Models | 240 GByte | |
Motherboard | ASUS P8P67 Deluxe | |
Chipset | Intel P67 | 1'333 MHz |
CPU | Intel Core i7 2600k | 3.4 GHz |
Memory | Kingston HyperX 2133 | 4 GByte |
Graphics card | Gigabyte GeForce GTX 285 | |
Storage (system) | Seagate Barracuda | 640 GByte |
Operating systems | Ubuntu 10.04 | |
Filesystem | XFS |
We think everybody reading this article can imagine the following scenario: You just bought a hard drive which according the specs sheet should transfer 120 MByte/s reading and writing. In the reviews you read about astonishing 110 MByte/s but after you put the drive into you system it feels much slower. The whole story gets even worse when you start a benchmark which does randomread/write of 4 KByte blocks. There you only get two to three MBytes/s.
Because of this we don't want to publish screenshots of standard programs like HD-Tach, HD-Tune, ... we want our tests to be
We test with activated caches and NCQ (Native Command Queueing) because they're also activated under daily use. But the data size tested is always at least twice the amount of the memory.
We noticed that the measuring error is constantly within ±2%. Therefore we mention it only here.
Additionally we evaluate the S.M.A.R.T. data to assess if there are already errors.De plus, nous évaluons les données S.M.A.R.T afin d'évaluer si il y a des erreurs.[/fr]
The following table give you a brief overview to which points we turn our centre of attention.
Test | Observations |
Sequential Read/Write Tests |
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Random Read/Write Tests |
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iozone3 is a benchmark suit for storage solutions which natively runs under Linux.
Therefore we are testing the throughput with different block sizes using the following commands:
It is important to reproduce scenarios of daily usage. Certain parameters need to be variable during the test to make a statement about the product. In our test the parameters are the different block sizes. It defines the size in KBytes which is written/read on the drive during a transaction.
With this method one can test the reading and writing of either small and big files. In a normal personal computer environment you usually don't find many files smaller than 16 KByte. The relative amount of small files is much bigger on a mail or database server. Therefore tests with small block sizes are of interest for database-based applications.
In bigger RAID arrays the hard disk cache is usually disabled and the RAID-Controller takes over the job of caching. Exactly in such setups hard drives need to be very fast when reading or writing small amounts of data. Sequential throughput isn't interesting in this case.
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OCZ IBIS 240GB | Review: OCZ Agility 3 240 GByte |
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