHz boost, which was a relatively rare occurrence during our testing in both stock and PBO trim.

We began with the non-AVX stress test in AIDA64 and found that the Ryzen 7 3800X draws very little power at stock settings, nearly matching the stock Ryzen 7 3700X's power draw. We activated Precision Boost Overdrive, and the processor's power draw only increased marginally to 95W. Our all-core overclock, however, sucked down 126W on average, but hit 163W peaks during the test.

You'll notice the Ryzen 7 3700X draws more power with PBO+AOC active than the 3800X's PBO configuration, but that's due to its all-core overclock-like nature. As such, our PBO+AOC results for the Ryzen 9 3900X and Ryzen 7 3700X are more comparable to the 3800X's all-core overclock.

We see muted increases in the 3800X's power consumption from the PBO option, and as a result, we also see minor performance improvements. Conversely, the all-core overclock consumes much more power but doesn't yield big performance benefits over the PBO settings. It appears that, for stock operation, AMD has tuned the processors right at the point of the voltage/frequency curve that provides the maximum frequency possible that can still provide great efficiency metrics. This PBO configuration also seems to retain some of those same characteristics, but that doesn't leave much headroom for explosive performance gains.

Plotting power consumption over our performance measurements highlights some of the gains we recorded with both overclocked settings. Here we can see the 3800X's 4.3 GHz all-core overclock regularly outperform the stock and PBO configurations, but its performance is very similar to the Ryzen 7 3700X with PBO. The overclocked 3800X's wins over the tuned 3700X weighed in at 1.91% for y-cruncher, 2.6% for x265, and 3.2% with x264 encoding. That shows that the Ryzen 7 3700X, while slower than the 3800X at stock settings by a larger margin, is competitive in threaded workloads after we tune both processors. Let's see how they compare in games.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

VRmark, 3DMark and AotS: Escalation

We tested the Threadripper 2920X in Game Mode for our game suite, and Creator Mode for our application tests.

VRMark, 3DMark

We aren't big fans of using synthetic benchmarks to measure performance, but 3DMark's DX11 and DX12 CPU tests provide useful insight into the amount of horsepower available to game engines.

The DX11 and DX12 CPU test results expose the full threaded heft of the Ryzen 3000 series processors. The Ryzen 9 3900X dethrones the overclocked Core i9-9900K in both tests. After overclocking, the Ryzen 7 3800X posts a virtual tie with Intel's flagship in the Fire Strike physics test, and the all-core overclock provides a comparable level of performance in the Time Spy test.

The VRMark test benefits heavily from per-core performance, and the Ryzen 3000 processors have made great strides compared to the first- and second-gen models. The Ryzen 3000 series processors have also become much more competitive in this benchmark, with the 3800X beating the stock Core i9-9900K and landing within a few FPS of the Core i7-9700K.

Ashes of the Singularity: Escalation

Ashes of the Singularity: Escalation is a computationally intense title that scales well with thread count, but clock speeds and per-core performance play a big role, as evidenced by the overclocked Core i9-9900K's spot at the top of the chart. The Ryzen 3000-series processors notch impressive gains, and we can see that the title responds well to our manual all-core overclock and the automatic PBO overclock. At stock settings, the Ryzen 7 3800X slots in right where we'd expect, and the Intel processors can only challenge if we apply an overclock.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Civilization VI Graphics and AI, Dawn of War III

Civilization VI AI Test

The Ryzen 7 3800X handily beats the previous-gen models in this test of AI performance in a turn-based strategy game. This test is highly dependent on per-core performance. At stock settings, the 3800X matches the 3700X. As expected, the automated PBO overclocking feature yields similar results, but the processor doesn't fare as well with the all-core 4.3 GHz manual overclock because it loses the advantage of the single-core boost frequency of 4.5 GHz.

Civilization VI Graphics Test

The Ryzen 9 3900X is incredibly impressive in this benchmark, but the Ryzen 7 3800X requires tuning to climb the ranks. The 3800X ties the 3700X at stock settings, but cranking up the voltage gives it a slim ~1 FPS lead over the tuned 3700X.

The all-core overclock, which is manually dialed into a static 4.3 GHz, does provide a 3 FPS advantage in our 999th percentile frame rates over the auto-overclocked PBO configuration. We noticed this almost imperceptible difference between the two processors in several tests, indicating PBO's dynamic clock adjustments might have an impact on smoothness, although it's fair to say it is likely imperceptible.

We also see a 1 FPS difference in the less-stringent 99th percentile measurement, but the differences are slight. The advantage goes either way, either for or against manual tuning, throughout our suite.

Warhammer 40,000: Dawn of War III

The Warhammer 40,000 benchmark responds well to threading, but it's clear that Intel's clock speed advantage has an impact. The Ryzen 7 3800X gains 1 FPS over the 3700X at stock settings, and roughly 2 FPS after tuning. In either case, the Intel processors lead the chart by a large margin after tuning.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Far Cry 5 and Final Fantasy XV

Far Cry 5

The Ryzen 7 1800X reminds us how far AMD has come since its first-gen products, and even the overclocked second-gen model lags behind the stock Ryzen 3000's by a decent margin.

After tuning, the 3800X ranks as the fastest AMD processor, and there is little difference between the manual and auto-overclocked configurations. Less than ~1 FPS separates the overclocked Ryzen 7 3800X and 3700X, which has become a theme. Intel asserts itself with faster performance across the board.

Final Fantasy XV

We run this test with the standard quality preset to sidestep the impact of a bug that causes the game engine to render off-screen objects. We see the slightest of gains for the manual overclock over the PBO configuration, but that's with expected variance for this benchmark, so consider this a tie.

Again, the Ryzen 7 3700X with PBO applied lands within striking distance of the overclocked 3800X.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

GTA: V and Hitman 2

Grand Theft Auto V

Grand Theft Auto V favors Intel architectures and, more generally, multi-core designs with high clock rates. The 3700X with its combination of PBO and an all-core overclock again offers roughly the same performance as the tuned 3800X.

Hitman

Hitman finds an oddity: The tuned 3700X actually ekes out a slim win over both overclocked 3800X configurations, but the differences are slight.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Project Cars 2, The Division 2, and World of Tanks enCore

Project CARS 2

Although Project CARS 2 is purportedly optimized for threading, clock rates obviously affect this title's frame rates. Intel's per-core performance, which is a mixture of IPC and frequency, pays big dividends in this title.

A glance at the Ryzen 7 1800X reminds us of the giant strides AMD has made in just three generations.

The Division 2

The Ryzen 7 3700X continues to be a thorn in its sibling's side, once again offering nearly the same performance after we engage automatic overclocking.

World of Tanks enCore

World of Tanks closes out our game testing with much the same pattern we observed in other titles.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Office, Web Browser, and Productivity

Web Browser

The Krakken suite evaluates JavaScript performance using several workloads, including audio, imaging, and cryptography. Like most browser-based benchmarks, single-threaded performance reigns supreme.

Browsers tend to be impacted more by the recent security mitigations than other types of applications, so Intel has taken a haircut in these benchmarks of fully-patched systems.

AMD's improved IPC comes into play as the processors post surprisingly good results that we wouldn't have expected with prior-gen models. The tuned Ryzen 7 3800X beats its more expensive counterpart the 3900X in several of these tests, but we see the impact of the 3700X's PBO+AOC configuration hamper its performance in lightly threaded tests. The same applies to the 3800X in some benchmarks even though we aren't engaging the AutoOC feature, meaning there appears to be some work left on the firmware side. Meanwhile, both processors provide great performance in stock trim. The 3800X notches complete victories over the -9700K in Krakken and Speedometer 2, but the -9700K takes the win in WebXPRT 3.

Microsoft Office

Core i7-9700K benefits massively from its overclock in some tests, but in stock form, it often trails the Ryzen 7 3800X. That trend is evident in the overall score.

Productivity

The photo editing benchmark measures performance with Futuremark's binaries using the ImageMagick library. Common photo processing workloads also tend to be parallelized, which plays well to Ryzen's multi-threaded heft. It takes a hefty overclock to boost the -9700K into contention with the 3800X. Again we can see some of the 3700X's performance sapped by the PBO+AOC configuration.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Rendering, Encoding, Compression, Encryption

Rendering

It shouldn't surprise anyone to see the 12-core 24-thread 3900X bring a taste of HEDT performance to the multi-threaded rendering benchmarks. Ryzen 3800X performs well throughout the suite, particularly in the threaded Cinebench R15 test where it even beats the overclocked Core i9-9900K. And it only lags that overclocked processor slightly in the threaded Cinebench R20 benchmark. The 3800X also matches the 3900X in several of the single-core rendering tests, but we can see the 3800X's all-core 4.3 GHz result tumble in the rankings because the processor loses the benefit of its boost clocks. That doesn't have as much of an impact in the threaded workloads where it largely matches or exceeds its own PBO configuration. The tuned 3700X also posts solid scores in those threaded benchmarks, often slotting in slightly below the Ryzen 7 3800X.

With only eight threads, the -9700K is out of its element in the threaded tests, so the wins go Ryzen 7 3800X's way convincingly. The 3800X also beats the -9700K in the single-threaded Cinebench R20 test, but the -9700K excels in single-threaded work.

Encoding and Compression

Core i9-9900K traditionally leverages high frequencies to dominate the HandBrake x265 test, which relies heavily on AVX instructions, and the H.264 test. The Ryzen 7 3700X is impressive against its price-comparable competition, notching impressive leads over the Core i7-9700K and nearly matching the stock -9900K.

We can also see the vast improvement in Ryzen's AVX performance in the y-cruncher tests: We would never have imagined such a massive generational leap, particularly in single-threaded performance. The work AMD has done here is truly impressive and benefits a wide range of professional applications.

Our threaded compression and decompression metrics work directly from system memory, removing storage throughput from the equation. Ryzen 3900X's greatly improved memory performance, along with the generous helping of cores, plays a big role in its commanding lead, but the Ryzen 7 3800X is equally impressive given its single-die design. Here we can see it outperform Intel's -9700K and -9900K across the board.

LAME is the quintessential single-threaded application, and here the Core processors take the lead.

MORE: Best CPUs

MORE: Intel & AMD Processor Hierarchy

MORE: All CPUs Content

Conclusion

We came away impressed with the Ryzen 7 3800X, but motherboard firmwares are still raw, leaving us wondering if there is more performance lurking underneath the heat spreader. Particularly with the Precision Boost Overdrive and Auto Overclock features. If history is any indication, we could see that situation improve as AMD and motherboard vendors work out the kinks. For now, these results reflect our experiences with a chip purchased at retail and with publicly-available firmwares, but your mileage might vary.

In the chart below, we plot gaming performance with both average frame rates and a geometric mean of the 99^th percentile frame times (a good indicator of smoothness). It's worth noting that AMD's previous-gen line-up is heavily discounted, so we’re departing from our standard practice of using official price lists. Instead, we’re using average pricing found online (temporary sales excluded). Volatility applies.

For gaming specifically, we did see slightly larger gains with the Ryzen 7 3700X via its PBO feature than we did with the Ryzen 7 3800X, allowing that processor to nearly match the more-expensive Ryzen 7 3800X in average framerates in all configurations. That isn't entirely unheard of – After overclocking, we saw the same trend of less expensive previous-gen models (non-X) offering similar performance to AMD's pricier X-series processors.

As we've seen, gaming remains an advantage for Intel, so if squeezing out every last frame is all you care about, Intel's processors are a good choice. Much of that performance advantage will be less noticeable when gaming at higher resolutions, or if you pair the processors with a lesser graphics card.

But, like most humans, if you do things other than gaming, the Ryzen 7 3800X offers a better mixture of performance in single- and multi-threaded applications. The 3800X offers twice the threads of the price-comparable Core i7-9700K, and it wields them to great effect in threaded workloads. As such, rendering and encoding remain a strong suit of the Ryzen chips, and AMD's improvements to AVX throughput have yielded impressive results.

AMD's platform also supports the PCIe 4.0 interface that provides twice the throughput of the previous-gen standard. The extra throughput doesn't equate to improved performance in gaming, but it does speed up everyday tasks like file transfers and will unlock more performance in storage-bound applications. That's an advantage that Intel can't match.

Unfortunately, the faster interface does result in higher-priced X570 motherboards, but AMD's continued support for the X470 motherboard ecosystem could help blunt the blow. Motherboard partners continue to offer X470 motherboards, and they are cheap and plentiful. You'll lose access to the PCIe 4.0 interface in exchange for lower pricing, but you'll also have a compelling upgrade path in the future.

AMD's Ryzen 7 3800X comes with a bundled cooler while competing Intel processors come with a cardboard box. That's an added value that you should take into consideration, but you might need a beefier cooling solution if you plan on pushing the limits with overclocking.

For now, we don't see massive gains in performance for the 3800X from the automated overclocking features, and AMD says we shouldn't expect too much manual overclocking headroom. Instead, you should look to tuning the Infinity Fabric and memory, which both raise in lockstep to a sweet spot of DDR4-3600. AMD also cites using PBO to boost performance, but in our test environment, that doesn't have a dramatic impact on performance. Given that we overclocked our memory in tandem with activating PBO, it's possible some of those slim gains actually stem from increased memory performance.

That means running the processor cores at stock settings paired with overclocked memory could offer roughly equivalent performance gains in some workloads. We're impatiently awaiting new firmware revisions to gauge how they react, but we have tested a multitude of PBO configurations with the Ryzen 7 3800X, of which there are many potential options, with varying levels of success. None seem to confer large speedups for gaming, though we did see some better uplift in traditional applications.

In either case, AMD is wringing a surprising amount of performance from its comparably lower clock speeds, largely due to the big generational uplift in IPC. In our tests, the Ryzen 3000 series is also more power efficient in terms of the amount of energy required to complete a task, which also equates to lowered thermal output.

Value seekers who aren't afraid to press the Precision Boost Overdrive button and have sufficient cooling should look to the Ryzen 7 3700X for roughly equivalent performance to the 3800X, particularly if gaming factors heavily into the buying decision. That could save you $70, reinforcing our decision to give the Ryzen 7 3700X an Editor's Choice award.

Out of the box, the Ryzen 7 3800X is a better all-arounder than the Core i7-9700K and offers incrementally higher performance than its downstream counterpart. The bundled cooler reduces platform costs, and a wide array of motherboards with both X470 and X570 chipsets offers plenty of choices for builders.

Photo Credits: Tom's Hardware

MORE: Best CPUs

MORE: CPU Benchmark Hierarchy

MORE: All CPUs Content

ASRock X570 Taichi Review: Jumping Into PCIe 4.0 With Ryzen 3000

Thomas Soderstrom — Sun, 07 Jul 2019 13:02:01 +0000

Features and Layout

ASRock dresses for success with a loaded and shrouded X570 Taichi motherboard, enabling most of AMD’s latest platform feature set when paired with a Ryzen 3000-series processor. Of course there are a few feature updates that weren’t addressed, such as that most of the board’s USB 3.x ports are of the Gen1 (5Gb/s) variety when the chipset supports Gen2 for all ports, but we expected a few small sacrifices from a sub-$300 X570 board. And sub-$300 it barely is, at $299.99.

ASRock X570 Taichi Specs

Socket	AM4
Chipset	AMD X570
Form Factor	ATX
Voltage Regulator	14 Phases
Video Ports	HDMI
USB Ports	10Gbps: (1) Type-C, (1) Type A 5Gb/s: (6) Type A
Network Jacks	Gigabit Ethernet, (2) Wi-Fi Antenna
Audio Jacks	(5) Analog, (1) Digital Out
Legacy Ports/Jacks	(1) PS/2
Other Ports/Jack	BIOS Flashback, CLR_CMOS Buttons
PCIe x16	(3) v4.0 (x16/x0/x4, x8/x8/x4) (*Excluded by 3rd M.2)
PCIe x8	✗
PCIe x4	✗
PCIe x1	(2) v4.0
CrossFire/SLI	3x / 2x
DIMM slots	(4) DDR4
M.2 slots	(2) PCIe 4.0 x4 / SATA, (1) PCIe 4.0 x4 (3rd M.2 consumes four-lane x16 slot)
U.2 Ports	✗
SATA Ports	(8) 6Gb/s
USB Headers	(1) v3.x Gen2, (1) v3.x Gen1, (2) v2.0, (1) AMD fan LED
Fan Headers	(6) 4-Pin, (1) AMD LED fan
Legacy Interfaces	System (Beep-code) Speaker
Other Interfaces	FP-Audio, Thunderbolt AIC, ARGB LED, RGB LED
Diagnostics Panel	Numeric
Internal Button/Switch	Power, Reset / ✗
SATA Controllers	Integrated (0/1/10)
Ethernet Controllers	WGI211AT PCIe
Wi-Fi / Bluetooth	Intel AX200 802.11ax (2.4 Gb/s) / BT 5.0 Combo
USB Controllers	✗
HD Audio Codec	ALC1220
DDL/DTS Connect	DTS Connect
Warranty	3 Years

The X570 PCH’s expanded I/O means that slot layout is one of very few things that the new X570 Taichi has in common with its X470 predecessor’s design. Most of the previous board’s added features have been upgraded on the new model, such as Intel’s 2.4Gb/s AX200 module, bringing the new board up to 802.11ax / Wi-Fi 6 speed. The I/O panel adds firmware update and CLR_CMOS buttons, the third PCIe slot gets added metal reinforcement, and all slots support PCIe 4.0 mode.

Total I/O panel USB count is eight, but only two of those (a Type A and a Type-C) support 10Gbps transfers while the remainder have only 5Gbps. This, it turns out, is a matter of cost rather than platform capability, as both the CPU and PCH support both standards. The single PS/2, HDMI, Gigabit Ethernet, and S/PDIF ports remain, and the Ethernet and Audio connections are still fed from the same i211AT controller and ALC1220 codec, so that the extra buttons and newer Wi-Fi appear to be the only I/O updates.

One of the newer features that isn’t completely obscured by sinks and shrouds are the fourteen chokes, for which circuitry leads to fourteen 50A MOSFETs which are paired up using phase doublers rather than the teamed design of its predecessor’s sixteen 30A phases. More power and smoother delivery are a given, and the firm also claims a reduction in overall temperature as well. All this despite the lower phase count, which means ASRock picked quality over quantity.

Surrounding a shroud that covers the X570 Taichi’s lower half are front-panel audio, Thunderbolt add-in card, TPM, addressable and classic RGB, one (of six) four-pin fan headers, PC speaker and legacy power LED, two dual-port USB 2.0, Intel-style front panel button/LED, eight SATA, USB 3 Gen2, AMD LED fan and fan LED, and a second (of the six) four pin fan headers. The Gen2 USB header supports 10Gb/s front panel port, and its complimentary two-port USB 3 Gen1 header is located further up the front edge. A two-digit diagnostics code display, power, reset, and CLR_CMOS buttons border the main front-panel header.

Peeling off the cover (after removing three socket-head screws), we find that the X570 Taichi supports three M.2 drives rather than its ancestor’s two. The third slot even has the space for those unusually-long 22110 drives, but alas its interface is shared with the third PCIe slot, so that they can’t be used simultaneously. Both PCIe x1 slots are open-ended to support longer cards (such as x4), but using the cover precludes that option as well. The PCH fan is factory configured to run at full speed, and even though it’s fairly quiet for its size, its nearly 6000 RPM makes the PC sound like it has a GeForce 2 constantly running Quake 3.

The back of the X570 Taichi is covered in black-anodized aluminum, which provides the builder the feel of increased quality even though we can’t think of any practical reason for that cover to be there once the PC has been assembled. It adds rigidity, but so does the case’s motherboard tray.

If similarities between the decorative gear on the top shroud to the techno-aesthetic reel-covers of late-80’s audio cassette decks didn’t catch the attention of older readers, perhaps the inclusion of a postcard will. Now where did I put those 35-cent stamps?

The rest of the support kit includes hardware and software manuals, a driver and application DVD, a classic high-bandwidth SLI bridge, a nicely-designed case-top Wi-Fi antenna with adhesive base, a 2mm hex socket screwdriver for the top shroud, four SATA cables, and a case badge.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Firmware and Overclocking

Firmware

The X570 Taichi’s OC Tweaker menu provides the overclocking controls we needed to reach 4175 MHz at 1.375V. More voltage would allow it to run temporarily at 4.20 GHz, but that’s hardly worth fighting for at the cost of CPU longevity. The board’s default “Level 3” Load-Line calibration even did an adequate job of stabilizing core voltage under shifting loads, though higher levels might be appropriate to maintain competition-level voltage settings.

Memory voltage was far less accurate, with the board’s 1.338V setting producing a measured 1.351V at the slots. We keep that under 1.355V for all boards to make sure nobody gets a leg up in overclocking by understating voltage, yet the X570 Taichi still pushed our DDR4-2933 to a stable DDR4-3733 with four DIMMs installed, and DDR4-4000 with only two DIMMs.

We base our memory overclock on CAS 21 straight timings (21-21-21-42) to give our modules a little breathing room, yet the first setting (CAS) showed 21 cycles when we set 20. Because our memory reaches the same overclock at either 20-21-21-42 or 19-21-21-42 (depending on the CPU), trimming one cycle off the front end of our limit doesn’t reduce its clock ceiling.

Though the board’s RGB software is more elaborate, its firmware app provides a variety of patterns for both the onboard strip (under the board’s front edge) and RGB headers.

Fan speeds are adjustable using either motherboard-defined profiles or custom slopes/curves, and the board’s FanTuning algorithm adds automatic customization to modify the factory profiles to better-match individual hardware. Five of the fans can be automatically (via motherboard detection) or manually switched between voltage and PWM-based RPM control, leaving just the primary CPU fan header as PWM-only.

Users who want a to create their own fan profile without keying in percentages can use ASRocks’ Fan-Tastic Tuning menu to drag set points around on a map.

Overclocking

Frequency and Voltage settings	ASRock X570 Taichi	Gigabyte X570 Aorus Master	Gigabyte X470 Aorus Gaming 7 WiFi
BIOS	P1.20 (06/20/2019)	F5e (07/04/2019)	F40 (05/16/2019)
Reference Clock	100-200 MHz (1 MHz)	100-300 MHz (10kHz)	100-300 MHz (10kHz)
CPU Multiplier	22-63x (0.25x)	8.00-63.75x (0.25x)	8.00-63.75x (0.25x)
DRAM Data Rates	1866-2400/5000/6000 (267/66/100 MHz)	1333-2666/5000/6000 (267/66/100 MHz)	1333-5000 (66.67 MHz)
CPU Voltage	0.90-1.55V (6.25 mV)	0.75-1.80V (6.25mV)	1.00-1.70V (6.25mV)
CPU SOC	0.90-1.60V (5 mV)	0.75-1.80V (6.25 mV)	0.80-1.70V (6.25mV)
VDDP	0.80-1.30V (10mV)	Offset -0.2 to +0.70V (20 mV)	Offset -0.2 to +0.70V (20 mV)
DRAM Voltage	1.00-1.80V (6 mV)	1.00-2.00V (10 mV)	1.10-2.00V (10 mV)
DDR VTT	Offset -600 to 600 mV (10mV)	0.44-0.98V (5 mV)	0.83-1.66V (8.33 mV)
Chipset 1.05V	1.00-1.20V (5 mV)	0.80-1.50V (20 mV)	1.05-1.41V (20 mV)
CAS Latency	8-33 Cycles	8-33 Cycles	8-33 Cycles
tRCDRD/RDCWR	8-27 Cycles	8-27 Cycles	8-27 Cycles
tRP	8-27 Cycles	8-27 Cycles	8-27 Cycles
tRAS	21-58 Cycles	21-58 Cycles	21-58 Cycles

ASRock X570 Taichi

Gigabyte X570 Aorus Master

Gigabyte X470 Aorus Gaming 7 WiFi

We’re comparing the X570 Taichi to Gigabyte’s X570 Aorus Master, which we’re then comparing to that company’s previous-gen X470 Aorus Gaming 7 WiFi. All three boards provide a range of voltage levels that exceed what we’re able to use effectively on our dual-fan closed-loop cooler.

Both X570 boards reached the same 4175 MHz CPU clock, but the X570 Aorus Master edged out the X570 Taichi with the highest stable data rate for our DDR4-2933. With four DIMMs installed, the X570 Taichi even fell victim to the X470 comparison board.

Performance is the point of overclocking, and the X570 Aorus Master needed that extra 133 MHz data rate (for four DIMMs) simply to produce the same performance as the X570 Taichi. Some companies use more-conservative advanced memory settings than others to gain an advantage in clock numbers, but the identical performance number puts both boards on par.

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Benchmark Results and Final Analysis

We updated our most-recent X470 test system to support AMD’s latest hardware with Microsoft’s latest Windows 10 patches. The hardware gets a small update too, to Gigabyte’s GeForce RTX 2070 Gaming OC 8G. Also, since XMP memory mode has no effect on AMD’s frequency management, we’ve enabled it.

Synthetic Benchmarks

Both X570 boards edged out the elder X470 in 3DMark Firestrike Extreme, but the X570 Taichi stood out by also beating both generations of Gigabyte board in PCMark’s MS Office bench.

3D Games

After getting replaced in our graphics test, the F1 series returns to motherboard testing due to its ability to single out poor memory performance. Today’s boards are on a level field there, though the X470 model fell behind in Ashes of the Singularity.

Mixed Apps

We switched to the integrated benchmark for 7-Zip, and that meant getting a performance score rather than a compression time. It breaks out of the timed applications chart, but none of the tested boards broke out of the pack in this benchmark.

Nothing looked unusual in the timed tests either, where the winning and losing scores were too close to raise any concerns about software or firmware configuration.

Power, Heat and Efficiency

Finally, a test that really stands out! ASRock’s X570 Taichi consumed far more power at full load, and a quick search for the cause revealed that this board, and only this board, was running the 3700X at 1.31V and 4.1GHz under Prime95 small-FFTs. The other boards were running less than 1.2V, at 3.9 to 4.0 GHz in this test.

Just to prove that the voltage reading wasn’t a mistake, the X570 Taichi pushed our CPU core temperature to 81 degrees Celsius in a 22-degrees ambient room. At least its voltage regulator kept its cool.

A quick look at our calculations also shows which test suites were used for our overall performance, efficiency, and value calculations. The X570 Taichi’s improved performance in PCMark’s Productivity test provide most of its 0.7% over-average advantage.

Slight performance advantages aside, the Taichi’s terrible power numbers destroy its image in our power-to-performance comparison. And that’s an average of best (idle) and worst (full load) power readings, not simply an effort to highlight the worst of its traits.

Final Thoughts

PCIe 4.0 is the main reason to buy an X570 board over its X470 predecessor, yet we’re not loading the PCIe bus heavily enough to show the benefit in our standard battery of tests. That capability is something to keep in mind if you own a bunch of storage and would like to upgrade it all to the faster standard.

That the X470 is a better value for people who don’t need the extra PCIe bandwidth explains why AMD told us that the older chipset will stick around well beyond the new one taking center stage. Yet those who need the bandwidth can easily justify the X570’s approximate $40 premium. The value analysis problem for the X570 Taichi is that it costs far more than the X570’s general price premium. We’re looking at a $70 difference in list price and a $90 difference when considering current discounts on older models.

If $40 is the cost of supporting the newer chipset, where does the other $30 go? A chunk of it certainly goes towards the upgraded 802.11ax Wi-Fi controller, and another chunk to the upgraded voltage regulator. But we have a feeling that a small chunk is going for that full-lower-half motherboard shroud that requires every card to be pulled and for the owner to find a 2mm hex key driver every time an M.2 drive has to be swapped.

And then there’s the fan whine, which isn’t loud but can certainly be annoying after what seems like endless hours of use. Buyers must also wonder how much they're paying for that aluminum plate that’s mounted to the back of the board, only to be obscured and made redundant by the motherboard tray. Back covers such as the X570 Taichi’s are certain to be appreciated by people who test boards for a living, but there's no practical function for end users.

Apart from the value premise that buyers will be paying for the inconvenience of removing so large a top cover to access any M.2 slots and likewise paying for a beautiful rear shield that they’ll never see, the X570 Taichi is a great board. The PCH fan speed can be turned down to reduce noise, or the board can be placed in a case that does a good job of containing the fan whine. Overall though, we’d rather pay a a little less for a board without unnecessary covers and in turn have easy access to our M.2 slots.

Image Credits: Tom's Hardware

MORE: Best Motherboards

MORE: How To Choose A Motherboard

MORE: All Motherboard Content

Asus Unveils 27-Inch QHD Gaming Monitor With 165 Hz Refresh Rate

Joe Shields — Mon, 25 Mar 2019 15:22:01 +0000

Asus has announced a new monitor to update their gaming lineup with the ROG Swift PG278QE. The 27-inch monitor has QHD resolution (2560x1440), a fast 165 Hz refresh rate and supports G-Sync. Asus markets the panel towards the professional esports gaming arena.

(Image credit: Asus)

Though Asus hasn't confirmed it, we expect the new monitor to replace the popular PG278QR released in 2016 by also delivering a twisted nematic (TN) panel. More TN evidence comes from its viewing angles (170 degrees H/160 degrees V), which is typical of a TN. The monitor has a 1,000:1 contrast ratio with a peak brightness of 350 cd/m², a 1ms GTG response time and a thin 6 mm bezel.

For inputs, the PG278QE consists of one HDMI 1.4 and DisplayPort 1.2. In order to reach a 165 Hz refresh rate, you have to use the DisplayPort. In addition to the video inputs, there is also a 3.5mm earphone jack and two USB 3.0 ports.

(Image credit: Asus)

Mechanically, the matte black panel has tilt, swivel and pivot functionality, along with height adjustment. The monitor can tilt forward 33 degrees and backwards five degrees with 90-degree swivel both ways and height adjustment from 0-130 mm. Those are all values an improvement over the PG278QR.

The monitor also includes GamePlus shortcuts (Crosshair, Timer, FPS Counter, Display Alignment), GameVisual display modes (Scenery, Racing, Cinema, RTS, RPG, FPS, sRGB, user), along with ULMB (ultra-low motion blur) support.

Asus ROG Swift PG278QE Gaming Monitor Specifications

Resolution and Refresh Rate	2560x1440 (QHD) @ 165 Hz
Max Brightness	350 nits
Response Time (GTG)	1ms
Refresh Rate	165 Hz
I/O	HDMI 1.4DisplayPort 1.23.5 mm earphone2x USB 3.0
Stand	Tilt: +33°/-5°Swivel: +90°~-90°Height: 0-130 mm

Asus did not reveal pricing and availability, but we expect to see the ROG Swift PG278QE soon and priced right around where the last generation PG278QR's original MSRP, $699, as there seems to be few changes between it and its predecessor.

MSI Optix MAG341CQ Curved Ultra-Wide Gaming Monitor Review: A Price Breakthrough

Christian Eberle — Sat, 05 Jan 2019 16:00:00 +0000

Features and Specifications

In a few short years, curved ultra-wide monitors have become a fixture in gaming. What started out as an answer to a question no one asked quickly turned into a must-have. With their 21:9-aspect screens, they heighten the sense of immersion and pull players into a gaming environment in a way no 16:9 monitor can.

The one sticking point for potential buyers is their cost, which is likely $200 more than a 16:9 display with similar features. But relief is in sight with the MSI Optix MAG341CQ. For $480 at the time of writing (£380), you get 3440x1440 resolution with 8-bit color, a wide gamut, FreeSync and a 100Hz refresh rate. It’s a great way to dip your toe into the ultra-wide waters without spending a fortune.

Specifications

Brand & Model	MSI Optix MAG341CQ
Panel Type / Backlight	VA / WLED, edge array
Screen Size / Aspect Ratio	34 inches / 21:9Curve Radius: 1800mm
Max Resolution & Refresh	3440x1440 @ 100HzFreeSync: 48-100HzDensity: 109ppi
Native Color Depth / Gamut	8-bit / sRGB+
Response Time (GTG)	5ms
Brightness	250 nits
Contrast	3,000:1
Speakers	✗
Video Inputs	1x DisplayPort 1.22x HDMI 2.0
Audio	✗
USB	✗
Power Consumption	53.5w, brightness @ 160 nits
Panel Dimensions(WxHxD w/base)	32.2 x 17.8 x 7.8 inches818 x 452 x 198mm
Panel Thickness	4.5 inches / 114mm
Bezel Width	Top/sides: 0.5 inch / 13mmBottom: 0.8 inch / 20mm
Weight	15.7lbs / 7.1kg
Warranty	Three years

The MAG341CQ offers nearly everything a gamer might need but does omit a few items in pursuit of value. The stand is fixed and only allows a tilt adjustment. There is no sRGB option. The refresh rate is a 100Hz despite many of the latest ultra-wides support 120 and 144Hz. There’s FreeSync, but since its operating range is 48-100Hz, there is no low framerate compensation (LFC), which might be an issue for owners of older video cards. There’s also no blur reduction and few image modes.

But you do get a nice VA panel with roughly double the contrast of an IPS or TN screen. Plus, you get a 100Hz refresh rate without overclocking, and the 109ppi pixel density is suitable for any task and allows Windows to run at 100 percent dpi scaling. That means text will be at its sharpest and graphic detail at its finest.

Unpacking & Accessories

Assembly of the base, upright and panel requires a Phillips-head screwdriver. The base’s captive bolt doesn’t have one of those little handles on it, which is a minor annoyance. The panel locks in place with two provided bolts. They are then covered by a small bit of plastic. The power supply is internal, unusual for an ultra-wide, so you get an IEC cord. Video is supported by HDMI and DisplayPort cables. The user manual comes in printed (another rarity).

Product 360

The MAG341CQ has more understated styling than most gaming monitors. Rather than molded features or lighting effects, it announces its intentions with a red upright and nothing else. This makes it more versatile, and since it also serves well as a workday display, the lack of look-at-me aesthetics is a plus. The curve is relatively tight at 1800R, which is the point where the image wraps around nicely but doesn’t distort. You can sit a comfortable 30-40 inches away and have your peripheral vision filled with sharp picture free of pixelation, thanks to the 109ppi pixel density.

The bezels don’t pretend to be slim; they’re a solid half-inch with a wider strip across the bottom. A tiny blue dot that’s barely visible, even in the dark, represents the power LED. On-screen display (OSD) controls consist of small buttons on the bottom right that are fairly hard to click. In fact, their small size and strong resistance caused me a bit of irritation during the calibration process. They are, at least, precise.

The back of the panel is completely smooth, broken only by a polished MSI logo. Interestingly, the dragon shield shown in the photo is not present on our sample. Even the box art shows the graphic, but we didn’t get one. Perforations on the top and bottom edges provide ventilation. The internal power supply takes quite a few minutes to warm up, during which time the panel clicks softly. Once up to temperature, the noise goes away.

Two features that wound up on the cutting-room floor are speakers and USB ports. You get neither with the MAG341CQ, nor is there a headphone jack. Inputs include one each of DisplayPort 1.2 and HDMI 2.0. You also get a DVI port, which is increasingly hard to find these days as that interface is rapidly disappearing from graphics cards.

The stand is super-solid but only includes 15-degrees backwards and 5-degrees forward tilts and no swivel or height adjustment. The upside is that the assembly is almost monolithic. This monitor will not wobble at all.

OSD Features

The OSD is styled for gaming with an info dashboard up top that shows input resolution, refresh rate, picture mode, FreeSync status and current input. There are five picture modes. User is the default and also allows white point and gamma adjustments. Sadly, there is no sRGB option. The MAG341CQ is an sRGB+ screen, which means its color primaries fall somewhere between sRGB and DCI-P3 (we’ll get into the details of its color-rendering on page three).

Navigating the OSD is a chore, thanks to the aforementioned stiff and tiny buttons. We’d have loved a joystick or at least buttons that don’t hurt to press. Like most monitors, once set up, you won’t have to visit the menu often. The Eye Saver mode offers low blue light, which MSI calls “Less Blue Light.” Like every display with that feature, it warms up the color temp to make reading easier on the eyes. Note, you won’t want to use it for gaming as it will flatten the image considerably.

Gaming features include a FreeSync toggle, 12 different aiming points for first-person shooter newbies and an overdrive setting that is either on or off and offers adequate blur reduction without ghosting.

Image controls include two gamma settings and two color temp presets, plus a user mode. The RGB sliders start center-range, but their adjustments are coarse and achieving precise color is difficult.

Setup and Calibration

The MAG341CQ ships in User mode, which offers below-average accuracy with a light gamma curve and whites that look distinctly green. If you do nothing else, set the gamma from 1.8 to 2.2. It will improve image depth significantly. Calibration was challenging because the RGB sliders do not have fine resolution; each click makes a large difference in color. But after a bit of back and forth, we managed a decent gain in quality with the greatest improvement being gamut saturation. We strongly recommend using our settings below to get the most out of your MAG341CQ:

MSI Optix MAG341CQ Calibration Settings
Picture Mode	User
Brightness 160 nits	100
Brightness 120 nits	61
Brightness 100 nits	145
Brightness 80 nits	30
Brightness 50 nits	10
Contrast	48
Gamma	2.2
Color Temp User	Red 52, Green 48, Blue 44

Gaming & Hands-on

The MAG341CQ is great for general computing, like web browsing, document editing and spreadsheets. It even makes a decent display for Photoshop, though it won’t provide reference color accuracy. The image is very sharp and clear with no artifacts from the anti-glare layer. We appreciated the ability to run Windows 10 at 100 percent dpi scaling, which provides the clearest possible image.

Gaming on the MAG341CQ was a good experience both with and without FreeSync. If you have a speedy graphics card, you won’t miss FreeSync if framerates stay in the 90-100 frames per second (fps) range. But for owners of slower graphics cards, FreeSync worked without issue. The overdrive also had no problems reducing motion blur without visible ghosting.

We really enjoyed the extra color and contrast afforded by the wide-gamut, VA panel. Though some color inaccuracies crept up during testing, it didn’t diminish the gaming experience. VA’s greater dynamic range is always an asset, and contrast is the most important element of good imaging. Color errors can be overlooked when they’re not too far off the mark and contrast is as deep as what we saw with the MAG341CQ.

Our only caveat is that if you buy the MAG341CQ, you should have a PC capable of maintaining framerates over 48 fps. With no LFC, there will be some tearing when the monitor renders below that speed. Since the MAG341CQ sports 3440x1440 resolution, you’ll need a mid-grade video card at least. And of course, if you can run closer to 100 fps, there won’t be any artifacts to spoil the fun.

MORE: Best Gaming Monitors

MORE: How We Test Monitors

MORE: All Monitor Content

Brightness and Contrast

To read about our monitor tests in-depth, check out Display Testing Explained: How We Test Monitors and TVs. We cover Brightness and Contrast testing on page two.

AOC Agon AG352UCG6

BenQ EX3501R

Monoprice 33822

Uncalibrated – Maximum Backlight Level

For comparison, we brought in a group of VA panels. On the 16:9 side is MSI’s Optix MPG27CQ and Monoprice’s 33822. Ultra-wides include BenQ’s EX3501R, AOC’s Agon AG352UCG6 and the mega-wide Samsung C49HG90.

The MAG341CQ is rated at 250 nits but our sample only managed 213.6 at maximum brightness settings. But that’s not a deal-breaker as that is more than enough light for the average indoor space; although, you should avoid bright, sunny windows. We’d like to see at least 300 nits to provide some headroom for calibration, which can reduce peak output.

Black levels were VA-dark with our review monitor earning first place. This is precisely the reason for buying a VA panel and why they’re our favorite for entertainment. That extra depth is easy to see and really enhances gaming and video content. Resulting contrast is mid-pack in our group and about average for VA screens as a whole.

After Calibration to 200 nits

After calibration, the MAG341CQ’s black level didn’t notably change, but peak white dropped to 163 nits with the brightness slider maxed. Again, this was enough light for most indoor environments, but there was no headroom left.

We had to reduce contrast a bit to fix a gamma issue, and our changes to the RGB sliders cost us some dynamic range. 1,881.7:1 is still a respectable contrast ratio, but all the other screens here fared better, except for the AOC. In the ANSI contrast test, the MAG341CQ moved up a spot with a solid 1,660.8:1 score. While that wasn’t enough to win in this group, it’s significantly better than any IPS monitor short of a full-array backlight model.

MORE: Best Gaming Monitors

MORE: How We Test Monitors

MORE: All Monitor Content

Grayscale, Gamma and Color

The MAG341CQ is an sRGB+ monitor, meaning its color gamut falls between the sRGB and DCI-P3 specs. Unfortunately, it doesn’t have an option for sRGB, but you might prefer the extra color saturation if you’re willing to accept lower accuracy.

Grayscale & Gamma Tracking

We describe our grayscale and gamma tests in detail here.

The MAG341CQ’s grayscale errors aren’t grievous, but the green tint in most brightness levels was visible to the naked eye. Green errors were easiest to see, thanks to human eyesight naturally favoring that primary color.

Another issue is gamma tracking, which is very light. The default setting is 1.8, which makes no sense for any content we’re aware of. The first chart above reflects the Warm color temp preset.

Adjusting the RGB sliders in the Custom color temp mode (second graph) offered a visible improvement. We couldn’t eliminate the red errors at 60 and 70 percent, but they were difficult to see in actual content. Changing the gamma preset to 2.2 and lowering contrast two clicks restored most of the lost image depth as well. We’re not happy with the dip at 90 percent, but this chart is a vast improvement over the default one.

Comparisons

With calibration to 200 nits, the grayscale error dropped from 5.23 to 2.31dE, not only improved perceived contrast, but also helped color gamut accuracy. Adjusting the white point made secondary colors fall into line.

Our gamma tweak also had a positive impact on color and contrast, but there was still room for improvement. Our MAG341CQ sample could only muster an average gamma value of 2.03, mainly due to the dip at 90 percent shown in the calibrated grayscale and gamma tracking chart. And its range of values is a bit wider than all but the MPG27CQ.

Color Gamut Accuracy

For details on our color gamut testing and volume calculations, click here.

MSI has taken an interesting approach to color reproduction with the MAG341CQ. While it’s nearly a DCI-P3 monitor, the inner saturation points (20-80 percent) come closer to the sRGB spec. That’s a good thing because most content will look natural and reasonably accurate. Only the outermost points (100 percent) are significantly oversaturated. Bright images will show vivid color, which many will prefer. Our issue with the default result is that the targets are inconsistent—some points are undersaturated while others are over.

Calibration tightened up the tracking quite a bit, with all points becoming a bit oversaturated. While this isn’t ideal, it is more consistent and therefore makes all content look better. This is the main reason to make the adjustments recommended on page 1. Grayscale calibration is the key to good color tracking. We’ve made some positive improvements here.

Comparisons

Even with calibration, the MAG341CQ lagged behind all the other monitors in color accuracy. While an average error of 3dE isn’t bad, the other screens did better. An sRGB option would have been a step in the right direction. In the past, we might have said these were good results for a gaming monitor. But in today’s market, few screens stray far from the proper specs. MSI might consider a firmware update to fix these issues.

As an extended color display, the MAG341CQ performed well. Those looking for the largest possible gamut volume will find it among the more colorful at this price point. Out of comparison group, only the MPG27CQ showed greater sRGB volume. And rendering nearly 80 percent of DCI-P3 is a plus. Note, if you need to use it for color-critical applications, a custom monitor profile is a must.

MORE: Best Gaming Monitors

MORE: How We Test Monitors

MORE: All Monitor Content

Viewing Angles, Uniformity, Response and Lag

VA panels are not known for stellar off-axis image quality, but the MAG341CQ looks better than most. From the sides, color tended slightly towards red with a light reduction of about 40 percent. Detail stayed solid, so users gaming on multiple screens will be able to see their enemy at a glance no matter where they approach from. When looking down from the top, detail lost definition, and the color was somewhat reddish. While an IPS screen would perform better in this test, the Optix beats many of the VA panels we’ve photographed.

Screen Uniformity

To learn how we measure screen uniformity, click here.

The screen uniformity of our MAG341CQ was a bit disappointing. We could see the black field get brighter towards the bottom where the backlight is situated. 15.01 percent isn’t a bad score, but it is higher than the other monitors. Note that the results here will vary among different MAG341CQ samples. In our case, the hot zones transitioned smoothly from the dark zones, so there were no obvious blotches or glowing edges. The issue was hard to see in most real-world content.[1] [2]

Pixel Response & Input Lag

Click here to read up on our pixel response and input lag testing procedures.

The MAG341CQ’s most impressive trait is speed. Though it runs at 100Hz, it managed to beat the Monoprice 33822, which hits 144Hz. It also traded punches with the 120Hz AG352UCG6. Motion blur was nearly non-existent, especially when in-game framerates were near 100fps.

Input lag is also a non-factor with only a 37ms delay. While users might gravitate towards 120 and 144Hz monitors, this one makes the most of its 100Hz rating. That’s one of the reasons for its low price, and obviously, there is no sacrifice in performance.

MORE: Best Gaming Monitors

MORE: How We Test Monitors

MORE: All Monitor Content

Conclusion

At this writing, the MSI Optix MAG341CQ is the least expensive 34-inch WQHD resolution ultra-wide, 100Hz, FreeSync gaming monitor currently available. That it delivers solid gameplay with good contrast and vivid color is simply icing on the cake. While a few features have been left out, this screen provides solid performance for gaming, video and general computing.

The downside is there are some grayscale and gamma accuracy issues.We wish we could have achieved a better grayscale calibration, and the monitor should have a darker gamma curve. And users looking for speakers, USB, or a headphone jack will have to search elsewhere because the MAG341CQ doesn’t have any. But this seems a worthy sacrifice to keep the price down.

Gaming performance is without fault. Though there are faster ultra-wide gaming monitors out there, like the Samsung C49HG90, the MAG341CQ makes the most of its 100Hz and even manages to match response and lag times with the 120Hz AOC AG352UCG6. Though there are no blur-reduction modes or overdrive levels (it’s either on or off), we enjoyed smooth play with instant response to control inputs and tear-free motion processing.

You can spend a lot more for an ultra-wide gaming monitor but if you’re willing to give up a few features, the MSI Optix MAG341CQ fills the bill at an attractive price.

MORE: Best Gaming Monitors

MORE: How We Test Monitors

MORE: All Monitor Content

PowerColor Red Devil RX Vega 64 8GB HBM2 Review: Cooling Vega Right

Igor Wallossek — Mon, 04 Jun 2018 13:00:00 +0000

Features & Specifications

If you asked us to point you in the direction of a well-equipped Radeon RX Vega 64 card, and if there was more differentiation between the boards that do exist today, we could definitely recommend checking out PowerColor's Red Devil RX Vega 64 8GB HBM2. Like Sapphire's Radeon RX Vega 64 Nitro+, the PowerColor card is particularly eye-catching. And it lights up, if you're a proponent of drawing attention to flagship-class graphics hardware in a windowed case.

Unfortunately, today's market makes it almost impossible to distinguish between one Radeon RX Vega 64 or another. You may find a handful of models in stock (an improvement compared to a few weeks ago), but they still start just under $800 and reach as high as $900. While PowerColor does land toward the bottom of that range, you're still paying a $200+ premium over many GeForce GTX 1080 models. Right out of the gate, PowerColor is fighting an uphill battle against less expensive and sometimes faster competition.

Unboxing, Look, & Feel

Weighing in at 1409 grams, this card lands just below Sapphire's monstrous flagship, which proved to be a an exhibition of sorts and is no longer available. PowerColor's solution is real though, and it's a massive beast just like Asus' ROG Strix Radeon RX Vega 64 8GB OC Edition. Similar to that card, the Red Devil measures 30.2cm long. A height of 12.7cm from the motherboard slot's top edge to the top of the fan shroud also matches what you get from Asus. But a depth of 5.2cm is notably wider. Hopefully that translates to even better cooling performance.

Three 90mm fans are mounted in 92mm openings. With their special shape, a total of nine blades per fan provide powerful throughput and less turbulence, generating a bit more static pressure. This should prove complementary to the deep thermal solution.

The backplate is characterized by a printed Red Devil logo. That plate doesn't help with cooling at all; it's primarily meant to look good and give the heavy card some rigidity.

Plan for an extra 5mm of clearance (at least) behind the Red Devil RX Vega 64. This may cause problems on some motherboards, particularly if the heat sink/backplate intrude on an occupied expansion slot or large CPU cooler.

As we can see from the bottom, PowerColor employs vertically-oriented fins. At the expense of occupying a third slot with its 2.5-slot design, the company does provide a lot more surface area for cooling.

The top side shows that PowerColor stays true to itself in the Red Devil's design. In addition to a familiar dark metal cover on the red ABS shell, there is an illuminated Red Devil logo in the middle. A pair of eight-pin power connectors are position at the end of the board. They're rotated 180 degrees and recessed as well.

Apart from three 6mm heat pipes and a single 8mm pipe, the almost completely closed back of the card reveals nothing conspicuous.

The rear bracket plays host to four display outputs. A pair of HDMI 2.0 interfaces is ideal for anyone with a VR HMD, while two DisplayPort 1.4 connectors make multi-monitor configurations easy. DVI is noticeably missing.

Unfortunately, we also have to bring up an issue that affected our test results. While our press sample was sealed by the manufacturer, it became clear that this card had been used and dismantled before landing in our lab. The amount of thermal paste we found on the GPU package would have been sufficient for two or more cards, and was nearly counterproductive the way it arrived. We fixed this by cleaning the card and applying much better stuff in moderation.

We realigned the heat pads, and even repaired the partially destroyed ones with similar replacements. In turn, we were rewarded with a four to five degree lower GPU temperature and significantly cooler VRM readings. Hopefully, that gets us close to PowerColor's stock performance, fresh from the factory.

Although PowerColor's official documentation claims a 1607 MHz boost clock, GPU-Z reports 1630 MHz. That specification is mostly wishful thinking though, given the Red Devil's power limit.

In comparison to the relevant reference cards the data looks as follows:

Model	Radeon RX Vega 64	PowerColor Red Devil RX Vega 64	Radeon RX Vega 56	GeForce GTX 1070 Ti	GeForce GTX 1080
GPU	Vega 10	Vega 10	Vega 10	GP104	GP104
Die Size	486 mm²	486 mm²	486 mm²	314 mm²	314 mm²
Transistors	12.5 billion	12.5 billion	12.5 billion	7.2 billion	7.2 billion
Base/Boost Clock Rate	1274/1546 MHz	1274/1630 MHz	1156/1471 MHz	1607/1683 MHz	1607/1733 MHz
Shaders/SIMDs	4096/64	4096/64	3584/56	2432/19	2560/20
Texture Units/ROPS	256/64	256/64	224/64	152/64	160/64
Pixel Fill Rate	99 GPix/s	104 GPix/s	94 GPix/s	108 GPix/s	114 GPix/s
Texture Fill Rate	396 GT/s	417 GT/s	330 GT/s	244 GT/s	257.1 GT/s
Memory Interface	2048-bit	2048-bit	2048-bit	256-bit	256-bit
Memory Type	HBM2	HBM2	HBM2	GDDR5	GDDR5X
Memory Bandwidth	484 GB/s	484 GB/s	410 GB/s	256 GB/s	320 GB/s
Memory Speed	1.89 Gb/s	1.89 Gb/s	1.6 Gb/s	8 Gb/s	10 Gb/s
Memory Size	8GB	8GB	8GB	8GB	8GB
DX12 Feature Level	12_1	12_1	12_1	12_1	12_1
PCIe Power Connectors	2x 8-Pin	2x 8-Pin	2x 8-Pin	1x 8-Pin	1x 8-Pin
TDP	295W	295W	210W	180W	180W

Test System & Measurement Methods

We introduced our new test system and methodology in How We Test Graphics Cards. If you'd like more detail about our general approach, check that piece out. We've upgraded the CPU and the cooling system since then to make sure that nothing's holding back graphics cards as fast as this one.

The hardware used in our lab includes:

Test System
Hardware	Intel Core i7-6900K @ 4.3 GHzMSI X99S XPower Gaming TitaniumCorsair Vengeance DDR4-32001x 1TB Toshiba OCZ RD400 (M.2, System SSD)2x 960GB Toshiba OCZ TR150 (Storage, Images)be quiet Dark Power Pro 11, 850W PSUWindows 10 Pro (All Updates)
Cooling	Alphacool Eisblock XPX5x be quiet! Silent Wings 3 PWM (Closed Case Simulation)Thermal Grizzly Kryonaut (Used when Switching Coolers)
Case	Lian Li PC-T70 with Extension Kit and ModsConfigurations: Open Benchtable, Closed Case
Monitor	Eizo EV3237-BK
Power Consumption Measurement	Contact-free DC Measurement at PCIe Slot (Using a Riser Card)Contact-free DC Measurement at External Auxiliary Power Supply CableDirect Voltage Measurement at Power Supply2 x Rohde & Schwarz HMO 3054, 500 MHz Digital Multi-Channel Oscilloscope with Storage Function4 x Rohde & Schwarz HZO50 Current Probe (1mA - 30A, 100 kHz, DC)4 x Rohde & Schwarz HZ355 (10:1 Probes, 500 MHz) 1 x Rohde & Schwarz HMC 8012 Digital Multimeter with Storage Function
Thermal Measurement	1 x Optris PI640 80 Hz Infrared Camera + PI Connect Real-Time Infrared Monitoring and Recording
Noise Measurement	NTI Audio M2211 (with Calibration File, Low Cut at 50Hz) Steinberg UR12 (with Phantom Power for Microphones) Creative X7, Smaart v.7 Custom-Made Proprietary Measurement Chamber, 3.5 x 1.8 x 2.2m (L x D x H) Perpendicular to Center of Noise Source(s), Measurement Distance of 50cm Noise Level in dB(A) (Slow), Real-time Frequency Analyzer (RTA) Graphical Frequency Spectrum of Noise

Specifications

GPU (Code-name)	Vega 10
Shader Units	4096
Base & Boost Clocks	1630 MHz
Memory Size & Type	8GB HBM2
Memory Clock	1.89 Gb/s
Memory Bandwidth	484 GB/s
Fans	(3) 90mm
Ports	(2) HDMI 2.0, (2) DisplayPort 1.4
Power Connectors	(2) 8-pin PCIe
Dimensions (LxHxD)	30.2 x 12.7 x 5.2cm
Weight	1409g
Warranty	2 Years

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Board & Power Supply

Board Layout

PowerColor's layout may seem a little different from AMD's reference PCB at first glance. However, the most important areas carry over almost 1:1. The second BIOS, lighting connector, and switches cause the board to be extended upwards a bit.

This implementation employs six power phases with doubling, resulting in 12 voltage converters for the VDDC and one phase for the memory (MVDD), just like AMD. In terms of components, PowerColor mostly mimics the AMD design.

The sources of other auxiliary voltages are also visible in our layout diagram.

Aside from the densely populated area opposite the GPU package, we also find the PWM controller, phase doublers, and SMD capacitors on the board's back side.

PowerColor employs a pair of eight-pin connectors to complement the PCIe slot's power delivery. Since our measurements show the motherboard slot only feeding this card 23-26W, those two connectors handle the rest.

GPU Power Supply (VDDC)

As with AMD's reference design, the focus is on International Rectifier's IR35217, a dual-output multi-phase controller that provides six phases for the GPU and an additional phase for the memory. But again, there are 12 regulator circuits, not just six. This is a result of doubling, allowing the load from each phase to be distributed between two regulator circuits.

A total of six International Rectifier IR3598 multipliers on the back of the board are used to double the controller's phase count. Our infrared thermal measurements make it easy to see how the PWM controller shifts load back and forth between individual phases at idle to maximize efficiency, but also avoid overloading any one specific circuit.

Voltage conversion of the 12 circuits is performed by an International Rectifier IRF6811 on the high side and an IRF6894 on the low side, which also contains the required Schottky diode.

For the resonant filters in the VDDC, PowerColor relies on 190nH encapsulated ferrite coils, similar to AMD's reference card. The capping of extreme spikes on both external 12V supply connections is achieved through generous 560nH coils.

Memory Power Supply (MVDD)

As mentioned, the memory's power is controlled by International Rectifier's IR35217 as well. One phase is fully sufficient for this card, as its HBM2 is less demanding. A CHL815 gate driver is placed on the board's back, while a NTMFD4C85N dual N-channel MOSFET on the front is used for voltage regulation. The co-packaged solution includes both high and low sides.

It’s interesting that PowerColor uses SMD capacitors instead of can caps. Their somewhat lower capacity is compensated for by simply running two of them in parallel on the back of the board. It does make sense to spread the hot-spots and make the thermal solution's job a little easier. Waste heat is kept to a minimum, as is the cost associated with cooling.

At 220nH, the coils are a bit larger this time around. The ones corresponding to the "partial voltage" converters, which operate at a much lower frequency, are even larger at 820nH. They don’t have to deal with the same amounts of power, though.

Additional Voltage Converters

Creating the VDDCI isn’t a very difficult task. But it's an important one since this regulates the transition between the internal GPU and memory signal levels. It’s essentially the I/O bus voltage between the GPU and memory. A constant source for 0.9V is generated as well, along with a 1.8V source (TTL, GPU GPIO). These three voltage converters are equipped almost identically, relying on an MPS MPQ8633 synchronous step-down converter.

Underneath the GPU, there’s an Anpec APL5620 low drop-out linear regulator, which provides the very low voltage for the phase locked loop (PLL) area.

PowerColor places a switch up top to control its dual-BIOS functionality. The second chip is placed right next to that switch in the PCB's extended upper area.

ON Semiconductor's MC74HC238A demultiplexer drives the LED bar that shows the power supply’s load. It’s a fun gimmick, but does get annoying in a dark room at night due to its brightness. Fortunately, there's another switch you can use to turn the lights off entirely.

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Gaming Benchmarks At 2560x1440

We benchmark the Red Devil RX Vega 64 with its standard BIOS; the overclocked firmware yields a completely insignificant performance increase through an almost senseless jump in power consumption. A bit of tweaking on Radeon RX Vega 64 does not change the card's competitive position against Nvidia's line-up. Where it does help, the difference isn't large enough to justify a louder and hotter card. Stick with PowerColor's default BIOS; it offers the best compromise of all.

Because we're guessing that most folks with a Radeon RX Vega 64 plan to game at 2560x1440, that's where we start our benchmarks.

PowerColor's Red Devil RX Vega 64 has a slight clock rate advantage over AMD's reference Radeon RX Vega 64, yielding a relatively minor lead in every benchmark.

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Gaming Benchmarks At 3840x2160

The story doesn't change much at 4K. PowerColor's version of the Vega 64 is consistently a little faster than AMD's implementation, while the Radeon RX Vega 64 trades blows with Nvidia's GeForce GTX 1080 more generally. Neither model is really suitable for max-quality gaming at 3840x2160, though. As a result, we dial back the detail settings to maintain playable frame rates.

The real advantages of PowerColor's card will have to be found elsewhere, hopefully in the cooling or noise sections. After all, those two aspects are where the reference board takes the most criticism.

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Power Consumption

Power Consumption at Different Loads

We measured about 283W during our gaming loop using the driver's Balanced power profile. That's about 3W more than AMD's reference model using its default BIOS. We're willing to accept the higher power consumption since PowerColor's performance is also better. Recent BIOS modifications, including an updated power table, seem to be working well. A 282W measurement in our stress test is also acceptable.

PowerColor's overclocked mode dials in a higher power limit, but doesn't affect the maximum clock rate by default. Even then, though, it exceeds the 320W mark. Worse, performance doesn't improve all that much. As a result, we decided not to get any more aggressive with our overclocking. Rather, we stuck with the driver's Balanced power profile for testing.

The corresponding voltages for our gaming workload and stress test at PowerColor's stock settings are plotted in the following graph:

Load On The Motherboard Slot

At a peak of 2.4A through our stress test, PowerColor's Red Devil RX Vega 64 falls significantly below the 5.5A ceiling defined by the PCI-SIG for a motherboard's 12V rail. A mere 2.3A during the gaming loop is even more conservative. Overall, balancing is well-implemented, and the motherboard slot hardly ever experiences serious loads.

Power Consumption In Detail

The graphs below plot detailed power consumption and current readings in order to illustrate our findings.

Naturally, peaks in power consumption are highest during gaming. But spikes of up to 360W are still acceptable, since they're far too brief to cause a problem.

The same goes for the corresponding current measurements:

In the BIOS' OC mode, we see power consumption explode compared to PowerColor's Standard configuration.

Of course, this applies to our current measurements, too.

During our stress test, the short-term peaks are significantly less pronounced (even if the power consumption is slightly higher than during gaming workloads).

Again, our current readings follow the graph rather closely and show no abnormalities.

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Temperatures, Clock Rates & Overclocking

Overclocking & Undervolting

Conventional overclocking through a higher power limit and more aggressive clock rate is a dead-end. Brute force just isn't the answer. Because PowerColor had to follow AMD's guidelines, this implementation is already running at its limit. Sure, you could dial in higher fan speeds to cool things down, creating more noise in the process, but who really wants that? As we explained in AMD RX Vega 64: The Tom's Hardware Liquid Cooled Edition, even with higher frequencies and brutal power adjustments, it is almost impossible to get Radeon RX Vega running much faster. Instead, undervolting can achieve far better results.

First and foremost, the use of a suitable utility like OverdriveNTool works wonders. As always, though, your results will also depend on the quality of your GPU. We can't generalize; you'll have to compare your improvements to ours.

Temperatures & Frequencies

We’re using the GPU temperature value exclusively because that's what our test sample’s telemetry reports. Of course, the hot-spot temperature is a lot higher. Why? You can read all about in Does Undervolting Improve Radeon RX Vega 64's Efficiency? On PowerColor's Red Devil RX Vega 64, those readings are up to 14°C higher.

The following table shows a comparison of start and end values for temperatures and GPU (boost) frequencies. Just keep in mind that these clock rates can be considerably higher in games with significantly lower loads. For example, Wolfenstein 2's indoor environments might push the card to 1.63 GHz, only to knock it way down once you step outside.

	Initial Value	Final Value
Open Test Bench
GPU Temperature	32°C	65°C
GPU Clock Rate	1523 MHz	1381 MHz
Ambient Temperature	22°C	22°C
Closed Case
GPU Temperature	34°C	64°C
GPU Clock Rate	1523 MHz	1375 MHz
Air Temperature in Case	24°C	47°C

Temperature vs. Frequency

To better illustrate our findings, we plotted temperatures and frequencies during our sample's 15-minute warm-up phase. It's particularly interesting that there's such a small thermal difference between open and closed cases.

Frequencies in the gaming loop are about 100 MHz higher than what we measured from AMD's reference card. This average increase of 11% only improves gaming performance by 6-8%, which isn't particularly impressive.

The results of our stress test look similar:

IR Image Analysis Of The Board's Back

To round out this section, we take a look at board temperatures across several different load levels. To keep the test setup as practical as possible, we removed the backplate for IR measurements (since it doesn't help with cooling anyway). Comparative before/after tests show no difference in temperature or cooling performance.

Gaming

This card has no problem in our Witcher 3 gaming loop. Measurements of 68°C behind the GPU package and 66°C at the voltage converters are actually cool compared to some of the Radeon RX Vega cards we've tested. Does the situation change at all in a closed case?

Not really, no. In a closed case, we measure one degree higher at the voltage converters, while the area behind AMD's GPU rises two degrees. This is enabled by faster-spinning fans, since PowerColor sets a fairly aggressive temperature target. We'll be paying close attention to what that does to noise output.

Stress Test

The stress test reflects slightly lower power consumption than our gaming benchmark. However, certain components (like the voltage converters) still get a little warmer. This is ultimately the result of a more constant load, which can be difficult to keep up with.

Again, the temperatures only rise one to two degrees moving from an open bench table to a closed case. Of course, the fan speeds needed to make this possible increase as well.

In the end, PowerColor's cooler proves itself to be incredibly effective. All of our thermal readings land within a very comfortable range.

Heating Up & Cooling Down

The last two pictures show where the heating starts and where the circuit board is cooled most effectively.

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Cooling & Noise

Cooling Solution & Backplate

By removing the cooler's shroud, we get a better look at its two shells: an outer one made of light metal and the inner one of red ABS. The fans are mounted to the plastic cover, but not acoustically decoupled.

Although PowerColor coats the inside of its backplate in black so that thermal energy can be absorbed more easily, there are also no large surfaces to cover sensitive areas of the board and hinder passive ventilation.

All of the real cooling happens up front, so there's nothing more to say about the Red Devil's back side.

Cooling System Overview
Type of Cooler	Air cooling
GPU Cooling	Nickel-plated copper heat sink
Cooling Fins	Aluminum, vertical alignmentNarrow configuration, not inclined
Heat Pipes	3x 6mm + 2x 8mm Nickel-plated copper composite material
VRM Cooling	Four phases via an extra VRM sink in the coolerThree phases via GPU sink
RAM Cooling	Cooling of HBM2 modules via heat pipe
Fans	3x 9cm fans (9.2cm opening), Nine bladesNo semi-passive fan control
Backplate	Blackened aluminumNo cooling function

In addition to the sink for some of the voltage converters, two 8mm and three 6mm pipes made of nickel-plated composite material are responsible for transporting thermal energy from the GPU to different parts of the finned cooler.

The GPU heat sink has a rather rough surface, yet performs its task at least as well as the polished plate on Asus' ROG Strix Radeon RX Vega 64.

Fan Curves & Noise

Despite PowerColor's claims to the contrary, our measurements show that there is no semi-passive fan mode. Like AMD, the company keeps its fans spinning continuously. A 33 to 34% PWM reading translates to 1100 to 1200 RPM with the GPU idling between 25-38°C. There doesn't seem to be an extra controller chip on the board that'd stop the fan below a certain threshold.

After a period of intensive cooling during the warm-up phase, PowerColor's fans slow down quite a bit as temperatures stabilize. It's also obvious that the card is acutely sensitive to operating in a closed case versus an open bench table. In order to keep thermals as constant as possible, the fans always spin quite a bit faster inside of a chassis, even after the temperature target is reached.

Little changes during our stress test. While the cooler and its three fans work well, they also have to move a lot more air over the sink in our closed case.

This card does have enough cooling headroom to dial the fans down a bit. You can even raise the temperature target to 70°C, allowing the volume-optimized thermal solution to operate more quietly.

Fan RPM & Noise Measurements
Fan RPM, Open Test Bench, Maximum	1861 RPM (Peak)
Fan RPM, Open Test Bench, Average	1496 RPM (Warmed up)
Fan RPM, Closed Case, Maximum	2561 RPM (Peak)
Fan RPM, Closed Case, Average	1617 RPM (Warmed up)
Noise (Air) Range	32.2 (Minimum) to 51.4 dB(A)
Noise (Air) Average	34.2 dB(A) (Warmed up, Open bench table)38.3 dB(A) (Warmed up, Closed case simulation)
Noise (Air) Idle	32.2 dB(A)
Noise Characteristics / Subjective Impressions	Low-frequency bearing noisesSome motor noises below 1 HzModerate air and turbulence noisesSlight voltage converter noises

The 34.2 dB(A) we measured in an open test bench is undoubtedly what other reviewers find so praiseworthy. However, if the fans are set to the speeds observed in a closed case, we blow right past 38 dB(A). Here's what that looks like in the form of a high-resolution frequency spectrum analysis:

With PowerColor's Red Devil RX Vega 64 installed, you'll want to pay close attention to airflow inside of your chassis. It's easier to exhaust waste heat with quiet case fans than to optimize the graphics card for a different target temperature. Or you could do both and win twice. At least that way you can keep noise output under 35 dB(A).

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content

Conclusion

With our review of PowerColor's Red Devil RX Vega 64 8GB HBM2 complete, it looks like we've tested every Radeon RX Vega 64 card available. There just aren't that many custom designs out there.

PowerColor modified AMD's reference card for its own purposes, adding a great cooler that lives up to the Red Devil reputation. Even if the company tuned this model for cooling performance and not acoustics, the outcome isn't obtrusive. If you want, you can bias the thermal solution to less noise by bumping its temperature target to 70°C or 75°C. You'll have to test this out of course. But if your board is louder than you'd like, it's at least good to know there are remedies.

The Red Devil RX Vega 64's performance is typical of other Radeon RX Vega 64 boards. It's also subject to the same voltage, power, and temperature limits. In other words, there isn't much room for overclocking unless you're willing to overwrite the BIOS with manual optimizations. PowerColor's OC mode is mostly theoretical in nature, just like AMD's own implementation. You might gain a bit of performance, but it comes at the expense of much noise, heat, and excess power consumption. The same disappointing news applies to all Radeon RX Vega-based cards equally.

In the end, PowerColor sends a heavyweight into battle that doesn't become overwhelmed, even under taxing workloads. Its performance is good. The noise is tolerable, even if there are quieter options. Fortunately, you're able to fiddle with software-based settings to make the Red Devil quieter, so long as a slightly higher operating temperature doesn't bother you.

Ultimately, PowerColor's solution hovers around the middle range of Radeon RX Vega 64 pricing, all without asking much in the way of compromise. In that context, this card is a solid choice. But even though it's generally faster than GeForce GTX 1080, Nvidia's closest competitor is currently available at a $200+ savings. We have a hard time recommending any Radeon RX Vega 64 with such a chasm between boards best suited to 2560x1440 gaming.

MORE: Best Graphics Cards

MORE: Desktop GPU Performance Hierarchy Table

MORE: All Graphics Content