|EonNAS 1100 NAS Network Storage Server|
|Reviews - Featured Reviews: Network|
|Written by Bruce Normann|
|Wednesday, 05 December 2012|
Page 9 of 15
Benchmark Reviews primarily uses metric data measurement for testing storage products, for anyone who is interested in learning the relevant history of this sore spot in the industry, I've included a small explanation below:
The basic unit data measurement is called a bit (one single binary digit). Computers use these bits, which are composed of ones and zeros, to communicate their contents. All files are stored as binary files, and translated into working files by the Operating System. This two number system is called a "binary number system". In comparison, the decimal number system has ten unique digits consisting of zero through nine. Essentially it boils down to differences between binary and metric measurements, because testing is deeply impacted without carefully separating the two. For example, the difference between the transfer time of a one-Gigabyte (1000 Megabytes) file is going to be significantly better than a true binary Gigabyte (referred to as a Gibibyte) that contains 1024 Megabytes. The larger the file used for data transfer, the bigger the difference will be.
Have you ever wondered why your 500 GB hard drive only has about 488 GB once it has been formatted? Most Operating Systems utilize the binary number system to express file data size, however the prefixes for the multiples are based on the metric system. So even though a metric "Kilo" equals 1,000, a binary "Kilo" equals 1,024. Are you confused yet? Don't be surprised, because even the most tech savvy people often mistake the two. Plainly put, the Kilobyte is expressed as 1000 bytes, but it is really comprised of 1,024 bytes.
Most network engineers are not fully aware that the IEC changed the way we calculate and name data chunks when they published the new International Standards back in December 1998. The International Electrotechnical Commission (IEC) removed the old metric prefixes for multiples in binary code with new prefixes for binary multiples made up of only the first two letters of the metric prefixes and adding the first two letters of the word "binary". For example, instead of Megabyte (MB) or Gigabyte (GB), the new terms would be Mebibyte (MiB) or Gibibyte (GiB). While this is the new official IEC International Standard, it has not been widely adopted yet because it is either still unknown by institutions or not commonly used.
NAS Testing Methodology
All the NAS devices we test cannot accommodate all the different disk configurations, so our current test protocol has been based on two of the most popular setups: a basic (single) disk and RAID-5 configurations. Most NAS products that can support RAID 5 go beyond the minimum number of drive bays, to a total of four, so that is the number of drives that I typically use to test with, even though I could get by with only three. During initial setup, the NAS was tested for the latest firmware by checking the Infortrend website The firmware installed on the EonNAS 1100 was v1.4.55 when I received it, which is the most current version.
Normally, I connect the NAS directly to an Intel Gigabit CT Desktop LAN controller in the test-bench system, with ten-foot CAT6 patch cables. I've recently upgraded my test environment with a business-class GS110T Smart Switch from NETGEAR, which offers high throughput along with a wide array of configuration options that the typical unmanaged network switch can't touch. I set all the components up with static IP addresses in the 192.168.xxx.yyy range. I did a couple throughput tests and saw no appreciable differences in transfer speeds, so I stuck with the more realistic network arrangement for testing. At the transfer speeds I was seeing, the single GbE connection wasn't holding the unit back, so I feel comfortable using this setup for all future testing.
With the networking taken care of, the next potential bottleneck that needed attention is the disk system on the host PC. In earlier tests, I relied on the third generation OCZ Agility SSD, which is good for at least 500 MB/s, input or output, on the appropriate Intel Platform Controller Hub. While I was doing some testing with an 8-bay monster NAS and 10GbE connections, I decided it was time to bypass the SSD on the test rig and install a RAM Disk. There are at least a dozen products on the market that will create and manage a RAM Disk on Windows systems; I chose RAMDisk v184.108.40.206R22 from Dataram based on performance tests in several reviews (we read 'em, too....) and its reasonable cost structure. I needed to assign at least 10GB of space to the RAM Disk, in order to replicate the test protocol I've been using for all my NAS testing, so none of the freeware products looked suitable. One other trick was necessary, to get the RAM Disk to transfer files larger than 2GB, I had to use the "Convert" utility in Windows to make the RAM Disk into an NTFS volume. Then I was able to perform the file transfers with 10GB files, no problem. If you want to avoid this extra step, be sure to look for a RAM Disk product that directly supports the NTFS file system.
For basic throughput evaluation, the NAS product received one test transfer followed by at least three timed transfers. Each test file was sent to the Western Digital Caviar Black 750GB (WD7502AAEX) hard drives installed in the NAS for a timed NAS write test, and that same file was sent back to the RAM Disk in the test system to perform a NAS read test. Each test was repeated several times, the high and low values were discarded and the average of the remaining results was recorded and charted.
The Read and Write transfer tests were conducted on each NAS appliance using the 1 GB file and then a 10 GB file. A second set of tests are conducted with Jumbo Frame enabled, i.e. the MTU value for all the Ethernet controllers is increased from 1500 to 9000. Most of the NAS products tested to date in the Windows 7 environment have supported the Jumbo Frame configuration. Only the NETGEAR ReadyNAS NV+ v2 uses the 1500 MTU setting by default, and has no user-accessible controls to change that; you'll see that reflected in the charts. I used a single GbE for all tests; I have not yet been able to achieve consistent results with all units using the IEEE 802.3ad Link Aggregation Control Protocol (LACP) mode.
I also ran the Intel NAS Performance Toolkit (NASPT) version 1.7.1, which was originally designed to run on a Windows XP client. People smarter than me have figured out how to run it under Windows 7, including the 64-bit version that is used more often than the 32-bit version these days. NASPT brings an important perspective to our test protocol, as it is designed to measure the performance of a NAS system as viewed from the end user's viewpoint. Benchmarks like ATTO use Direct I/O Access to accurately measure disk performance with minimal influence from the OS and the host platform. This provides important, objective data that can be used to measure raw, physical performance. While it's critical to measure the base performance, it's also important to quantify what you can expect using real-world applications, and that's exactly what NASPT does. One of the disadvantages of NASPT is that it is influenced by the amount of memory installed on the client, and it was designed for systems that had 2-4 GB of RAM. Consequently, two of the tests give unrealistic results, because they are measuring the speed of the buffer on the client, instead of the actual NAS performance. For that reason, we will ignore the results for "HD Video Record" and "File Copy to NAS". I'm also not going to pay too much attention to the "Content Creation" test, as it is too heavily focused on computing tasks that aren't really handled by the NAS.
Benchmark Reviews also measures NAS performance using some tests that are traditionally used for internal drives. The ATTO Disk Benchmark program is free, and offers a comprehensive set of test variables to work with. In terms of disk performance, it measures interface transfer rates at various intervals for a user-specified length and then reports read and write speeds for these spot-tests. CrystalDiskMark 3.0 is a file transfer and operational bandwidth benchmark tool from Crystal Dew World that offers performance transfer speed results using sequential, 512KB random, and 4KB random samples. Benchmark Reviews uses CrystalDiskMark to illustrate operational IOPS performance with multiple threads, which allows us to determine operational bandwidth under heavy load.
We are continuing our NAS testing with the exclusive use of Windows 7 as the testing platform for the host system. The performance differences between Win7 and XP are huge, as we documented in our QNAP TS-259 Pro review. The adoption rate for Win 7 is very high, and Benchmark Reviews has been using Win 7 in all of our other testing for some time now. It was definitely time to make the jump for NAS products.
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