Advanced Transient Response Tests
In these tests, we monitor the response of the PSU in two different scenarios. First, a transient load (15 A at +12V, 6 A at +5V, 6 A at +3.3V, and 0.5 A at 5VSB) is applied to the PSU for 20 ms while it is working at 20% load. In the second scenario, the PSU, while working at 50% load, is hit by the same transient load. In both tests, our oscilloscope measures the voltage drops caused by the transient load. All voltages should remain within the regulation limits defined by the ATX specification.
During real-world usage, a PSU always operates under changing loads, depending on whether the CPU or graphics card is busy. It is of immense importance that the PSU can keep its rails within the limits defined by the ATX specification. Smaller deviations reduce the stress applied to system components.
We should note that the ATX specification requires capacitive loading during the transient tests. Still, in our methodology, we chose to apply the worst-case scenario with no extra capacitance on the rails. Although the ATX specification asks for this capacitance, your system—the mainboard and its other parts—may not provide it, which we have to keep in mind as well.
Advanced Transient Response 20% - 50 Hz |
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Voltage | Before | After | Change | Pass/Fail |
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12V | 12.171V | 11.999V | 1.41% | Pass |
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5V | 5.010V | 4.913V | 1.94% | Pass |
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3.3V | 3.326V | 3.197V | 3.87% | Pass |
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5VSB | 5.055V | 5.017V | 0.74% | Pass |
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Advanced Transient Response 50% - 50 Hz |
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Voltage | Before | After | Change | Pass/Fail |
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12V | 12.131V | 12.016V | 0.95% | Pass |
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5V | 4.997V | 4.801V | 3.93% | Pass |
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3.3V | 3.314V | 3.180V | 4.06% | Pass |
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5VSB | 5.020V | 4.979V | 0.81% | Pass |
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I would like to see lower deviations, below 1%, at +12 V, and below 3% at 3.3 V. The 5 V rail ideally should be within 2%.
Below are the oscilloscope screenshots we took during Advanced Transient Response testing.
Transient Response at 20% Load
Transient Response at 50% Load
Turn-On Transient Tests
We measure the response of the PSU in more straightforward scenarios of transient load—during the power-on phase of the PSU—in the next set of tests. In the first test, we turn the PSU off, dial the maximum current the 5VSB can output, and then switch on the PSU. In the second test, we dial the maximum load +12V can handle and start the PSU while the PSU is in standby mode. In the last test, while the PSU is completely switched off (we cut off power or switch the PSU off by flipping its on/off switch), we dial the maximum load the +12V rail can handle before switching the PSU on from the loader and restoring power. The ATX specification states that recorded spikes on all rails should not exceed 10% of their nominal values (e.g., +10% for +12V is 13.2 V and 5.5 V for +5V).
Inrush Current
Inrush current, or switch-on surge, refers to the maximum, instantaneous input current drawn by an electrical device when it is first turned on. A large enough inrush current can cause the tripping of circuit breakers and fuses and may also damage switches, relays, and bridge rectifiers. As a result, the lower the inrush current of a PSU right as it is turned on, the better.
Inrush current is high with 230 V input. This requires EVGA's attention, and a higher-resistance NTC thermistor.
Leakage Current
We use a GW Instek GPT-9904 electrical safety tester to measure the leakage current. According to the IEC-60950-1 regulation, no power supply should exceed 3.5 mA of leakage current, which is low enough not to harm anyone touching the chassis. This test is performed at 110% of the rated input voltage.
Leakage current is at normal levels, well below the limit.