The Samsung 860 QVO (1TB, 4TB) SSD Review: First Consumer SATA QLC
by Billy Tallis on November 27, 2018 11:20 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 860 QVO is clearly lower than the 3D TLC competition, while the Intel/Micron QLC NVMe drives have no trouble competing against the field of mainstream SATA TLC drives. Even in the worst case of the smallest QVO being entirely full, read speeds are still vastly better than a hard drive.
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 Toshiba TR200 DRAMless TLC drive is no longer able to stay ahead of the 860 QVO, and even the Intel/Micron QLC drives fall behind most mainstream SATA drives (especially when full).
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| Power Efficiency in MB/s/W | Average Power in W | ||||||||
The power consumption of the 860 QVO during the random read test is only slightly higher than its TLC-based relatives, but that's plenty to push its efficiency scores into last place, given the poor performance.
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The queue depth scaling of the 860 QVO during random reads is fairly typical in shape, with improvements starting to taper off after QD16. However, the vertical scale is important: the QVO doesn't ever reach even half the performance of the best TLC-based SATA SSDs.
Looking at the 1TB 860 QVO's random read results compared to all the other SATA drives in the benchmark database, it is clear that the QVO isn't anywhere near the cutting edge for power efficiency or peak performance, but there are worse drives out there.
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 SLC cache of the 860 QVO is very effective for the burst random write test, leaving it tied or slightly ahead of the 860 EVO.
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 larger SLC cache and greater parallelism of the 4TB 860 QVO helps it keep pace with other top SATA SSDs, but the 1TB QVO has to settle for being slightly faster than the DRAMless TLC drive.
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| Power Efficiency in MB/s/W | Average Power in W | ||||||||
The QVO is again a bit more power hungry than most of the TLC drives, which doesn't hurt the 4TB QVO's efficiency score much thanks to its good performance, but the 1TB QVO ends up tied for last place with the full-drive performance from the Intel/Micron QLC drives.
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The 1TB 860 QVO shows very little random write performance scaling with increasing queue depth, though power consumption does go up significantly from QD1 to QD2. The 4TB 860 QVO shows a much more typical scaling up to saturation at QD4, with a performance curve that is almost an exact match for the 4TB 860 EVO.
There are some TLC SATA SSDs that draw the same power to deliver half the random write performance of the 1TB 860 QVO, but in the grand scheme of things the 1TB QVO's results on this test are sub-par. The 4TB starts out in the same spot but ends up hitting the SATA performance wall without consuming too much power.
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CheapSushi - Wednesday, November 28, 2018 - link
Yeah the premise was cheaper NAND for bulk storage with compromises. That way all okay in my mind. But as shown, there's just no good value proposition here yet. Just inherently I figured QLC would be 33% cheaper than TLC and then mass production and the higher density stacking would bring that down further. But...I guess not.nagi603 - Friday, November 30, 2018 - link
At $400 I'd toss out all the current HDDs of my NAS. Maybe in a few years.... or not, as the HDD prices/capacities move too.azazel1024 - Friday, November 30, 2018 - link
My price point is roughly 8 cents a GB and performance of at least 250MB/sec sustained writes/reads.Which these aren't at. That might mean a few more generations of TLC drives to get there. I don't know. My use case is replacing the spinning rust in my desktop and server. I mirror storage between them and I am running dual 1GbE interfaces with SMB Multichannel. So I can push about 235MB/sec across.
Sometimes I am just shoving a few GB file (sometimes one or two single digit MB sized files, but more often larger ones). On rare occasions I am backing up completely from one machine to the other, because reasons. So when tossing 2-3TB of data, I don't need my transfer "stalling" at 80MB/sec, or even 160MB/sec. Hopefully soon networking prices on 2.5/5/10GbE will drop enough I will upgrade there. I don't necessarily need to saturate a 2.5GbE, let alone 5 or 10GbE interface with big transfers.
So my benchmark is 250MB/sec sustained on full disk transfers. That way I don't need to set up drives in RAID to accommodate higher speeds. As one of things I am looking forward to/hoping for with SSDs is being able to move to storage pools/JBOD type setup so that as I start pushing my capacity limits, I can just add a new drive, rather than needing to replace an entire array. And those sustained speeds better be able to manage that with the disk 80-90% full. One of those things that makes me shy away from using HDD arrays that full is the performance suffers a lot once you start getting that far in on the tracks (my current 2x3TB RAID0 arrays can push about 320MB/sec when on the outer tracks, on the inner ones it is only about 190MB/sec).
Once of these days I could justify dishing out $600-800 to replace my 2x3TB arrays with 5-6TB of storage in each machine. Especially if it is storage that I can potentially keep using for a long time (I don't know, call it a decade or so) by just adding a new disk once capacity starts getting low, rather than replacing all of them. But I need/want good performance while I am at it.
For my server I can still comfortably live with a 60GB system drive. When I upgrade it, I will likely FINALLY replace the old SATAII SSD in there with a newer SATAIII 120GB SSD or get an M.2 120GB depending on what the board will support. Basically the smallest capacity I can get. It doesn't need heaps of performance. My desktop I will likely get a 500GB M.2 TLC drive once I finally upgrade it (currently running a last generation 256GB TLC SATAIII drive as the system disk).There I'd like some nice performance, but frankly a good M.2 TLC drive with 512GB is big enough jump in performance I don't care to spend the money on an MLC drive for the system disk.
TheCurve - Tuesday, November 27, 2018 - link
Another great review from Billy. Love reading your stuff!rocky12345 - Tuesday, November 27, 2018 - link
This is great and a step closer to getting rid of spinning drives but they are not there yet. The prices of these Samsung drives are far better at the 4TB range but I just picked up a 4TB WD Blue for $99 Canadian on the black Friday sales granted that same drive before the sale was $209.99 Canadian but even still far cheaper than the $599.99US for the Samsung 4TB almost SSD drive.With all of that said I am very happy to see large TB drives for SSD coming into a lower price range probably going to be another 5-6 years before the prices match for spinning and SSD drives or if Seagate and WD totally stop making spinning drives then of coarse we have nothing to fall back on if we want large TB hard drives in our systems for data storage and we will have to pay the price of these types of SSD drives.
On a side note my fear is that when Seagate and WD stop making spinning drives SSD drive prices might sky rocket because we have no other option. The only reason SSD drives are coming down in the larger sizes is these companies are trying to compete with large TB spinning drives on price points.
kpb321 - Tuesday, November 27, 2018 - link
I'm not sure SSD's will ever pass up HD's for $ per GB for pure bulk storage. Even the "Cheap" 4tb SSD is around the cost of 2x 10 TB HDs so somewhere around 5X more expensive in $ per GB. Not an impossible margin but still a lot of ground to make up vs a moving target. What has happened is SSDs have gotten "big enough" and "cheap enough" that for many people they are viable as the only drive in their machine. Looking at Newegg it's ~$45 for your basic 1tb hd and you can pick up a cheap ~250gb SSD for a little less or a ~512gb SSD for a little more. I'd certainly prefer a 250 or 512 gb SSD as the drive in my system over a 1tb HD but if you do need bulk storage (1tb+) HDs are still hard to beat. 3TB hd's start off at ~$85 and continue to be more cost effect at higher sizes so I don't think HDs will completely vanish. They may become increasingly specialized to bulk storage and cloud providers with things like SMR trading off some performance for increased density but I doubt they will go away. Cheap PC mfgs do still seem to like the cheap 1tb hds. About the same cost as a small but usable SSD but give big numbers for the ads.dontlistentome - Tuesday, November 27, 2018 - link
It's about 10 years ago that I bought an Intel 80GB drive for $250. We're getting 2TB flash for that now - about a factor of 25 times reduction in price.Another 5 times cheaper? Easy.
DanNeely - Tuesday, November 27, 2018 - link
For comparison, in 2008 the biggest HDDs were apparently 1.5TB in size; that drive launched at ~$215 (although it rapidly dropped afterward). For comparison a 14TB Ironwolf is $530 at B&H. That's 9.3x more capacity at at 2.4x the price; or roughly at 3.8x improvement in price per TB at the top end. Or only 2.7x is you use the ~$150 price estimated price for nov 08.Flash might end up needing to drop 10x in price per TB to beat spinning rust; but it has momentum behind it, and the more market share it wins based on size/power/performance the more economies of scale and larger R&D budgets will tilt the floor in its favor.
https://www.tomshardware.com/reviews/hdd-terabyte-...
https://camelcamelcamel.com/Seagate-Barracuda-7200...
Lolimaster - Thursday, November 29, 2018 - link
Ever heard of law of diminishing returns?At 1st tech is hard to produce and sell than it scales till you reach a wall, same with flash cards at the times of N64, 32-64MB for $100.
Even HDD's which a well known tech is having a hard time executing the next step, HAMR which should boost capacities to 20-50TB, 4 years of delay.
The_Assimilator - Thursday, November 29, 2018 - link
Just like HDDs never passed tapes in cost/GB for bulk storage.