Additional technical assistance: Peter McFarland and Jeremy Price.
Correctly testing power supplies is a complex procedure and KitGuru have configured a test bench which can deliver up to a 2,000 watt DC load. Due to public requests we have changed our temperature settings – previously we rated with ambient temperatures at 25C, we have increased ambient temperatures by 10c (to 35c) in our environment to greater reflect warmer internal chassis conditions.
We use combinations of the following hardware:
• SunMoon SM-268
• CSI3710A Programmable DC load (+3.3V and +5V outputs)
• CSI3711A Programmable DC load (+12V1, +12V2, +12V3, and +12V4)
• Extech Power Analyzer
• Extech MultiMaster MM570 digital multimeter
• SkyTronic DSL 2 Digital Sound Level Meter (6-130dBa)
• Digital oscilloscope (20M S/s with 12 Bit ADC)
• Variable Autotransformer, 1.4 KVA
We test the EVGA SuperNova P2 1200 power supply with the fan in the ‘normal’ state.
DC Output Load Regulation
|
||||||||||
Combined DC Load |
+3.3V
|
+5V
|
+12V
|
+5VSB
|
-12V | |||||
A
|
V
|
A
|
V
|
A
|
V
|
A
|
V
|
A | V | |
100W
|
1.55
|
3.32
|
1.75
|
5.03
|
6.65
|
12.18
|
0.50
|
5.02
|
0.20
|
-12.07
|
200W
|
3.13
|
3.32
|
3.50
|
5.03
|
13.50
|
12.16
|
1.00
|
5.01
|
0.20
|
-12.07
|
400W |
6.40
|
3.32
|
7.05
|
5.03
|
27.50
|
12.14
|
1.50
|
5.01
|
0.30
|
-12.07
|
600W |
9.80
|
3.31
|
10.77
|
5.03
|
41.70
|
12.11
|
2.00
|
5.01
|
0.30
|
-12.07
|
800W
|
13.25
|
3.31
|
14.55
|
5.02
|
56.40
|
12.08
|
2.50
|
5.00
|
0.50
|
-12.08
|
1000W | 16.55 | 3.31 | 15.75 | 5.01 | 71.40 | 12.05 | 3.00 | 5.00 | 0.60 | -12.08 |
1200W | 22.01 | 3.30 | 22.01 | 5.00 | 85.00 | 12.03 | 3.60 | 5.00 | 0.80 | -12.08 |
Load regulation is absolutely superb holding close to reference on all the rails.
EVGA SuperNova P2 1200 | Maximum Load |
1333 Watts |
We managed to get another 133 watts from the power supply before the protection circuitry kicked in. The supply was undamaged and it was ready to fire up again when we dropped the load to a more realistic level.
Next we want to try Cross Loading. This basically means loads which are not balanced. If a PC for instance needs 500W on the +12V outputs but something like 30W via the combined 3.3V and +5V outputs then the voltage regulation can fluctuate badly.
Cross Load Testing | +3.3V | +5V | +12V | -12V | +5VSB | |||||
A | V | A | V | A | V | A | V | A | V | |
1190W | 4.0 | 3.33 | 3.0 | 5.03 | 88.0 | 12.01 | 0.2 | -12.02 | 0.50 | 5.02 |
240W | 19.0 | 3.32 | 22.0 | 5.00 | 2.5 | 12.09 | 0.2 | -12.04 | 0.50 | 5.02 |
The EVGA SuperNova P2 1200 power supply delivered a great set of results in the demanding Cross load test, as shown above.
We then used an oscilloscope to measure AC ripple and noise present on the DC outputs. We set the oscilloscope time base to check for AC ripple at both high and low ends of the spectrum. ATX12V V2.2 specification for DC output ripple and noise is defined in the ATX 12V power supply design guide.
ATX12V Ver 2.2 Noise/Ripple Tolerance
|
|
Output
|
Ripple (mV p-p)
|
+3.3V
|
50
|
+5V
|
50
|
+12V1
|
120
|
+12V2
|
120
|
-12V
|
120
|
+5VSB
|
50
|
Obviously when measuring AC noise and ripple on the DC outputs the cleaner (less recorded) means we have a better end result. We measured this AC signal amplitude to see how closely the unit complied with the ATX standard.
AC Ripple (mV p-p) | ||||
DC Load | +3.3V | +5V | +12V | 5VSB |
100W | 10 | 5 | 5 | 5 |
200W | 10 | 5 | 5 | 5 |
400W | 10 | 5 | 10 | 5 |
600W | 10 | 5 | 10 | 5 |
800W | 10 | 5 | 10 | 10 |
1000W | 15 | 5 | 15 | 10 |
1200W | 15 | 10 | 15 | 10 |
These are some seriously good ripple suppression figures that any manufacturer would be proud to achieve. As good as we have seen, even in this high end sector. Bravo!
Efficiency (%)
|
|
100W
|
85.7
|
200W
|
88.8
|
400W
|
92.9
|
600W
|
94.4
|
800W
|
93.7
|
1000W | 92.8 |
1200W | 92.4 |
The overall efficiency results are excellent, peaking at 94.4% at 600W. This drops to 92.4% efficiency at full load, a very impressive result overall.
We take the issue of noise very seriously at KitGuru and this is why we have built a special home brew system as a reference point when we test noise levels of various components. Why do this? Well this means we can eliminate secondary noise pollution in the test room and concentrate on components we are testing. It also brings us slightly closer to industry standards, such as DIN 45635.
Today to test the Power Supply we have taken it into our acoustics room environment and have set our SkyTronic DSL 2 Digital Sound Level Meter (6-130dBa) one meter away from the unit. We have no other fans running so we can effectively measure just the noise from the unit itself.
As this can be a little confusing for people, here are various dBa ratings in with real world situations to help describe the various levels.
KitGuru noise guide
10dBA – Normal Breathing/Rustling Leaves
20-25dBA – Whisper
30dBA – High Quality Computer fan
40dBA – A Bubbling Brook, or a Refrigerator
50dBA – Normal Conversation
60dBA – Laughter
70dBA – Vacuum Cleaner or Hairdryer
80dBA – City Traffic or a Garbage Disposal
90dBA – Motorcycle or Lawnmower
100dBA – MP3 Player at maximum output
110dBA – Orchestra
120dBA – Front row rock concert/Jet Engine
130dBA – Threshold of Pain
140dBA – Military Jet takeoff/Gunshot (close range)
160dBA – Instant Perforation of eardrum
Noise (dBA)
|
|
100W
|
28.0
|
200W
|
28.0
|
400W
|
30.8
|
600W
|
31.9
|
800W | 32.7 |
1000W | 33.8 |
1200W | 35.5 |
The EVGA SuperNova P2 1200 is a very quiet power supply, barely registering on our equipment until 800 watts is demanded. Even then it is very quiet. At full load, the fan spins up to compensate, but if you need to deliver a constant 1,200 watts then you need to be thinking about a 1,500 watt or greater power supply anyway.
Temperature (c)
|
||
Intake
|
Exhaust
|
|
100W
|
35
|
38
|
200W
|
35
|
41
|
400W
|
37
|
44
|
650W
|
43
|
50
|
800W
|
45
|
52
|
1000W | 47 | 58 |
1200W | 50 | 62 |
Temperatures are well controlled as the fan spins actively once load hits 900W load and beyond.
Maximum load
|
Efficiency
|
1333W
|
91.6
|
Pushing the power supply above its rated limits generates an efficiency level of around 91.6%. This is not a viable ‘real world’ situation, but its interesting nonetheless.