The Samsung 870 QVO (1TB & 4TB) SSD Review: QLC Refreshed
by Billy Tallis on June 30, 2020 11:40 AM ESTBurst IO Performance
Our burst IO tests run at a queue depth of one and the amount of data transferred is limited to ensure that SLC write buffers don't fill up and controllers don't overheat. In between each burst there's enough idle time to keep the drive averaging a 20% duty cycle, allowing for some buffered writes and deferred garbage collection to be completed. The random read and write tests use 4kB operations and the sequential tests use 128kB operations. All the burst tests are confined to a 16GB portion of the drive, so DRAMless SSDs are not disadvantaged as much as they are for larger tests.
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Sequential Read | Sequential Write |
The Samsung 870 QVOs show significant improvement to QD1 random read performance, with the 1TB model still outperforming the 4TB model. QLC still imposes a bit of a performance penalty relative to mainstream SATA drives, but the biggest difference on display here is naturally from the NVMe drive serving the reads entirely out of its huge SLC cache.
For random writes at QD1, the 870 QVO is a stark regression from its predecessor, which was on par with the TLC-based 860 EVO. The 870 QVO is now clearly slower than mainstream TLC SSDs and is barely faster than the slower DRAMless competitor.
Sequential reads and writes at QD1 both show slight improvements, but these drives are almost all simply bumping against the limits of the SATA interface.
Sustained IO Performance
Our sustained IO tests measure performance on queue depths up to 32, but the scores reported here are only the averages for the low queue depths (1,2,4) that are most representative of real-world consumer workloads. Each queue depth is tested for up to one minute or 32GB, and the tests are confined to a 64GB span of the drive.
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Sequential Read | Sequential Write |
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Sequential Read | Sequential Write |
The most notable performance changes the 870 QVO brings to the sustained IO tests are from the 1TB model, which has greatly improved both random and sequential write performance. However, this comes at the cost of reduced random read performance, which is also a weakness for the 4TB model.
Power efficiency from the 870 QVOs during the sustained IO tests ranges from poor to average. Samsung's controller and LPDDR4 help keep power draw in check, but ultimately it takes more energy to operate slower, more complicated QLC NAND.
Random Read | Random Write | ||||||||
Sequential Read | Sequential Write |
Looking at the big picture of the 870 QVO against all the other drives we've tested shows that the 870 QVO can reach the same top speeds as most SATA drives for three out of the four workload types. Random reads are the exception, where even high queue depths don't bring the 870 QVO up to the SATA limits during our sustained test, and the power draw is clearly on the high side there as well.
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Sequential Read | |||||||||
Sequential Write |
Compared to its predecessor, the 870 QVO brings slight improvements to random read performance, mainly at higher queue depths, while keeping power consumption almost unchanged. Random write performance has changed drastically for the 1TB QVO: the 1TB 870 is able to ramp up to much higher random write speeds, keeping pace with the 4TB model until the very end of the test when the smaller drive's cache finally runs out in spite of the idle time between phases of the test. The older 1TB 860 QVO's random write speed was constrained almost from the very beginning of the test. The 1TB 860 QVO also used to show a bit of fall-off in sequential read performance as the test reached higher capacities, and that behavior is gone with the 870 QVO. Sequential writes show a similarly drastic improvement for the 1TB 870 QVO, now able to generally keep pace with the larger model, which was not remotely the case for the previous generation.
Some of the big differences in write speed shown for the 1TB QVOs here may be an artifact of this test's size and duration, but even so it is clear that the smallest QV
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Guspaz - Tuesday, June 30, 2020 - link
I bought a 2TB TLC Phison drive for a lower price than Samsung wants for their 2TB QLC drive. They're a ripoff.Guspaz - Tuesday, June 30, 2020 - link
Clarification: my 2TB TLC NVMe drive costs less than Samsung's 2TB QLC SATA drive.ddhelmet - Wednesday, July 1, 2020 - link
If you wanted an SSD just to put games, isn't 870 QVO identical in perfomance (loading speed) to 860 EVO?flowingbass - Wednesday, July 1, 2020 - link
Looks like these are good for use as game installation drives where capacity is good and random performance still better than hard drives. But price needs to be cheaperisthisavailable - Wednesday, July 1, 2020 - link
I disagree. What about when you decide to move games for example 90 GB GTA 5 folder and your write speeds drop to 80 MB/s?NoSoMo - Wednesday, July 1, 2020 - link
You're just better off buying a non-QLC SSD period --- These drive make no sense for anyone that knows better.StrangerGuy - Wednesday, July 1, 2020 - link
Yeah, I mean just how much brain damaged one can be to think buying any Samsung QVO over cheaper and faster TLC drives would be a good idea?chrysrobyn - Wednesday, July 1, 2020 - link
It's great to see a spinning hard drive in the benchmark comparisons. Puts a lot of them into perspective.Alim345 - Wednesday, July 1, 2020 - link
WD black 1tb was recently available for 130$, Intel's 660p nvme ssd is faster and cheaper than those Samsung drives. Who would buy those ssds? If qlc drives get substantially cheaper they might become viable for game storage needs.Oxford Guy - Wednesday, July 1, 2020 - link
QLC is garbage.Lipstick on a pig won't make me kiss one.