For this review I will be using a computer with the following configuration:
- Motherboard: ASUS X99-A (Intel X99 chipset)
- Processor: Intel Core i7 5280K @ 4.4GHz
- RAM: RAM: Crucial Ballistix Elite 4x8GB
- GFX: MSI GTX 960 2GB
- Sound: Onboard Realtek HD audio controller
- OS SSD: HyperX Fury 240GB
- PSU: Seasonic 750W
- Display: Futsiju Siemens 22”
- Operating System: Windows 10
The ADATA SU800 256GB SSD was connected to first SATA port on the ASUS X99-A motherboard. All power saving features were disabled during all of my synthetic benchmarks.
The SATA 6Gbps drivers used on our review PC were Intel Rapid Storage Technology (RST) Version 220.127.116.111.
To test the performance of the ADATA SU800 256GB SSD, I will be using the following test applications in this review.
I will start off our testing procedures explanation by stating that I did not run many synthetic benchmarks on the ADATA SU800 256GB SSD. You may ask why I have run so few synthetic benchmarks.
SSD technology has moved so fast in the last couple of years, that basic synthetic benchmarks alone are now of very limited use, as they don't really tell us much about performance and how the drive will behave in the real world. I have therefore decided to show some basic benchmarks for the ADATA SU800 256GB SSD, and will complement this with advanced benchmarks using IOMeter and AS SSD benchmark. I will also show how the ADATA SU800 256GB SSD performs in the real world.
The reality of SSD performance
While I can easily show you which SSD is technically the faster, when you use one of these modern SSDs as an operating system drive it becomes very difficult to tell them apart as far as performance is concerned.
A typical use of a small capacity SSD at the moment is to have your operating system and applications installed onto the SSD. The performance difference compared to a traditional HDD is enormous, however when you start to compare SSD to SSD the difference becomes almost impossible to detect.
Let’s look at why this is the case.
Drive A can boot to the desktop in 8.11 seconds, and drive B can boot to the desktop in 8.12 seconds, the difference in time is milliseconds, and can one really tell the difference?
The fact is, all modern SSDs are only ticking over when they are only running the OS and launching applications, it’s only when you get to some of the larger capacity SSDs, with enough free space to be able to hold the actual data that you’re going to be working with, be that video, audio or pictures, for example, that you actually get a tangible difference in performance. This is where the SSDs with the better sequential performance start to pull well ahead of the SSDs which have lower sequential read/write performance.
Small file random IOPS vs sequential performance
This is a fairly complex subject, but I will do my best to explain things in a manner that is easy to understand.
The term IOPS is the amount of input or output transactions that can take place in a one second interval, so for example, if an SSD is quoted as being able to cope with 20,000 4K random write IOPS, then the SSD should be able to cope with 20,000 input transactions in a period of one second. If the same SSD is said to be able to produce 20,000 4K random read IOPS, then the same SSD should be able to produce 20,000 4K random read output transactions in a one second interval.
Ok, now we have some figures to work with, the next question is how many IOPS are actually required?
This will depend on your usage pattern. If you are a typical desktop user who browses the internet, does some word processing or perhaps some audio or video editing, and perhaps plays a few games, then in actual fact, you don’t need to have massive 4K random read/write performance. The actual amount of 4K random performance that is required for a fast and smooth running system for a desktop user with a usage pattern similar to the above will be well under 1,000 4K IOPS.
On the other hand, if the SSD is being used for running a large and complex database server, then 4K random performance is the absolute measurement of how fast that server will run, as this type of application does most of its input and output transactions in the 4K domain.
So why would I need an SSD with 80,000 4K IOPS for a desktop?
In fact you don’t need this type of performance for a desktop, but an SSD which is capable of coping with 80,000 4K IOPS will be faster than an SSD which can only cope with 20,000 4K IOPS.
OK, I just said if under 1,000 4K IOPS are actually required for typical desktop usage, why is an SSD with 80,000 4K IOPS faster than an SSD with only 20,000 4K IOPS, confused?
You may ask, if I only require 1,000 4K IOPS surely the rest is wasted?
While you may never need 80,000 4K IOPS, IOPS is all about latency. The reason that an SSD can cope with as much as 80,000 4K IOPS is because latency in this domain is very low. With 4K files, even if you require to process 500 of them at the same time, you are not talking about a huge amount of data, it has far more to do with how long it takes the SSD to process a single file, and the amount of time required to process a single 4K is all about how long it takes for the SSD to access or store that data before it can move on to the next transaction.
In other words an SSD with 80,000 4K IOPS performance will handle those 500 files faster than the SSD with 20,000 IOPS.
So how will a desktop user even notice this faster speed if so little 4K random IOPS and data are actually used?
Multitasking is a good example. The more tasks you run at the same time, you more you will notice the speed difference.
I have always maintained that sequential performance was every bit as important as small random file performance for a desktop SSD. Some highly regarded people on other sites found this statement quite funny a couple of years ago when I made it, but my, how times have changed in the world of SSD reviewing.
To me this was always so obvious for a desktop user. For example, let’s say you want to launch an application or game. Both have some fairly large files to load, and also a great many small files, but the point is, even the smaller files are sequential in nature. Now let’s say you’re into audio or video editing. Video files tend to be huge, and the files are written or read sequentially. Isn’t this how many users are using their PCs these days?
So how does this shape up in the real world? Which is better, massive 4K IOPS or massive sequential performance?
In an ideal world you want both, as an SSD with massive random 4K IOPS and sequential performance will always be faster than an SSD that has high sequential performance and moderate 4K random IOPS performance, and the same applies to an SSD that has massive 4K random performance and moderate sequential performance. The SSD which has high performance in both patterns will always be the faster SSD.
However, you can still have an SSD that is very fast for desktop use that has moderate random 4K performance and massive sequential performance, the same can be said about a drive having massive random 4K performance and moderate sequential performance, as it is about getting the balance right if you have to compromise on one or the other.
Drive preparation for running the tests
All the SSDs used in this article were in a clean and fresh state when the testing period started. From then on, each drive had to rely on its own NAND cleaning effectiveness for the remainder of the tests.
- Both our spinning HDD drives were defragged before the start of each test.
- All SSD and HDD used in this article had their partitions aligned to the Windows 7 x64 defaults.
Where I use graphs in this article to display results, I will use the following colours to make it easier, for our readers to see which drive we are reviewing.
ADATA SU800 256GB SSD
Let's take a look at the ADATA SSD Toolbox software