Comparing Two 1TB NVMe Drives with Same NAND, Same Controller: XPG SX8200 Pro vs HP EX950
by Billy Tallis on February 6, 2019 11:30 AM ESTRandom Read Performance
Our first test of random read performance uses very short bursts of operations issued one at a time with no queuing. The drives are given enough idle time between bursts to yield an overall duty cycle of 20%, so thermal throttling is impossible. Each burst consists of a total of 32MB of 4kB random reads, from a 16GB span of the disk. The total data read is 1GB.
The combination of Silicon Motion NVMe controllers and IMFT 64L 3D NAND continues to provide the best QD1 random read performance available from mainstream SSDs. The retail SM2262EN drives are slightly faster than the engineering sample we tested last year, which itself was an improvement. The top spot among the flash-based SSDs we have tested now belongs to the ADATA SX8200 Pro. The 1TB HP EX950 is slightly faster than the 2TB model.
Our sustained random read performance is similar to the random read test from our 2015 test suite: queue depths from 1 to 32 are tested, and the average performance and power efficiency across QD1, QD2 and QD4 are reported as the primary scores. Each queue depth is tested for one minute or 32GB of data transferred, whichever is shorter. After each queue depth is tested, the drive is given up to one minute to cool off so that the higher queue depths are unlikely to be affected by accumulated heat build-up. The individual read operations are again 4kB, and cover a 64GB span of the drive.
On the longer random read test that brings in some higher queue depths, the SM2262EN drives have a clear and substantial lead over the rest of the flash-based SSDs, including the SM2262-based EX920 and SX8200.
Power Efficiency in MB/s/W | Average Power in W |
The ADATA SX8200 Pro takes a clear lead in the efficiency rankings for the random read test, while the EX950 is tied with the WD Black SN750 and Toshiba XG6. The SX8200 Pro averages about 0.6 W lower power draw during this test than the EX950, which is the most power-hungry flash SSD in this bunch.
The 1TB SX8200 Pro and EX950 perform identically at each queue depth, but the SX8200 Pro has a persistent power draw advantage. The 2TB EX950 draws slightly more power and delivers slightly less performance across the entire tested range of queue depths. Compared to the rest of their competition, the SM2262EN drives maintain a lead in random read performance at every queue depth, and are very close to catching up with the Optane SSD by QD32.
The ADATA SX8200 Pro may be quite efficient for low queue depth random reads compared to other NVMe SSDs, but when graphed against our entire database of results, it is clear that plenty of SATA SSDs deliver better performance per Watt at low speeds, and at higher speeds and queue depths there are some NVMe SSDs that offer similar performance with lower power consumption.
Random Write Performance
Our test of random write burst performance is structured similarly to the random read burst test, but each burst is only 4MB and the total test length is 128MB. The 4kB random write operations are distributed over a 16GB span of the drive, and the operations are issued one at a time with no queuing.
The burst random write performance of the retail SM2262EN drives is a bit lower than we got from the engineering sample we tested last year. The Phison E12-based Corsair Force MP510 is a few percent faster than the ADATA SX8200 Pro, and the HP EX950 is a bit slower but still faster than most other brands.
As with the sustained random read test, our sustained 4kB random write test runs for up to one minute or 32GB per queue depth, covering a 64GB span of the drive and giving the drive up to 1 minute of idle time between queue depths to allow for write caches to be flushed and for the drive to cool down.
On the longer random write test that includes some higher queue depths, the SM2262EN drives stay near the top of the chart as the Corsair MP510 falls slightly behind and the WD Black SN750 and Samsung 970 EVO Plus catch up—but the overall spread among this top tier of drives is quite small. The 2TB HP EX950 is faster than the 1TB model but doesn't match the performance we got from the 2TB engineering sample.
Power Efficiency in MB/s/W | Average Power in W |
The power efficiency of the ADATA SX8200 Pro on the random write test is very close to the Toshiba XG6 and WD Black SN750, and those three drives are clearly more efficient than the rest of this bunch, including the HP EX950.
The WD Black SN750 and Samsung 970 EVO both start out a bit slower than the SM2262EN drives at QD1, but they reach full performance at QD4 while the SMI drives take a bit longer to saturate and aren't quite as fast at high queue depths.
The ADATA SX8200 Pro may not be able to quite match the fastest TLC drives for random write throughput, but across the entire range of tested queue depths it provides excellent power efficiency that few drives can match.
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Mikewind Dale - Wednesday, February 6, 2019 - link
That drop in performance for a full drive in the Heavy - and even the Light!! - tests is worrying. They're right around the level of a SATA SSD.My question is, how full is full? If you fill the drive up 99%, is its performance closer to empty or full? With all my SSDs, I typically leave about 10% of the drive unallocated (unpartitioned). How would the drive perform in this state?
I would be interested in seeing results for a drive that is almost full, but not quite full. I imagine that most people don't use their drives up until the final MB is used. Still, if a cost-conscious person is trying to get their money's worth, they might use the drive until it's 90-something percent full. Until recently, I was using a 512 GB SATA SSD with a real capacity of 476.8 GB. I used it until I was using 420 GB, at which point I upgraded to a 2 TB drive. So I was using 88% of its capacity. To me, that seems like a reasonable usage to test - not quite full, but almost full.
Targon - Wednesday, February 6, 2019 - link
I would suspect that the reason for this might be thermal throttle issues. Throw a heat sink on there, and the performance downgrade might disappear. The versions with a pre-installed heatsink might be worth the money, depending on how much it would cost to buy a SSD heatsink at this point(I haven't looked).BillyONeal - Wednesday, February 6, 2019 - link
Seems more likely to be reduction in the size of the SLC cache -- see the the filling the drive tests where there are 3 distinct phases depending on how much space is actually in use.jabber - Thursday, February 7, 2019 - link
I must admit I still leave a few GB spare/unallocated on any SSD I install. 2GB on a 120GB, 4GB on a 240GB and 8GB on a 500GB. Old habits.reactor_au - Thursday, June 13, 2019 - link
I was wondering the same thing, how full can one get before performance drops off the cliff like in the benchmarks? Its a very import detail to omit!Luckz - Friday, November 29, 2019 - link
At 80% full it was really tragic in this review of the 256GB size https://pclab.pl/art79361-9.htmlMikewind Dale - Wednesday, February 6, 2019 - link
I also notice that these drives don't have an active power state less than 3.8W. That's unfortunate, because as Ganesh T S noted in his Anandtech review of the MyDigitalSSD M2X M.2 NVMe SSD Enclosure, that enclosure will only work with SSDs that have an active power state less than 3.8W.I think this is important because it determines whether you can continue to use the SSD as a portable drive after you upgrade later. If you replace your 2 TB with a 4 or 8 TB SSD someday in the future, it will be nice to know that you can repurpose your 2 TB as an external drive.
Also, it determines whether you can easily upgrade your SSD when all your M.2 slots are full. Whenever I upgrade a SATA boot drive, I typically use an external USB enclosure to clone the current SATA drive (still installed internally) to the new SATA drive (inside the enclosure). Then I can swap the two drives, and my computer will transparently use the new drive. With M.2, this is even more important because many motherboards have only two M.2 sockets. So if you have both M.2 sockets filled and try to upgrade one of the M.2 drives, you'll have a bit of a challenge. You could buy a PCIe-M.2 card and use that, but using an external USB enclosure is more convenient.
So I'd like to see more M.2 drives with a sub-3.8 W active power state. The Samsung 970 EVO Plus has a 3.4 W active state, so it passes this test.
MrSpadge - Wednesday, February 6, 2019 - link
I love ADATA's naming scheme! It's so easily memorable and has more X's than any other brand.eddieobscurant - Wednesday, February 6, 2019 - link
Nice review , as always although I disagree with your conclusion. Peak performance is what most people want.Billy Tallis - Wednesday, February 6, 2019 - link
My reviews are intended to advise consumers who are buying SSDs to increase their productivity, not people who are trying to set a high score on Crystal Disk Mark.People who care about real-world productivity rather than CDM scores should recognize that imperceptible improvements to peak performance are probably not worth the sacrifice of significant regressions in performance on niche heavy workloads. For a lot of users, both SM2262 and SM2262EN drives are fast enough. Beyond those lighter use cases, I think it will be more common to find the SM2262EN coming up short in a meaningful way than to find it providing a tangible performance advantage over SM2262.