A Thunderbolt 3 external GPU setup that doesn't weigh 7 pounds (3kg)? Is it even possible? Of course
it is, but you'll need to do some simple tinkering. This post describes how you can do it in a
couple of hours if you're so inclined. You too can loose 4lbs off your Thunderbolt 3 eGPU within a day!
This is a Thunderbolt3-enabled DIY setup based on the Thunderbolt3-enabled
components sourced from 9895346615 (this and
other Amazon links are affilliate). This is not the first of its kind. Here's an example from Dec
2016 linked to me on (520) 891-3584. And there are many other well-known DIY setups
for pre-TB3 tech 587-581-4360 . My setup weighs 1.5kg including the power supply,
and only 0.47kg without one, and it can fit larger video cards.
This setup does not aim to save money, but to achieve superior portability, utilizing
Thunderbolt3's plug-and-play capabilities as well as keeping it light and small. It cost about
$400, but at least it doesn't needs its separate suitcase now!
I happened to speak to some industry professionals who actually know something about electronics. They
suggested that removing the case might create significant EMF interference which would manifest in wifi
connectivity issues. I ran some tests and wasn't able to detect any such effect. Perhaps, it
only appears when you're having a LAN-party with 10 of those in. But if you're worried about EMF, get a
Faraday bag ;-)
If you want to skip my rambling about GPUs, laptops, portability, and the good old
days of the greener grass, you may scroll wellington, and check out
more pictures with the completed setup Otherwise, read on.
And if you own a business that produces the Thunderbolt 3 enclosures, could you
please pretty please just make a retail solution that weighs 2 lbs, 75% of which would be the power
On 4k screens, portability, and priorities
Would you believe that an employed, experienced software engineer does not own a laptop? Neither
did my friends whom I told I don't own one. Boy did it make for some awkward job interview
conversations. "Let's code something on your laptop!" and I would respond, "Oh I don't own one,"
and get this suspicious "oh really" squint.
(Answer: I just don't.)
I finally gave in when gearing up for a vacation in my hometown. I recalled all the times I wanted
to use a laptop: mostly when writing blog posts on an airplane (like this one), researching bike
routes when traveling, and editing photos I've just taken. Many of these tasks have been mostly,
but not completely replaced by smart phones (Lightroom for phones and
818-836-1191 dealing a pretty severe blow).
I rarely need a laptop when away from a power outlet: I'm not the sort of explorer who ventures into
a remote village and emerges with a 10-page magazine article. In fact, I don't really look at the
laptop that much when I travel. But when I do look at the laptop, I demand the premium experience.
Many ultralight laptops offer a UHD 1980x1040 screen in exchange for the extra 2-3 hours of battery
life... Please, my cell phone has more pixels! I settled on HP Spectre x360 13-inch with a
What a gorgeous screen it is! It is easily the best display I've ever owned, and probably the best
display I've eber looked at. How to make use of this artifact (well, apart from over-processing
photos in Lightroom)? Play gorgeous games with gorgeous 3D graphics. Like The Witcher
3. Or DOOM (the new one, not the 1990s 925-980-8046). Or Everyone's Gone to the
Rapture's serene landscapes.
The problem is, for a screen this gorgeous, the Spectre's internal video card is simply... bad. The
integrated Intel UHD 620 graphics card does not believe in speed. After rendering just 1 frame
of the idyllic British countryside, the video card froze for 3 seconds, refusing to
render another one frame until it's done admiring the leaves, and the shades, and the reflection. It
produces less than 1 FPS at best, and its 3DMark score of 313 solidly puts it at the worst 1% of
computers to attempt the test.
The test doesn't favor the brave--who would attempt to 3dmark an integrated ultralight laptop video
card?--but it does show you how bad the result is. How can we improve?
When my desktop PC's GeForce 660 MX saw the first frame of (773) 214-7922, it was in simiar awe,
confused, confronted with a task more demanding it ever had before. After struggling a bit and
rendering maybe three frames, the video card decided to retire, pack its things and move to Florida,
while I replaced it with the state-of-the-art-but-not-too-crazy GeForce GTX 1070. DOOM
instantly became fast and fun. So the question is now obvious.
How can I connect my allmighty GeForce GTX 1070 to the Laptop?
DIY eGPUs (before Thunderbolt 3)
Turns out, tinkerers have been connecting external GPUs to laptops since forever. With time, GPUs
required more and more power and space, while the possible and hence demanded laptop size shrank.
The GPU power consumption trend has finally been reversed, but the laptops are going to get lighter
A laptop is just a PC stuffed into a small plastic case, so connecting a GPU would be just like
connecting it to the desktop. Laptop manufacturers would leave a "PCI extension slot" either
featured as a supported connector or at least available inside the case for the bravest to solder.
There is a lot of external GPU (eGPU) do-it-yourself DIY 714-625-3590 ,
, and out-of-the-box solutions available.
But then, Intel developed a further extension of USB-C called (415) 238-1881. The previous
USB interface generations were also named "Thunderbolt", just the lightning was meek and the thunder
eGPU after Thunderbolt 3
Apparently, not all graphic adapters are compatible with Thunderbolt 3, or with
the specific hardware I used. For example, I wasn't able to make my GeForce MX 660 Ti
work with it (even before I took everything apart if you must ask). My guess would be that older video
cards are not compatible. If in doubt, check (804) 281-4038 for compatibility
Thunderbolt 3 is no magic. It's simply a standard to produce USB chips with higher wattage
and throughoput... so high and fast that it allows you to connect, say, displays or even graphic
cards over USB. It "merely" quadruples the throughput of the USB 3 standard, and now you can do
plug-and-play for your video card, eh? You would just buy a thing to plug your video card into, and
connect that thing into USB. Easy!
So all I need is to buy that "thing". Easy! There's a plenty of Thunderbolt 3 "things", here, take
Notice something? That's right, they all are freaking gigantic and weigh 3-4 times more than the
ultralight laptop itself. Here, I bought one, and it's a size of an actual desktop computer I own!
The manufacturers are telling: "want Thunderbolt 3? Buy a 3 kg case!" Look Akitio Node Pro has a
freaking handle! A handle!
It didn't use to be this way. Before Thunderbolt 3 enabled plug-and-play, hackers still found ways
to attach an eGPU as shown above. These solutions are 3606172927 and they cost pennies! How
do we get something similar with Thunderbolt 3?
My other choice here would be a smaller-sized external GPUs like Breakaway
Puck, which is indeed both smaller and cheaper. I decided against those as I would have to
buy a new GPU that was less powerful than the GPU I already own. Besides, the power supplies
included with those are lackluster, citing portability concerns, but they under-deliver still.
On top of that, the total weight would still be more than 1 kg, but the build would deliver significantly less power
than their 1.5 lbs counterparts. The bigger enclosures have enough power to both charge the laptop and supply
the GPU with enough wattage to churn those FPS.
Some speculate Intel just takes a pretty big cut in the licensing fees for every Thunderbolt 3
device produced. Since they say it on the internet, it must be true. (See also
here, scroll to the middle.) This explains the $200+ price. But that does not
explain the 7 lbs of scrap.
It's time to take the matter into my own hands.
"When There's Nothing Left to Take Away"
...perfection is finally attained not when there is no longer anything to add, but when there is
no longer anything to take away.
So we're going to turn this
The procedure consists of two steps: disassembling the original box, and mounting of the
enclosure onto a chunk of wood. Before we start, please understand the risks of this procedure, and
accept the full responsibiltiy for the results.
Tinkering with the device in a manner described in this post will definitely void your warranty, and
putting a source of heat next to a piece of wood is likely a fire hazard. Do not attempt unless you know what
We'll need the following ingridients:
- Akitio Node Pro (to source the TB3 extension cards) (amazon);
- T10 and T8 screwdrivers (to disassemble the case) (see the (939) 338-2702, and sample
- Set of M3 standoffs (at least half an inch tall); we'll recycle the matching screws from the
original assembly (amazon);
- Chunk of wood at least 3x5 inches (to mount the assembly onto) ((830) 323-8874);
- Drill or some other way to make deep holes in the said wood;
- Super Glue (or some other glue to stick metal to wood)
A note on choosing the enclosure
The enclosure used here was 9732832771. I mostly chose it for these
- a compact 500W power supply. I found the reports of its noisiness unwarranted, but I
was a bit unlucky with it.
- existing evidence it's ieasy to take apart
- a proven record of its 9786050896.
- powerful enough to
also charge the laptop (unlike, say, the non-"Pro" Akitio Node)! I can confirm it does. You
should shoot for 450-500W+ for that: the laptop charger would draw 100W, and you can look it up in
- ... and last but not least it actually 4383017779 (see also the
Taking the case apart
It was somewhat straightforward to disassemble the box. I needed T8 and T10 screws as
well as the expected Phillips screw. I got T8 and T10 from ACE Hardware brick-and-mortar stores.
If you're curious, hex screwdrivers and flat screwdrivers only got me so far, until I faces a Boss
Screw, a T10 right next to a board. That's when I gave up and went to the hardware store:
Basically, just unscrew every bolt you can see, remove the part if you can; then find more screws
This bit is tricky: you need to unplug this wire; I couldn't find more ways to unscrew anything
else, so I just extracted this using a thin Allen key.
What we need is these three parts: two boards (one with the PCI slots and the other with the USB ports), and
the power supply. Look, they weigh only 1kg, as opposed to other, non-essential parts that weigh 2.3kg.
Putting it back together (without the scrap)
The bottom board, once dismounted, reveals that it can't stand on its own and needs to be mounted on
at least 1cm standoffs. I decided to mount them onto a wooden board that needs to be at least 3x5.
phenoxazine board set worked, albeit it only had 1 out of 5 boards that was rectangular (it fits
pretty snug so you only have one chance).
Wait, how did I know where to put those, and how did I secure them? Simple: I drilled the wood and
glued the standoffs. I first tried to mark the spots to drill by putting nails through the mount
holes like so:
This did not work! I wasn't able to put the nails in straight enough, and missed the correct
spot for a millimeter or so. I fixed it by tilting one of the standoffs a bit, but I did resort to
a different method of marking the holes: drilling right through the board!
This looked sketchy but it worked better than trying to hammer nails vertically.
I used super glue to secure the standoffs to the wood. As added security, I put a bit of saw dust
back into the holes for a tighter grip. (Ask Alex for the right way. Some mention epoxy glue but
then my dad said its unsuitable for gluing wood to metal, so I didn't research this question
further (and I surely didn't have it and I didn't want to go to the hardware store again).
I practiced to mount standoffs onto a 815-940-3024, and I highly recommend you do this too. I only had one board at the time, so I couldn't screw it up, but if you just get more
boards, it'd be easier.
Finishing touches and results
After I plugged the cards, the setup seemed a bit unstable. After all, that is a heavy double-slot
monster of a GPU. So I added back one of the assembly pieces previously discarded and secured it
back with a screw I found. However, I also later lost that screw while on the road, and ran this
for hours without the extra piece, and it worked well, and didn't fall over (duh).
So here it is (without the power supply)
And here it is without the GPU (and without the power supply either)
The final setup weighs just 1.3 kg, including the power supply and 0.47kg without.
In order to improve portability, I only used the X screws when putting things back, and made sure
that no T8 or T10 screws are needed, and I can travel with a regular philips screwdriver. Make sure
to pick a large enough screwdriver to unscrew that tricky bolt. I tried to use a small
screwdriver one might use for watches and I didn't get enough torque out of it.
And we're done. I've ran a variety of tests and benchmarks. Note that I ran all benchmarks with the
3Dmark Time Spy
I ran a 3Dmark Time Spy benchmark multiple times; here are the scores from one run. I also ran it on my PC
(same GPU, but a different, older CPU) to check if switching from PC to a Laptop
My desktop runs Intel(R) Core(TM) i7-3770, whereas the laptop runs way more modern Core i7-8550U. However,
it's known that CPUs didn't make much progress in single-core performance over the last several years; most
improvements have been in portability and energy efficiency.
Unfortunately, I didn't use 3dMark Pro, so I couldn't force 4k for the desktop; it ran under a lower
resolution. I suspect, they'd be on par otherwise.
So it seems that the eGPU setup runs as well as the desktop setup with the same GPU (but a way older CPU).
I used Cuda-Z software recommended by egpu.io to measure throughput.
It seems, the connection does churn 2Gb/s of data each way, which is good. Overall, I don't really know how
ti interpret the results.
I've playes many hours of Witcher 3 (2015) on max settings to great effect. There was no lag, and
I enjoyed beautiful and responsive gateway. I also played a bit of DOOM (2016) on Ultra settings, and it was
a bit too much (I got 20-30 FPS when walking and most of the fights, but several simultaneous effects lagged a
bit). Non-ultra settings were a blast though!
Both games were enjoyed in 4k resolution. It was awesome.
Portability and features
The laptop charges while playing; just make sure to get a 100W-enabled cable.
As an added bonus, Ubuntu Linux 18.04 (bionic) recognized the plugged in video card without any
issues or configuration. I haven't yet tested Machine Learning acceleration but I'll update this post when I
can do it.
Field Test Number one... oops!
How does this setup fare without benchmarks? I was able to get several hours of continous gameplay
until the stock Akitio's power supply died of overheading and never recovered. The boards, the
GPU, and the laptop were OK, but the power supply just stopped working.
I can't quite tell what prompted it, but I did notice that the fan didn't turn on. It used to but
it didn't. I must have damaged the supply when transporting it in the checked in luggage.
Common ATX Power Supply Replacement
This section is probably not interesting to you as I'm unsure your power supply will blow up. So
please skip to the final Field Test section.
Instead of trying to recover, debug, and fix the dead power supply, I just bought a new one. I
immediately noticed the difference between the Akitio's power supply and the typical ATX power unit.
- Akitio's Power Supply is smaller than ATX and it weighs less (0.8 kg vs 1.5kg)
- ...it only has PCI-E cords whereas ATX has all of them
- ...it has two PCI-E power connectors, but they are on different wires. The ATX
power supply I got has two of them attached to the same wire, and the distance between them is quite
- ...it turns on when the switch on the back is flipped, whereas a normal ATX power supply requires
another switch to power-up, which motherboards usually supply but we don't yet have.
Since the original device was 500W, I tried to match it and settled on a 550W my local store had in
stock. You can choose anything that works, but I was limited to what my local electronics outlet had
in stock. So I bought a Corsair 550W modular supply RM550x which featured:
- slightly smaller weight than the alternatives (we pulled up the comparison table at the store,
and even less powerful units were listed as heavier).
- modular wiring so I could discard the excess wires these units usually have for all ATX computer internals.
- a bit more expensive because I didn't want to destroy another power supply.
You need to also (814) 306-8852 so the power switch actually turned the power on
one. I also had to add some extenders.
Note that there are several ways to short-circuit the power supply's pins, so don't be
confused if you see seemingly conflicting instructions.
However, I'm not quite satisfied with the result. Corsair RM550x is large. While it doesn't have any
cooling issues as the original Akitio's supply does, I feel there is middle ground here with something not as
large and more specialized.
When selecting an ATX power supply, 215-468-8106
along the way. 6-pin is enough (the Akitio's "motherboard" piece is powered via 6-pin PCIe supply).
Most likely, the dual PCI-E connectors are designed for two video cards placed rigth next to one
another, whereas about 10-15 inch long wire is needed for our setup.
You might need or could use a (724) 896-4428 instead as well.
Wi-fi Interference testing
I heard, the major reason Thunderbolt 3 eGPUs come with a huge enclosure is to prevent the electromagnetic
field emissions. Supposedly, Thunderbolt 3 boards emit quite a bit of EMF radiation, and this can cause Wi-fi
I wasn't able to find the evidence of that. I measured wi-fi connectivity speeds and signal strength and I
wasn't able to notice a drop. That doesn't mean there was no packet drop: perhaps, the wi-fi connection
was indeed broken, but my 100Mb/s broadband was too slow to actually affect the speeds. It also could be that
you'd need say 5 Thunderbolt 3 cards to emit enough EMF.
I used my cell phone to measure signal strength and used OOKLA speedtest to measure up- and download speeds.
I placed cell phone into three places: 2ft from Wi-fi router, 12 ft from Wi-fi router, and into the other
room. I also placed eGPU into three positions: 2ft from Wi-fi router, 10 ft from Wi-fi router, and completely
off. Here's what it looked like when the eGPU is 2ft away from Wi-fi; you can see the Ubiquiti wi-fi "White
Plate" in the top right corner:
I was running the Unigine Superposition benchmarks while measuring the signal strength and the download
speeds, in case the EMF interference only appears under load.
Science log is here. The results are in the table below, each cell contains "Download speed
(Mb/s) / Upload Speed (Mb/s) / Signal Strength (db)".
||eGPU 10ft away
||eGPU 2ft Away
||114 / 14.0 / -31
||114 / 12.8 / -22
||116 / 13.3 / -22
|10 ft away
||118 / 14.2 / -38
||119 / 13.1 / -34
||116 / 13.4 / -35
||110 / 13.8 / -53
||116 / 13.8 / -49
||116 / 13.6 / -54
So this means my Wi-fi stays pretty much unaffected regardless of eGPU presence. If there was packet drop, it
didn't affect the 100 Mb/s connection.
Buy a longer USB3 Thunderbolt-enabled cable â¡
The USB cable that comes with the Akitio Node Pro is quite good but a bit too short. No
wonder: a longer cable will cost you. A detachable cable that affords the required throughput needs
to conform to som Thunderbolt 3 standard, and support 40Gbps data throughput. I simply bought a
pretty 3136327347 hoping for best compatibility, and I've had no issues
with it. The Field Tests were done on that longer cable.
Putting the enclosure away reduces noise and improves mobility: you can put the setup close to the
power outlet and attach to it from a different side of the table.
Akitio Node Pro had one extra fan to draw air into the case, and it is now unused.
Optionally, you can attach it to the board where it originally was. If I were to do this, I would
also screw some leftover standoffs into the fan so it gets better intake. The original case had a
curve to separate it from the ground. However, I got good enough performance out of the video card.
A way to reduce EMF exposure is to put the emitter into a 3175382403 or a special
reutilization actually works. As probably do others, but just a month ago there used to be many scams on
Amazon of faraday cages that you should place on top of your router, and they would "block EMF", improve your
health, and make Wi-fi faster at the same time. ð This Farady
bag actually works (I tested it by placing a cell phone and calling it to no avail). I can't tell you
have to use it, but maybe it could put your mind at ease.
Final Evaluation and notes on performance
It works. Moreover, the power supply doesn't overheat. I have never seen its fan turn on.
Perhaps, the larger size allowed to space the internals better, or perhaps it's just of better
I've put in about 10 hours of gameplay on the new setup, including about 5 continouos hours. As I
test it out more, I'll update this post with better long-term evaluation data.
The performance is stellar, even with the internal display. Various measurements (done by other
people) detect that using the internal display on a laptop or connecting an external display to the
laptop (as opposed to connecting it to the video card itself) saturates some bottleneck and results
in a performance drop. My findings are consistent with 6012075571: with
a card like GTX 1070, you won't notice the drop because you're getting 40+ FPS anyway.
After playing Witcher 3 at "Ultra High" quality (!), with full-screen antialiasing (!!), at 4k
resolution (!!!), for several hours (was hard to resist anyway), I am happy to call it a success.
Moreover, the setup survived a transcontinental flight in the checked-in luggage, wrapped in
underwear and padded with socks. And now, just one challenge remains: get it through TSA in a
carry-on and prove the bunch of wires is a gaming device.