The Mainstream Phoenix Rises: Samsung's 970 EVO (500GB & 1TB) SSDs Reviewed
by Billy Tallis on April 24, 2018 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 burst random read performance of the Samsung 970 EVO is the best they've ever delivered from TLC NAND flash memory, but the Intel SSD 760p is a few percent faster still.
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, the Samsung 970 EVO proves to be the fastest TLC-based drive, but Samsung's MLC-based drives offer up to 20% higher performance.
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| Power Efficiency in MB/s/W | Average Power in W | ||||||||
The Samsung 970 EVO and its OEM sibling PM981 have the worst power efficiency of any recent high-end SSD during the random read test. The 970 EVO is drawing over 2.5W while Samsung's previous generation high end drives averaged less than 2W for very similar performance.
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The performance scaling of the 970 EVO is almost identical to that of the 960 EVO, but the 970 EVO draws more power throughout the random read test.
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 from the Samsung 970 EVO is disappointing compared to the PM981, especially for the 1TB 970 EVO. Meanwhile, recent Intel and WD drives have been raising the bar with very fast SLC write caches.
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, the 1TB PM981 provided top-tier performance, but the 1TB 970 EVO is about 12% slower, putting it on par with the previous generation from Samsung. The 500GB 970 EVO is also slightly slower than its PM981 counterpart.
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| Power Efficiency in MB/s/W | Average Power in W | ||||||||
Power efficiency has also regressed for the 970 EVO on the random write test, leaving it well below the standard set by the WD Black and the slower but similarly efficient Toshiba XG5.
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The random write performance of the 1TB 970 EVO tops out at just over 1.5 GB/s at queue depths of 8 and higher. The 500GB 970 EVO starts running out of SLC cache and showing inconsistent performance past QD4. The 1TB PM981 was able to ramp up performance much faster than the 970 EVO and hit a maximum of about 1.8GB/s before running out of SLC cache near the end of the test. The 512GB PM981 behaved very similarly to the 500GB 970 EVO.
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jkresh - Tuesday, April 24, 2018 - link
is a review of the HP EX920 coming?Billy Tallis - Tuesday, April 24, 2018 - link
Yep, I have a sample of that on hand. I haven't tested it yet so it'll be a few weeks while I run it and several other drives through the post-Meltdown/Spectre patched testbed.Luckz - Tuesday, April 24, 2018 - link
You write that you use Windows drivers instead of manufacturer ones, but elsewhere I hear complaints that the PM981 isn't a very useful buy because it requires drivers that aren't even available to the public, only to OEMs. Wouldn't it make sense to also try these with Samsung drivers especially if they're being compared to the PM981 all the time?Billy Tallis - Tuesday, April 24, 2018 - link
The PM981 doesn't require any special drivers. It's just another standard NVMe SSD.HStewart - Tuesday, April 24, 2018 - link
I am curious what kind of performance would I see replacing the Hyrix 512G in my Dell XPS 15 2in1 with a 1G or possible 2G in a year.Drazick - Tuesday, April 24, 2018 - link
Why do we need M.2 in desktop computer?Why should we live with this thermal compromise?
We want SATA Express / U2 drives.
Cooe - Tuesday, April 24, 2018 - link
Yuck and yuck. SATA Express is 1/2 the speed, and a completely stillborn interface, and the cable dependant huge waste of space 2.5" U2 makes next to no sense outside the data center. The M.2 form factor has countless innateadvantages over both those and any of it's potential thermal issues are easy & cheap to solve if you're particular setup happens to be vulnerable to their occurrence.
Not only have Samsung's copper heatsink labels reduced the problem significantly w/o any user action, but most good current motherboards have included M.2 heatsinks and even for those that don't, they can be purchased online for ridiculously cheap.
Now find me something braindead simple to install & use for just a couple $ that can make SATA Express twice as fast and actually used in drives, or make U.2 cableless and a fraction of a standard 2.5" drive's size. There isn't any.
medoogalaxy - Wednesday, April 25, 2018 - link
superpower ssdshatteredx - Wednesday, April 25, 2018 - link
Which is more important for “snappiness,” 4K random qd1 read or write?sjprg2 - Wednesday, April 25, 2018 - link
Just because I hate the sata cables I now have all M.2 Samsungs installed either in the M.2 slots or on the PCIE plugin adapters. This also allows all of the trays to be removed from the chassis letting the front panel fans blow straight onto the motherboard and plugins.