FSP Hydro G Pro ATX 3.0 Review

Introduction

FSP has a bit of a special place in my heart. Back in 2003, my dad bought a desktop that would last him until over a decade later, still working to this day. Powering an XFX-made (yes kids, XFX used to work with Nvidia) Nvidia FX GPU and a Pentium 4 3GHZ was a simple FSP-300-60PN. It’s an awful unit by today’s standards, with almost double the capacity on 3.3v and 5v compared to 12v, a simple switch that could kill the unit within seconds if you decided it would be funny to switch it while it runs and the now extinct -5V rail still being used on it. But even if I wouldn’t let it power any of my rigs today, it has kept that desktop working to this day, and if I wanted to, could still let it power it.

But nostalgia aside, let’s take a step back. For those not familiar with FSP, strap yourself for the ride. This is to my best knowledge:

FSP group started out as Fortron Source USA, Sparkle Power International (SPI) Taiwan and Powertech Systems Taiwan. Simple enough, right? But what’s the fun at leaving it at that? In 2002, Powertech Systems split off FSP group, with Fortron Source and Sparkle Power acquiring Protek Power Taiwan, putting the P back in FSP (sorry not sorry). Over the years, FSP group has sold their PSUs under FSP, Fortron Power (mainly for US), Sparkle Power, SPI, Huili and Quanhan, but these days mostly under the FSP brand.

Outside of their own units, FSP can be found in three other categories:

As an aftermarket PSU OEM for the likes of BeQuiet, EVGA, Antec, Silverstone, Cooler Master, NZXT and Thermaltake
As an OEM for desktops and laptops from the likes of HP, Dell, Lenovo Acer, MSI, Asus, Toshiba and many others
As an OEM for servers from the likes of HPE, Dell, Lenovo, Supermicro and many others

With that introduction out of the way, let’s get started with today’s unit, the refresh of the FSP Hydro G pro, the Hydro G pro ATX 3.0!

General Specifications

Brand	FSP
Model	Hydro G Pro ATX 3.0
Wattage	1000W
Introduction year	2022
Modularity	Fully modular
Warranty	10 years
Size	150 x 85 x 150mm
ATX 3.0 Certified	Yes, Cybenetics

Power Specifications

3.3V	5V	12V	5VSB	-12V
20a	20a	83.33a	2.5a	0.3a
120w		1000w	12.5w	3.6w

Cables

Cable type	Cable Quantity	Connector Per Cable	Gauge
ATX 20+4 pin	1	1	18-22 AWG
EPS 4+4 pin	2	1	18 AWG
PCIe Power 6+2 pin	3	2	18 AWG
PCIe 12VHPWR 12+4 pin	1	1	16-24 AWG
SATA Power	2	4	18 AWG
SATA Power + Peripheral 4 pin	2	2 / 2	18 AWG
SATA Power + Peripheral 4 pin + FDD 4 pin	1	2 / 1 / 1	18 AWG

While not visible in the table above, FSP did something… interesting with the PCIe power cables on the Hydro G pro ATX 3.0. While two of the cables are 65+15cm length, one of them is 15cm shorter. What reason FSP has for this, I honestly can’t quite figure out. But it’s nothing that would bother me when building with it, honestly. I’m already more than happy that FSP includes sufficient cables to put a high-end GPU like a 7900XTX on separate PCIe power cables, something a few other ATX 3.0 units have skipped over in favor of just two cables and a 12VHPWR cable. It would’ve been nice to see single connector cables, but this is rather uncommon to do.

Speaking of the 12VHPWR cable, this is the only cable that comes fully sleeved out of the box. It’s a bit stiff, but I’m honestly yet to see a first party cable that isn’t. It also includes two in-cable capacitors from what I can see, though I haven’t taken the sleeving off to check in risk of heavily damaging the cable.

FSP chose to include dual 4+4 pin EPS cables, which is to be expected out of a 1000w unit these days, given that they’re even sometimes supplied with as low as 650w PSUs (which is stupid because a single cable in the best case can already handle 480w on its own, but let’s not get too distracted here). Nothing to complain here, nothing out of the usual, pretty much as should be expected.

The total of fourteen SATA power connectors makes the Hydro G pro ATX 3.0 very much fun to play with for say a massive storage array at home. It’s not usual to see this much, though something like Corsair RM 2019/2021 (750w+), RMx 2021 (850w+), HX 2017 (750w+), FSP Hydro PTM (750w+), Seasonic Prime PX/TX (850w+), Vertex GX/PX (850w+) and many others are able to match or exceed this. The top position in this regard is held by Corsair (AX1500i), Cooler Master (MW Maker 1500w) and Thermaltake (DPS G RGB titanium 850w/1000w/1500w), though all three have been discontinued years ago.

The SATA cables are also combined with a total of five peripheral power connectors and even a single FDD power connector. This is mostly useful for legacy use more than anything, and I would’ve liked to have it separate from the SATA power cables, but I don’t mind it too much.

Overall, would’ve been nice to see FSP match the few companies that started using 16AWG and HCS more, but other than that… not bad!

External

“POWER NEVER ENDS”. From the side of the box as you open it to exhaust of the unit, FSP’s slogan comes back a few times on both the box and the PSU itself. It’s the very first thing I noticed when opening the box and… don’t know, it has something interesting to it.

Speaking of the box, it includes all you expect. Talk about the new ATX 3.0 specification and 12VHPWR connector, marketing around efficiency, DC-DC, semi-fanless mode, Japanese capacitors, compliance with EPS and ATX specifications and so on. Unlike most units however, it even shows an internal shot of the unit itself, though this one doesn’t look quite right. It shows a capacitor that looks to be made by Teapo, while my sample has a Nippon-Chemicon that physically looks very different. Then again, I won’t think much of this.

As you open the box, it’s divided into two sections. The left section includes the cables in a bag, a short instruction on seating the 12VHPWR connector correctly, two extra sets of stickers for the side, a few velcro straps, screws and a PSU tester (god bless). The right section is of course the unit itself, packed in foam to make sure the units gets to you in one piece. I really like the PSU tester being included. This is nothing more than a cover that goes over the 24 pin and shorts out the PWR_ON pin to a ground pin, causing the unit to turn on. This is what you normally do with a paperclip test, but this makes it way easier for an end user to do.

Now, to the unit itself. The Hydro G pro ATX 3.0 shows a relatively compact, but otherwise rather usual, but effective design we’ve seen FSP use many times before. The exhaust uses hexagons as it should (yes, I still didn’t create a hexagon cult), the unit is easy to open with just four screws on the side, of which two are covered by stickers. And speaking of stickers, as you have two extra sets of them, you can customize the look of the sides to your liking with either the stock blue or additional green and red stickers. This is something minor and probably something not that many users will utilize, as many modern cases cover the PSU entirely behind a shroud, but it’s a nice touch nonetheless.

As a final note, there’s a smaller switch next to the power on/off switch, that can be used to turn the semi-passive mode of the Hydro G pro ATX 3.0 on or off, and as a user that prefers always on, I really appreciate FSP giving a choice here.

Overall, no complaints worth mentioning here, solid job!

Protections

AC OCP	ICE2PCS02G
AC UVP	ICE2PCS02G
DC OCP	APW7159C, WT7527RA
DC OVP	APW7159C, WT7527RA
DC UVP	APW7159C, WT7527RA
OTP	APW7159C, APW9010
SCP	WT7527RA
MOV	Yes

The protection coverage FSP went here with is pretty solid. (Is it me or am I starting to sound like Aris sometimes?)

The APFC controller (Infineon ICE2PCS02G) handles OCP (Over Current Protection) and UVP (Under Voltage Protection) on the AC side, protecting the unit from brownouts and pulling too much power from the wall.

DC OCP (Over Current Protection), OVP (Over Voltage Protection) and UVP (Under Voltage Protection) is handled by both the DC-DC controller (APW7159C) and the protection IC (WT7527RA).

OTP (Over Temperature Protection) is handled by either the fan controller (APW9010) or DC-DC controller (APW7159C), but I haven’t traced this back myself, these are estimates based off the datasheet.

SCP (Short Circuit Protection) seems to be handled by the protection IC (WT7527RA), though it could be the case that other controllers are supervising this as well.

FSP went with a really nice DC-DC controller here, only having to use a single one instead of the often used two lower end controllers on PSUs. Both are totally valid ways to achieve the same end goal, but a more overkill one like this also allows to integrate things like Over Temperature Protection straight into the controller. The APFC controller is rather old, but doesn’t lack anything noteworthy from what I could see and outside of just having a single OCP channel on 12V, where at this wattage I prefer to have multiple, I have nothing to complain here. Solid setup, just lacking multirail for my own liking.

Parts Breakdown+Internal

OEM	FSP
Platform	HG2-1000 gen. 5 rev. 3
Input Voltage	100-240 VAC
Primary Converter	APFC Half-Bridge LLC
Rectifier	Synchronous Rectification
Regulator	DC-DC
Fan	Protechnic Electric MGA12012XF-O25 (ZP series G)
Bearing	Fluid Dynamic Bearing (FDB)
PCB Type	Double sided
Bulk Capacitor(s)	1x Nippon Chemi-Con KHS (450V, 680uf, 105C)
Bridge Rectifiers	2x HY GBJ2506 (600V, 25A @ 100°C)
APFC MOSFETs	2x Infineon IPA60R120P7 (600V, 16A @ 100C)
APFC Boost Diode	1x CREE C3D08060A (600V, 8A @ 150C)
APFC Controller	Infineon ICE2PCS02G*
LLC Resonant Controller	Champion CM6901T2X*
Main Switches	2x Magnachip MMFT60R115PC (600V, 20.9A @ 100C)
12v MOSFETs	6x Infineon BSC014N04LSI (40V, 123A @ 100C)*
DC-DC Converters	6x NEC 2SK3062-ZJ (60V, 70A)
DC-DC Controller	Anpec APW7159C*
Supervisor IC	Weltrend WT7527RA
Fan controller	Anpec APW9010*
5VSB Rectifier	1x CET CEF04N7G (700V, 4A)
	1x PFC P15L50SP SBR (50V, 15A)

Just four screws on the side later, I can reveal the internals…

The Hydro G Pro ATX 3.0 is made by well… FSP! While not all OEMs use their own production lines for all of their units (Seasonic, Superflower, Cougar (HEC)), I’m yet to see an FSP unit that isn’t designed and assembled in their own factories. It uses the same base platform as the regular Hydro G pro, but as main change uses six Infineon BSC014N04LSI MOSFETs for 12V compared to the weaker Toshiba TPH1R306PL MOSFETs used on the Hydro G pro. Other parts seem to have stayed the same, but given there’s only one review that details the parts used, it’s hard to say if changes over time have been made or if parts not mentioned in said review are changed for the ATX 3.0 version.

An issue worth noting with identifying some of the parts here, is that multiple parts aren’t printed or have been covered with something that looks to be resin of some sort. I was unable to identify these parts even after scratching the resin off and cleaning it with IPA, so these are based off Aris’ review over at hwbusters. These parts are marked with a star at the end.

FSP went out of their way to source a fan from Protechnic Electric, a fan manufacturer mainly known for server grade fans, and are definitely a nice choice to see here. They’re far from cheap, but offer great reliability. A very respectable choice here, well above the average.

Speaking of not cheap, FSP also went with a Nippon Chemicon KHS series main capacitor rated for 450V. This allows the unit to use a higher voltage, making it ever so slightly more efficient. I generally don’t complain when manufacturers use 400V or 420V however, as there’s still a shortage on 450V capacitors.

Honestly, looking at the overall part choice FSP made here, I have nothing specific to complain about. They used high quality parts from well known brands, made changes compared to the regular Hydro G pro where it made sense and the only thing that annoyed me is it being hard identify for myself, but this isn’t something important for the end user at all.

Electrical Performance

The following results are by third party PSU lab Cybenetics. The results shown are based off the Hydro G pro ATX 3.0 report published on 18-10-2022.

Test Equipment

Electronic Loads	Chroma 63601-5 x4
	Chroma 63600-2 x2
	63640-80-80 x20
	63610-80-20 x2
AC Sources	Chroma 6530
	Keysight AC6804B
Power Analyzers	N4L PPA1530 x2
Sound Analyzer	Bruel & Kjaer 2270 G4
Microphone	Bruel & Kjaer Type 4955-A
Data Loggers	Picoscope TC-08 x2
	Labjack U3-HV x2
Tachometer	UNI-T UT372 x2
Digital Multimeter	Keysight U1273AX
	Fluke 289
	Keithley 2015 - THD
UPS	CyberPower OLS3000E 3kVA x2
Transformer	3kVA x2

Overall (115v)

Average efficiency	88,560%
Efficiency at 2% load	67,969%
Average efficiency 5VSB	79.337
Standby power consumption (W)	0,0714
Average PF	0,991
Average noise output	27.04
Efficiency rating (ETA)	GOLD
Noise rating (LAMBDA)	A-

Overall (230v)

Average efficiency	90,806%
Average efficiency 5VSB	76,878%
Standby power consumption (W)	0,1615
Average PF	0,966
Average noise output	26.84 dB(A)
Efficiency rating (ETA)	GOLD
Noise rating (LAMBDA)	A-

Efficiency (115v)

Load (115v)	Efficiency	AC (Watts)	DC (Watts)
20w load	66,894%	29,883	19,99
40w load	77,998%	51,269	39,989
60w load	82,921%	72,342	59,987
80w load	85,718%	93,254	79,935
10% load	86,868%	115,1	99,985
20% load	90,054%	222,007	199,927
30% load	90,868%	330,115	299,968
40% load	90,914%	439,392	399,469
50% load	90,573%	551,124	499,168
60% load	90,113%	665,492	599,697
70% load	89,454%	781,873	699,419
80% load	88,671%	901,563	799,425
90% load	87,795%	1024,191	899,187
100% load	86,809%	1151,846	999,906
110% load	85,485%	1286,444	1099,721
Crossload 1	82,990%	146,129	121,272
Crossload 2	81,742%	124,028	101,383
Crossload 3	77,266%	87,185	67,364
Crossload 4	87,427%	1143,59	999,805

Efficiency (230v)

Load (230v)	Efficiency	AC (Watts)	DC (Watts)
20w load	67,834%	29,46	19,984
40w load	79,219%	50,474	39,985
60w load	84,242%	71,204	59,984
80w load	87,024%	91,834	79,918
10% load	88,209%	113,33	99,967
20% load	91,572%	218,295	199,898
30% load	92,393%	324,628	299,935
40% load	92,551%	431,506	399,364
50% load	92,478%	539,872	499,265
60% load	92,233%	650,262	599,759
70% load	91,899%	761,078	699,424
80% load	91,406%	874,56	799,404
90% load	90,876%	989,423	899,15
100% load	90,324%	1106,97	999,857
110% load	89,551%	1227,993	1099,678
Crossload 1	84,497%	143,516	121,266
Crossload 2	83,200%	121,848	101,378
Crossload 3	78,623%	85,675	67,36
Crossload 4	90,911%	1099,822	999,864

Voltage Regulation (115v)

Load (115v)	12V (voltage)	5V (voltage)	3.3V (voltage)	5VSB (voltage)
20w load	12.312V	5.062V	3.359V	5.166V
40w load	12.279V	5.061V	3.358V	5.162V
60w load	12.268V	5.061V	3.357V	5.157V
80w load	12.266V	5.06V	3.356V	5.153V
10% load	12.273V	5.058V	3.355V	5.133V
20% load	12.262V	5.054V	3.351V	5.119V
30% load	12.252V	5.051V	3.348V	5.106V
40% load	12.243V	5.047V	3.345V	5.093V
50% load	12.233V	5.043V	3.341V	5.079V
60% load	12.220V	5.036V	3.336V	5.062V
70% load	12.209V	5.031V	3.332V	5.047V
80% load	12.197V	5.027V	3.328V	5.036V
90% load	12.185V	5.023V	3.324V	5.026V
100% load	12.174V	5.018V	3.321V	5.016V
110% load	12.161V	5.014V	3.316V	5.009V
Crossload 1	12.264V	5.042V	3.34V	5.156V
Crossload 2	12.270V	5.048V	3.349V	5.164V
Crossload 3	12.260V	5.061V	3.348V	5.16V
Crossload 4	12.184V	5.031V	3.331V	5.118V

Voltage Regulation (230v)

Load (230v)	12V (voltage)	5V (voltage)	3.3V (voltage)	5VSB (voltage)
20w load	12.310V	5.061V	3.358V	5.165V
40w load	12.278V	5.06V	3.357V	5.161V
60w load	12.266V	5.06V	3.357V	5.157V
80w load	12.264V	5.06V	3.356V	5.153V
10% load	12.272V	5.058V	3.355V	5.134V
20% load	12.261V	5.054V	3.351V	5.12V
30% load	12.254V	5.052V	3.348V	5.106V
40% load	12.244V	5.048V	3.345V	5.093V
50% load	12.231V	5.041V	3.339V	5.074V
60% load	12.218V	5.035V	3.335V	5.061V
70% load	12.208V	5.032V	3.332V	5.047V
80% load	12.197V	5.028V	3.328V	5.036V
90% load	12.186V	5.024V	3.324V	5.026V
100% load	12.174V	5.019V	3.321V	5.016V
110% load	12.162V	5.015V	3.317V	5.01V
Crossload 1	12.264V	5.044V	3.341V	5.157V
Crossload 2	12.271V	5.049V	3.349V	5.164V
Crossload 3	12.260V	5.06V	3.348V	5.16V
Crossload 4	12.184V	5.03V	3.331V	5.117V

Ripple (115v)

Test	12V	5V	3.3V	5VSB	Pass/Fail
10% Load	16.93mV	8.39mV	7.79mV	9.61mV	Pass
20% Load	27.95mV	13.57mV	15.77mV	43.06mV	Pass
30% Load	24.35mV	12.81mV	13.09mV	36.33mV	Pass
40% Load	14.11mV	8.28mV	8.14mV	9.26mV	Pass
50% Load	29.41mV	12.85mV	17.44mV	38.96mV	Pass
60% Load	14.91mV	9.00mV	10.57mV	10.98mV	Pass
70% Load	32.23mV	14.99mV	19.01mV	38.15mV	Pass
80% Load	15.93mV	10.82mV	14.00mV	11.69mV	Pass
90% Load	27.14mV	15.96mV	19.92mV	36.33mV	Pass
100% Load	23.02mV	11.90mV	16.22mV	14.22mV	Pass
110% Load	23.81mV	11.90mV	17.12mV	14.49mV	Pass
Crossload1	18.81mV	14.80mV	14.84mV	10.45mV	Pass
Crossload2	16.48mV	12.09mV	10.57mV	9.82mV	Pass
Crossload3	24.35mV	12.15mV	15.62mV	36.99mV	Pass
Crossload4	23.08mV	11.18mV	15.07mV	13.88mV	Pass

Ripple (230v)

Test	12V	5V	3.3V	5VSB	Pass/Fail
10% Load	42.91mV	15.86mV	16.13mV	42.86mV	Pass
20% Load	35.32mV	15.45mV	14.71mV	41.80mV	Pass
30% Load	12.07mV	6.81mV	8.24mV	9.87mV	Pass
40% Load	36.18mV	16.46mV	18.20mV	43.21mV	Pass
50% Load	29.97mV	13.32mV	15.78mV	38.71mV	Pass
60% Load	35.24mV	16.11mV	17.95mV	41.54mV	Pass
70% Load	33.67mV	16.67mV	15.57mV	43.42mV	Pass
80% Load	16.23mV	10.82mV	14.51mV	11.54mV	Pass
90% Load	29.06mV	13.87mV	19.41mV	37.34mV	Pass
100% Load	23.60mV	15.36mV	16.52mV	13.81mV	Pass
110% Load	24.70mV	12.19mV	17.50mV	15.22mV	Pass
Crossload1	18.26mV	16.19mV	13.85mV	10.34mV	Pass
Crossload2	35.32mV	16.21mV	16.68mV	37.39mV	Pass
Crossload3	27.34mV	11.74mV	14.11mV	36.43mV	Pass
Crossload4	23.33mV	12.58mV	15.07mV	13.04mV	Pass

Fan Speed/Noise (115v)

Load (115v)	RPM	Noise (DBa)	Temperature in	Temperature out
20w load	0	<6.0	40.19°C	37.07°C
40w load	0	<6.0	40.82°C	37.46°C
60w load	0	<6.0	41.82°C	38.06°C
80w load	0	<6.0	44.08°C	40.1°C
10% load	0	<6.0	45.28°C	40.96°C
20% load	0	<6.0	46.2°C	41.46°C
30% load	0	<6.0	47.36°C	42.01°C
40% load	0	<6.0	48.52°C	42.77°C
50% load	1033	24.6	43.18°C	49.19°C
60% load	1035	24.6	43.49°C	50.23°C
70% load	1076	25.7	43.78°C	51.25°C
80% load	1509	35.8	44.23°C	52.25°C
90% load	1882	43.3	45.2°C	54.29°C
100% load	2276	47.5	45.83°C	55.85°C
110% load	2687	51.0	46.5°C	57.42°C
Crossload 1	0	<6.0	48.26°C	42.74°C
Crossload 2	939	21.6	43.89°C	50.99°C
Crossload 3	0	<6.0	52.64°C	44.56°C
Crossload 4	2019	44.4	45.29°C	55.21°C

Fan Speed/Noise (230v)

Load (230v)	RPM	Noise (DBa)	Temperature in	Temperature out
20w load	0	<6.0	39.72°C	36.61°C
40w load	0	<6.0	41.78°C	38.5°C
60w load	0	<6.0	42.51°C	39.01°C
80w load	0	<6.0	43.1°C	39.24°C
10% load	0	<6.0	44.35°C	40.11°C
20% load	0	<6.0	45.29°C	40.62°C
30% load	0	<6.0	46.62°C	41.48°C
40% load	0	<6.0	47.26°C	41.62°C
50% load	0	<6.0	48.82°C	42.88°C
60% load	1032	24.5	42.95°C	49.36°C
70% load	1152	27.8	43.47°C	50.54°C
80% load	1682	39.4	44.33°C	52.39°C
90% load	1999	43.9	44.65°C	53.66°C
100% load	2366	48.1	45.12°C	55.2°C
110% load	2788	51.6	46.61°C	57.52°C
Crossload 1	1027	24.4	42.33°C	48.81°C
Crossload 2	0	<6.0	50.75°C	43.66°C
Crossload 3	0	<6.0	52.69°C	44.62°C
Crossload 4	2088	46.1	45.63°C	55.54°C

Hold-up Time (230v)

Hold-up time (ms)	20.4
AC loss to PWR-OK hold up time (ms)	17.4
PWR_OK inactive to DC loss delay (ms)	3

Conclusion

Just like the Hela 1200R we reviewed recently, the Hydro G Pro ATX 3.0 comes in at just 150mm depth, so I would’ve tolerated the noise performance of it, but surprisingly it comes up pretty highly in that regard. FSP went with a solid part choice, build quality and exceptionally high-end fan choice, went successfully through ATX 3.0 testing over at Cybenetics, includes a native 12VHWPR cable while still keeping enough PCIe power cables to use GPUs like a 7900XTX with individual cables, supports ALPM (Alternative Low Power Mode) and has both a semi-passive and always spinning mode.

That doesn’t mean it’s perfect, however. A lot of the competition uses a higher wire gauge and terminals that allow for more current to go through the cable, which is definitely something you need for daisy chaining PCIe power cables, and can be useful for EPS power, even if it’s not needed as much there with many boards having two while housing CPUs that can’t even pull close to the limit of a single cable.

The low load efficiency isn’t poor per se, but behind its direct competition, something that with the higher and higher power costs would be nice to see getting a boost. Voltage regulation isn’t that bad either, just behind others at this pricepoint. The multirail OCP is my own controversial point, as it does cost more to integrate and is more prone to the user configuring it incorrectly, but I do consider it something nice to have with higher wattage PSUs.

Now, of course the final question I ask myself every time… Should you pick one up? Sure! It’s pretty compact, silent, includes all the connectors you need for a high end system or even a storage server and even has a native 12VHPWR connector. But it’s also not your only option, so I would also suggest looking at the alternatives below.