Performance Comparisons – Mixed Burst
These are the Mixed Burst results introduced in the Samsung 850 EVO 4TB Review. Some tweaks have been made, namely, QD reduced to a more realistic value of 2. Read bursts have been increased to 400MB each. 'Download' speed remains unchanged.
In an attempt to better represent the true performance of hybrid (SLC+TLC) SSDs and to include some general trace-style testing, I’m trying out a new test methodology. First, all tested SSDs are sequentially filled to 100%. Then the first 8GB span is pre-conditioned with 4KB random workload, resulting in the condition called out for in many of Intel’s client SSD testing guides. The idea is that most of the data on an SSD is sequential in nature (installed applications, MP3, video, etc), while some portions of the SSD have been written to in a random fashion (MFT, directory structure, log file updates, other randomly written files, etc). The 8GB figure is reasonably practical since 4KB random writes across the whole drive is not a workload that client SSDs are optimized for (it is reserved for enterprise). We may try larger spans in the future, but for now, we’re sticking with the 8GB random write area.
Using that condition as a base for our workload, we now needed a workload! I wanted to start with some background activity, so I captured a BitTorrent download:
This download was over a saturated 300 Mbit link. While the average download speed was reported as 30 MB/s, the application’s own internal caching meant the writes to disk were more ‘bursty’ in nature. We’re trying to adapt this workload to one that will allow SLC+TLC (caching) SSDs some time to unload their cache between write bursts, so I came to a simple pattern of 40 MB written every 2 seconds. These accesses are more random than sequential, so we will apply it to the designated 8GB span of our pre-conditioned SSD.
Now for the more important part. Since the above ‘download workload’ is a background task that would likely go unnoticed by the user, we also need is a workload that the user *would* be sensitive to. The times where someone really notices their SSD speed is when they are waiting for it to complete a task, and the most common tasks are application and game/level loads. I observed a round of different tasks and came to a 200MB figure for the typical amount of data requested when launching a modern application. Larger games can pull in as much as 2GB (or more), varying with game and level, so we will repeat the 200MB request 10 times during the recorded portion of the run. We will assume 64KB sequential access for this portion of the workload.
Assuming a max Queue Depth of 4 (reasonable for typical desktop apps), we end up with something that looks like this when applied to a couple of SSDs:
The OCZ Trion 150 (left) is able to keep up with the writes (dashed line) throughout the 60 seconds pictured, but note that the read requests occasionally catch it off guard. Apparently, if some SSDs are busy with a relatively small stream of incoming writes, read performance can suffer, which is exactly the sort of thing we are looking for here.
When we applied the same workload to the 4TB 850 EVO (right), we see an extremely consistent and speedy response to all IOs, regardless of if they are writes or reads. The 200MB read bursts are so fast that they all occur within the same second, and none of them spill over due to other delays caused by the simultaneous writes taking place.
Now that we have a reasonably practical workload, let’s see what happens when we run it on a small batch of SSDs:
From our Latency Percentile data, we are able to derive the total service time for both reads and writes, and independently show the throughputs seen for both. Remember that these workloads are being applied simultaneously, as to simulate launching apps or games during a 20 MB/s download. The above figures are not simple averages – they represent only the speed *during* each burst. Idle time is not counted.
The slightly slower reads and slightly faster writes of the 750 EVO series suggest that they favor writes when compared to the other SATA models in this grouping. The Intel 600p is faster on both fronts, but not by as large of a margin as you might think.
Now we are going to focus only on reads, and present some different data. I’ve added up the total service time seen during the 10x 400MB reads that take place during the recorded portion of the test. These figures represent how long you would be sitting there waiting for 4GB of data to be read, but remember this is happening while a download (or another similar background task) is simultaneously writing to the SSD. This metric should closely equate to the 'feel' of using each SSD in a moderate to heavy load.
Here the 850 EVO shaves 4-6 seconds vs. the 750 EVO's, while the 600p shaves nearly a third of the time.
The above results retained sorting consistent with the rest of the roundup charts. Below is a lot more data, sorted by performance:
On the page “Performance
On the page “Performance Focus – 750 EVO 250GB” under the first graph it says “Very impressive speeds for the 1TB 960 EVO. […]”.
Clearly that’s wrong 😀
Fixed. Thanks!
Fixed. Thanks!
You’re welcome 😉
You’re welcome 😉
Was Samsung 840 EVO really
Was Samsung 840 EVO really worth Editor’s Choice Award?
840 EVO? Back when it
840 EVO? Back when it launched? Sure. There were issues that were fixed, but could not be discovered at the time of the review.
hey Allyn, is it possible to
hey Allyn, is it possible to include some raid0 SATA devices on your chart? for example samsung 850 pro raid 0 or 960 pro raid 0 to see how it fairs with single drives.
I understand due to raid latency, QD1 performance would drop but since your chart shows average of 1-4QD this would see some improvement in terms of raid, also see how well does SSD caching with intel RST would benefit us over single drive.
Isn’t the 750 EVO EOL now?
Isn’t the 750 EVO EOL now?
I love your write up about
I love your write up about the Latency Percentile. Your storage reviews are by far more realistic with some real engineering behind it. Keep up the great work!
Still waiting on a Storage
Still waiting on a Storage Leader board, like have the stats of all of them on an consistently updated page.
The 500GB 750 Evo is $241,
The 500GB 750 Evo is $241, the 500GB 850 Evo is $170. You’d be a fool to buy the lesser 750 for more than the better 850.
You would be a fool to pay
You would be a fool to pay that, especially since you can get one practically anywhere for ~$145-155 depending on tax/shipping.
Hi Allyn.
Wishing you all a
Hi Allyn.
Wishing you all a happy festive season………………
Samsung and Sandisk(rip)were the only ones to get a grip
on planer TLC.That Ultra 2 result in the write cache test
is really strange.
I remember when you did a comparison a while back I asked
if you could include ultra 2 which was using folding on
each individual die-obviously you were too busy.
Guess something was going on in the background there…..
As to the 750 EVO’s-the 250 and 500 pass my requirements.
1.More than 8000 IOPS read QD1.(must for a boot drive)
2.Write more than 200MB after the cache(cant have it slower
than my spinning rust)
Would be great if this huge
Would be great if this huge chart was searchable and not as an image. I wonder if my Toshiba Toshiba THNSNJ is somewhere there…