The Samsung 970 EVO Plus (250GB, 1TB) NVMe SSD Review: 92-Layer 3D NAND
by Billy Tallis on January 22, 2019 10:00 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 QD1 burst random read performance of the Samsung 970 EVO Plus is an improvement over its predecessor, but not as large as was promised by the spec sheet. The Samsung drives are also still lagging far behind the fastest combinations of IMFT NAND and Silicon Motion controllers.
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 test of random read performance that also brings in some higher queue depths, the Samsung 970 EVO Plus is more competitive and comes out tied or ahead of last year's best. But not shown here are the preliminary results from our tests of SM2262EN drives (next in the review queue) which are substantially faster than the 970 EVO Plus.
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| Power Efficiency in MB/s/W | Average Power in W | ||||||||
The 970 EVO Plus uses more power during the random read test than any other drives in this bunch, leaving it with some of the worse efficiency scores despite the good performance.
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The random read performance of the 250GB 970 EVO Plus begins to fall behind the 1TB model as queue depths increase, and the smaller drive seems to be close to saturating by QD16. At QD32 the 250GB model's random read throughput is less than half that of the 1TB model. The 250GB 960 EVO delivered substantially higher random read performance at high queue depths than the small 970 EVO Plus manages.
The relatively high power consumption of the 970 EVO Plus is apparent when plotting its test results against the rest of the database. At lower queue depths it delivers speeds that are achievable by SATA SSDs but uses more power than almost all of them. Once the queue depth has increased sufficiently to take the 970 EVO Plus beyond the SATA limit, it still uses more power than most of the remaining competition.
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 970 EVO Plus takes a slight step backwards from its predecessor, leaving it far behind the best competitors, which are currently led by the Phison E12-based Corsair MP510, 67% faster than the 970 EVO Plus.
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.
When the longer random write test brings in some higher queue depths, the 1TB 970 EVO Plus regains a high-end standing but doesn't quite catch up to the WD Black SN750. The 250GB model is a bit further behind the lead thanks to the fast write cache of the ADATA SX8200, which performs identically to that of the related 1TB HP EX920.
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| Power Efficiency in MB/s/W | Average Power in W | ||||||||
The 970 EVO Plus improves upon the random write power efficiency of its predecessors and ranks very highly, but the WD Black SN750 provides 26% better performance per Watt on this test, and the ADATA SX8200 beats the 250GB 970 EVO Plus by 21%.
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The Samsung 970 EVO Plus reaches full random write speed by QD4 and is reasonably steady through the rest of the test. The 1TB model saturates at a slightly higher level than the WD Black SN750, but its overall score suffered due to the slower QD1 performance. The ADATA SX8200 that provides excellent low-QD random write performance at low capacities does run out of SLC cache for part of the test and drops below the 250GB 970 EVO Plus's performance level for a while before recovering.
Comparing the 970 EVO Plus against all the results in the database shows the 1TB drive starts out with QD1 performance just beyond the limit for SATA drives, and power requirements don't increase much as throughput climbs. At higher queue depths the 970 EVO Plus falls roughly in the middle of the normal power consumption range for high-end drives.
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kgardas - Friday, January 25, 2019 - link
Thanks for explanation! Actually makes sense indeed. This would also mean that if your workflow is read dominated and you are sensitive on latency than RAID1 of SATA drives may be faster than NVMe. At least if SATA/SAS chip is not a crap.ikjadoon - Tuesday, January 22, 2019 - link
Even a SATA SSD could pump 4 kB random read numbers up, but it'd require pricey SLC. MLC and TLC both have 2x to 4x slower page reads to register vs SLC.latency source: https://www.anandtech.com/show/6337/samsung-ssd-84...
Still, TLC 4 kB random has improved, but not by "leaps and bounds" like 4K write has. The 970 EVO Plus has 53% faster random 4kB reads (sustained) than the MX 500. And even a 960 PRO has 76% faster 4kB reads (sustained) than the MX500.
FWIW, random 4K read performance (both burst and sustained) doesn't benefit much of anything from parallelization. https://www.anandtech.com/bench/product/2229?vs=21... The 250 GB and 1 TB 960 EVO have identical 4K read performance, i.e. within 0.75%. Random 4K write and larger page sizes are about 2x faster on the 1 TB model, however.
Can't vouch for accuracy, but this answer sounds right: https://superuser.com/questions/1168014/nvme-ssd-w...
Alistair - Tuesday, January 22, 2019 - link
The performance is amazing, and I've been buying the 1TB SX8200 for $180 USD before tax. Nothing beats that still.Dark_wizzie - Tuesday, January 22, 2019 - link
1tb ex820 for $160 after tax and shipping beats it.palindrome - Tuesday, January 22, 2019 - link
You mean EX920 and it has been as low as $153 recently (before tax).gglaw - Tuesday, January 22, 2019 - link
Not too long ago it was $135 twice with the Ebay and Rakuten 15% coupons. $155 range seems almost every other week now and frequent enough I'd even consider it the typical selling price. (Very few people who follow tech would actually pay $180 for it). Can't beat this for consumer use with the small performance differences with current gen drives. When the EX950 and SX8200 Pro phase it out and drop to the same price points, they'll replace it as best consumer deals so I don't see the new Samsung or WD having a place in my line-up.If for some purpose I can find a use for something more expensive, it'd have to be the next gen 970 Pro (Plus?) if it's a major upgrade.
** A - R ** - Wednesday, January 23, 2019 - link
https://news.samsung.com/global/samsung-electronic...Billy, Specs in the official site mentions MLC, here I see it's TLC ! ?
Could You please verify it.
olafgarten - Wednesday, January 23, 2019 - link
It says 3 bit MLC, meaning TLC.mortenge - Wednesday, January 23, 2019 - link
Why do you bring Optain into the mix and not the 970 PRO, when all we care about is EVO vs PRO?alfatekpt - Wednesday, January 23, 2019 - link
The review should include 970 EVO 250GB numbers for comparison.