It’s such a hilariously dumb idea I hope the tech bros sink millions into it.
Lets make a data center we can’t maintain, upgrade or access for any practical reason. Waiting for the suggestions to put them in geostationary orbits so that way their latency is even higher but going to struggle staying powered when in Earth’s shadow. Or get put in the Earth-Sun L1 so they always have solar power but now have to have significant more radiators on top of even MORE latency beyond beyond the moon’s orbit.
It makes sense if we have a space elevator and also invert the way most of the physics of data centers work.
The “good idea” isn’t the data centers but the stock pumping. You propose something insanely difficult and expensive (also hopelessly impractical and stupid in this case) and because it is so difficult and expensive you claim you can monopolize the market if you succeed which is the ultimate dream of every capitalist but you just need some insane amount of investment to get there. Then when the money runs out you go back and ask for more and exploit sunk cost fallacy. All the while valuations increasing. It is an amazing way for already rich scammers to get much, much richer than could happen in a sane economy and slurp up huge amounts of capital that otherwise could have gone into more productive endeavors.
Obviously in any well regulated economic system this shit would be subject to some proper oversight to protect the interests of the majority, particularly all the people whose pensions and livelihoods are at risk when this all goes to shit.
Just billionaire psychosis like where ai got to where it is to begin with. Obviously they’re all visionaries leading the world to a better place…
I had a conversation with a colleague of mine about this. He believed that Musk’s decision to merge xAI and SpaceX was truly because of the potential of datacenters in space. I was unable to convince him that the logistics of this would be a nightmare and that this was just a way to make the Twitter buyout SpaceX’s problem.
Imagine launching that scale of infrastructure, loaded full of Nvidia chips that’ll be outdated in like 2 years.
I skimmed the title for a sec and thought “what’s wrong with orbital stations?” before realizing the utter stupidity that graced my vision.
Do we have a way to transfer heat into rock, because I’m thinking lunar data centers.
At medium earth orbit the minimum delay will be about 67ms (250 ms to 600+ ms for geostationary orbits) for LEO it is 25-50 ms. The average ground network ping on a good day is 1ms-20ms.
If and only if someone is insane enough to develop off-planet manufacturing with the bulk of the raw materials originating from somewhere in deep space, e.g. asteroid mining, putting data centers in space might be useful for problems that demand intensive compute and can work with extreme latency.
Then again that’s like saying inventing the airplane would have been a good strategy for Neanderthals to find better firewood.
At minimum how would the heat be managed? Also as someone else said, just getting the material from the earth into orbit is currently possible but why?
Argue? It’s a physics problem that has no solution.
I don’t know how that even got past the brainfart stage. AFAIK nobody has actually demonstrated how that would really work.
- Despite SpaceX’s advancements in regards to things like resutable rockets, shooting stuff into space is still prohibitively expensive.
- Server clusters are exceptionally heavy.
- Server clusters run hot, cooling is not a triviality considering you can’t just rely on convection in space, so more mass for alternative solutions.
- Datacenters need regular maintenace.
- Logic boards won’t do well with the radiation in space.
- Despite SpaceX’s advancements in regards to things like sattelite internet, getting large datacenter level quantities of data from earth into space and back, and at low latency, is no triviality.
Not saying this won’t ever be a thing. But not in the lifetime of anybody on earth right now I don’t think.
There is an unsolvable compute problem. The average PC on earth has multiple bit-flips a year from cosmic rays. The space hardened chips we use are 50nm and the chips used from inference are 4 to 6nm. 50nm is far more cosmic ray resistant than 6nm because of the transistor size. Are we supposed to think making H100s with a 65nm process is possible? The speed of light creates a die size limitation as well.
People don’t understand just how difficult it is to cool stuff in space. Half of the shit sticking out of the ISS that people think are solar panels are actually radiant cooling systems, and the ISS will generate WAY less heat per volume than a data center.
Im seeing the ISS needs to reject 70kw with a max ability of 84kw. The datacenter dishes will be between 125 and 150, so around double or less.
Not to mention the power requirements would likely require more than solar unless they put solar panels up far bigger than anything put up there before.
It will be far bigger. Its mostly solar panels.
Or one of those mini nuclear reactors they are working on
If we did make something like that, could you even put it on a disposable dish meant to burn up in the atmosphere after 5ish years? There’s already uncertainty about all the dishes burning up and long term impacts, but a mini nuclear reactor?
The datacenters are only a little bigger than a v3 starlink. It’s 1 rack of compute, around 125kw avg 150kw peak. The biggest part is the solar array.
Not saying this won’t ever be a thing.
I’m saying it
This whole idea reminds me of the “putting solar panels on highways” idea that keeps popping up from time to time. Anyone who has ever built anything understands how stupid it is. Even if you could do it, it still wouldn’t make sense over just putting solar panels next to highways.
That, and solar windows.
Making an expensive solar panel that lets most of the energy pass through it, and is not mounted in a way to effectively collect solar energy, is a terrible idea.
I agree, that this is at the moment not a viable thing and especially the SpaceX “concept” is complete bullshit.
I do not agree with some of your points, since they are solved/irrelevant (e.g. “regular maintenance”, “low latency”) or could be overcome with reasonable tech advances (e.g. “rockets prohibitively expensive”, “radiation shielding”).
Let me steelman the argument a bit with this single bit of - sadly forgotten - “super cool and innovative tech”: “Underwater data center”, like project Natick (Microsoft) or the Chinese project:
Soooooo, if we will ever see something other than our current land based data centers, we will see millions of ocean data centers, before we will ever see a single commercial space data center.
Reasons:
- Delivery is super cheap (in comparison to space) at scale, thanks to the already existing wind farm infrastructure
- Weight is not an issue
- Cooling is solved
- Maintenance is not necessary, but replacement is. Easy on scale, because modular.
- No radiation shielding necessary
- Connection: data cable = no extra lag or quantity limit
Oh, and by the way, it is still not clear if even ocean data center will be viable. Just found this 😂
They’ll manufacture it on the moon ofc. We won’t ship it from earth.
What about the latency hit getting data back to earth?
LEO isn’t that far away. StarLink has quite good latency.
Whatever the end latency is, it’ll be higher than starlink as these are going to be in a sun synchronous orbit and they dont talk to earth, they talk via starlink.
So you’ll have to go up to starlink, then laser link the shortest route to the nearest available dish, then back.
Heh yeah you’d get daily latency variation.
You’d have to constantly adjust its orbit. Something that huge with massive radiators and solar panels is going to get a lot of drag.
1000km is still considered LEO and would take hundreds of years to decay. At this distance, you’d add 3ms of latency, which isn’t nothing but acceptable for most applications.
Unless it becomes cheaper than having a datacenter on earth per quanity of compute, it won’t happen in any meaningful scale even if these issues are solved.
You would need staff living up there to support them. Robotics isn’t up to it.
It will never be an economic thing. Only unpluggable skynet military thing. The weight is not an issue. though. It’s volume.
Weight is always the issue with lifting stuff into space. Volume might merely be an additional issue.
The $200/kg launch price target is based on 150 ton capacity. That’s a $30m launch costs target. Volume/foldability matters the most because that is the actual constraint that limits datacenter launch to a single NVL72 size.
Projected cost targets from SpaceX, especially for Starship are only losely related to reality. Weight is what determines the minimal required energy input to lift something into orbit. Independently from SpaceX number magic. Volume, like I said, can be an additional bottleneck but never undo the above.
Starship is huge. I dont know how tightly they can fold these expected dishes, but by weight, they can amd will do 60 starlink v3, and itd be 50 datacenter dishes equivalent. How many they can actually launch is going to depend on how well the solar and radiator folds down, so it might be a volume issue vs weight where they cant launch with the max weight capabilities of the ship.
If they build a data center on land and an identical one floating on the ocean, what is the difference in how much heat they emit when I throw thermite grenades at them?
Is this before or after we colonize mars?






