Overall Performance

How does the i-RAM impact overall system performance? In order to find out, we installed Winstone on the drive and compared its benchmark results to the Raptor:

Overall Performance Comparison (Higher is Better)
Business Winstone 2004
Multimedia Content Creation Winstone 2004
Gigabyte i-RAM (4GB)
24.5
36.3
Western Digital Raptor (74GB)
23.9
35.4

What's very interesting here is that there's very little performance gain from running Winstone on the i-RAM, which tells us that Winstone isn't nearly as disk bound as we originally thought.

We wanted to run other benchmark suites on the i-RAM; however, we ran into capacity issues once again.

One of the biggest advantages of the i-RAM is its random access performance, which comes into play particularly in multitasking scenarios where there are a lot of disk accesses. In order to see if this translates into any tangible real world performance gains, we turned to the Multitasking Business Winstone tests:
"This test uses the same applications as the Business Winstone test, but runs some of them in the background. The test has three segments: in the first, files copy in the background while the script runs Microsoft Outlook and Internet Explorer in the foreground. The script waits for both foreground and background tasks to complete before starting the second segment. In that segment, Excel and Word operations run in the foreground while WinZip archives in the background. The script waits for both foreground and background tasks to complete before starting the third segment. In that segment, Norton AntiVirus runs a virus check in the background while Microsoft Excel, Microsoft Project, Microsoft Access, Microsoft PowerPoint, Microsoft FrontPage, and WinZip operations run in the foreground."
Winstone Multitasking Performance Comparison (Higher is Better)
Test 1
Test 2
Test 3
Gigabyte i-RAM (4GB)
5.55
2.98
3.1
Western Digital Raptor (74GB)
2.78
2.93
3.04

The biggest performance gain is in the first multitasking test, which is the file copy test while Outlook and IE run. The performance advantage here is tremendous, with the i-RAM generating a score almost twice that of the Raptor.

The rest of the tests show very little performance improvement. We'd guess that the majority of the boost in the first test is due to the file copy that takes place during the run.

File Copy and Archive Performance Final Words
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  • Sea Shadow - Monday, July 25, 2005 - link

    I wonder if the OS is the limiting factor. They should run some tests using other os *cough* linux *cough*.

    What would be really neat is if they could design an i-Ram device that uses 2 HDD bays and supported 8+ GB of ram and ran from a standard molex.
  • sprockkets - Tuesday, July 26, 2005 - link

    You people think about using Knoppix and copying to the drive? For that matter, that and stuff like damnsmalllinux and such can be run totally from system ram.

    Instead of using this though for a slient drive, you are better off using flash memory drives for that.
  • ViRGE - Monday, July 25, 2005 - link

    Unfortunately if they did that, it would mean that your computer could never be turned off. As noted in the review, the card is currently still powered even if the machine is "off", due to the fact that when a modern ATX computer is off, it's actually more of a super-standby mode that leaves a few choice items powered on for wake-on events(LAN/modems, and the power button of course). All Gigabyte is doing here is taping in to the 3.3v line on the PCI slot that wake-on power is provided through, which is enough to keep the device powered up even when the system is in its diminished state.

    Molex plugs on the other hand are completely powered down when the system is "off", so it would be running off of battery power in this case. A lot of us leave our systems on 24/7 anyhow, but I still think they'd have a hard time selling a device that would require your computer to be off for no more than 16 hours at a time.
  • Gatak - Monday, July 25, 2005 - link

    They could use the USB power. On most motherboards you can enable with a jumper or BIOS to supply standby power to the USB. Often the setting is called "Wake on USB" or "Wake on Keyboard" etc
  • reactor - Monday, July 25, 2005 - link

    "What would be really neat is if they could design an i-Ram device that uses 2 HDD bays and supported 8+ GB of ram and ran from a standard molex."

    Was thinking something similar myself as i was reading.

    I think once ram modules are 4gb or larger, then this could be very useful. But not until it gets updated with sata2, ddr400 etc. When the time comes to build an HTPC then ill give this another look.

    Nice article.
  • ranger203 - Monday, July 25, 2005 - link

    Not to shabby, but i was honestly expecting like 3 second boots, & 5 second game load times... why is there only a 20% speed increase in some areas?
  • Griswold - Thursday, July 28, 2005 - link

    Because the data still has to be processed after being loaded - bandwith is obviously not the biggest bottleneck here.
  • forwhom - Tuesday, July 26, 2005 - link

    What I would be very interested in seeing is the performance of the thing using it as the source for encoding a dvd/mpeg... Most encoders are heavily disk-based and if it could reduce the time significantly it might be worth while - assuming that eventually they come out with one big enough to hold the source. There's now reasonable CPU encode performance, just have to get the data to/from it... maybe the i-drive would help..
  • highlandsun - Monday, July 25, 2005 - link

    Hmmm, the WD Raptor has a sustained transfer rate of 72MB/sec. So on a freshly formatted drive, with no fragmentation, it should still be half the speed of the iRam. But at $200 for a 74GB drive, then you could get a pair of these running in RAID0, which would run at around 140MB/sec anyway, and still have spent less than the cost of the iRam and 4GB of DDR DIMMs. It definitely seems like this product falls short.

    The use of PCI 3.3V standby power is clever. Perhaps a future version should just use a dummy PCI card to provide the power, connected to a 5" drive-size case with many more DIMM slots. If you can't cram at least 16 DIMMs in there, then the ability to use old memory is kind of wasted, since the old modules will have such small capacities.

    Ultimately I think this type of product will always be a failure.

    What they should do instead is make it a pass-through cache for a real SATA drive. So you plug the SATA controller into it, and plug it into a real SATA drive, and it caches all I/O operations to the real drive. That's the only way that you can get meaningful benefit out of only 4GB of memory. A card like this would turn any SATA drive into a speed demon; 4GB is definitely a decent size for most caching purposes.
  • highlandsun - Monday, July 25, 2005 - link

    Of course the next logical step is to put the DIMM slots on the SATA controller card, so that access to cached data occurs at real memory speeds, not just SATA bus speed. This would only be a useful product for folks stuck on 32-bit systems, because otherwise it would be best to just increase the system memory instead. But there are plenty of 32-bit systems out there that would benefit from the approach.

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