Load Testing

Power supplies are not like most other computer components, where it is a simple matter of comparing the item to others in the same category. Power supply's are comprised of several different variables, such as maximum output, voltage regulation, and current ripple. Each of these variables must be analyzed with unique tools, which makes it a difficult product to properly review.

I am well aware of what the more knowledgeable readers think about these power supply reviews: impractical and often useless. That's about to change. In the past, Benchmark Reviews has been guilty of the same thing nearly all of the other sites are guilty of: testing with a digital multimeter alone. So beginning now with this review, we are taking a corrected approach to testing PSU's and hope to offer the best analysis possible.

Benchmark Reviews has researched the equipment necessary to complete the most thorough power supply unit review possible. We spent the time learning what it takes because the best possible PSU tests are what we want to give to our readers. But after discovering the prices on a programmable output DC power supply system, variable range load testing units, and a DC power analyzer (Oscilloscope), we felt that more than ten-thousand dollars worth of equipment would be far too cost prohibitive for testing a hundred-dollar power supply. So without compromising too much, we made a slightly less-expensive investment into a good quality Oscilloscope in order to test DC voltage regulation and AC power ripple. Together, the Oscilloscope and digital multimeter will offer readers the best measurement of power stability any review site could reasonably offer.

Test System

Motherboard: ABIT AB9 Pro v1.6 BIOS (Intel 965 chipset)
Processor: Intel E6600 Core 2 Duo 2.2GHz operating at 3.2 GHz (356 MHz FSB)
Cooling: Thermaltake MaxOrb CL-P0369 CPU Cooler
Memory: 2 GB (1,024 MB x2 modules) Crucial PC2-8500 CL5 Ballistix DDR2 RAM
Video: FOXCONN GeForce 8800 GTS 640MB operating at 600MHz Core and 900MHz RAM
Audio Device: HT Omega 7.1 C-Media 8788 Oxygen Chipset
Hard Disks: (2) Western Digital WD360GD 10,000 RPM SATA in RAID-0 array
Optical Drive: Lite-On SH-16A7S-05 SATA DVD R/W
Enclosure: Lian Li PC-B20A ATX Case with 2x120mm and 1x90mm cooling fans
PSU: Mushkin HP-580AP Modular 580W
Operating System: Windows XP Professional SP-2 with IE7

Test Equipment

• Velleman PCSU-1000 Oscilloscope
  • DC Voltage Regulation Settings: 2V DC Volt/Division, 60MHz 1x, 1ms
  • AC Power Ripple Settings: 50mV Volt/Division, 60MHz 1x, 1ms
• PC-Lab2000SE v3.03 Interface Software
• Extech 450 Auto ranging Digital Multimeter

Test Methodology

Our testing process is comprised of measuring the AC current ripple, and the DC voltage regulation. There are several key steps, all of which allow us to measure and record our readings using the identical methods for every test we perform. Consistent testing methods are key to obtaining comparable results.

At the start of every test, the Velleman PCSU-1000 Oscilloscope is calibrated to the PC-Lab2000SE software. After calibration is complete, the voltage on the 12V rails are measured and recorded with the Extech 450 digital multimeter to ensure comparable margin across all rails. Once the Velleman 60MHz probe has been grounded and attached to the 12V lead, our test system is powered on and left at the Windows logon screen for ten minutes.

Once this lightly-loaded idle warm up period is complete, the Velleman PCSU-1000 Oscilloscope was allowed to run for one minute measuring the AC power ripple. Then once ripple is recorded, the 12V DC voltage regulation is recorded after another minute.

After the results have been recorded from the light idle load, our test system then receives heavy load by utilizing the following tools: two console versions of the Folding @ Home client operate and task each CPU core to 100%, hard disks are stressed by benchmarking each with HD Tach RW, system memory (RAM) is given a stress test with Lavalys EVEREST, and ATITool scans for artifacts which forced the video card into high-power 3D mode. After ten minutes of heavy load the power supply is again measured, and the AC power ripple and 12V DC voltage regulation results are recorded.

Voltage Regulation & Ripple Test Results

In the test results below, it will be necessary to explain what you are viewing. In each image the AC power ripple is represented by the yellow trace line making up the waveform. While every personal computer power supply unit available to the retail market has some degree of measurable AC power ripple, it is most important that measurable AC ripple is very minor and does not create a large peak to peak voltage (Vpp) distortion. Stable, well-regulated power is critical to system stability and hardware longevity.

AC Ripple at Light Idle Load

The waveform image above shows the AC power ripple under light idle load, which measured 12.70 mV. Note that there are several minor ripples above and below the baseline, and only a few major ripples, all of which occur inside of a 1ms recording frame. The waveform data recorded during the light idle load measurement is displayed in the chart below:

AC Ripple Waveform Data at Light Idle Load

The waveform data above describes the actual measurements at light idle load. The maximum peak-to-peak AC voltage distortion was 225.0 mV, and the AC RMS ripple was 12.7 mV under light idle load. Here are the average AC RMS ripple measurments under light idle load for power supplies we have recently tested:

The waveform image below shows the AC power ripple under heavy load, which measured 16.32 mV. Note that there are several minor ripples above and below the baseline, and only a few major ripples, all of which occur inside of a 1ms recording frame.

AC Ripple at Heavy Load

Under heavy load, the Hiper HPU-4M730-SS Type M measured an average AC RMS ripple only slightly higher than the ripple at light idle load, which is very good. The waveform data recorded during the heavy load measurement is displayed in the chart below:

AC Ripple Waveform Data at Heavy Load

The Hiper HPU-4M730-SS Type M offered great results in the idle readings, and they remained excellent into the heavy load tests. Here are the average AC RMS ripple measurements under heavy load for other power supplies we have recently tested:

DC Voltage Regulation Waveform Data at Light Idle and Heavy Load

Many of the power supplies we test here at Benchmark Reviews have DC voltage regulation measuring above the 12V baseline more often than below. For obvious reasons, the diversion from the 12V baseline with increased voltage is more preferred than below it since dropping too far under 12V will cause a system to power off or recycle. Plainly put, no power supply is ever perfectly centered at 12V DC; instead they most often maintain a DC mean voltage higher than they are regulated at.

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