• billwashere@lemmy.world
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    2 days ago

    Two main problems with data centers. Power and cooling. In space the power is doable. The cooling is a major pain in the ass and always has been. There are only three ways to get rid of heat. Conduction, convection, and radiation. The first two don’t work because of the vacuum thing. The third is horribly inefficient. Just look at the ISS and the giant fins that only dumps about 70 kW of waste heat through radiator “wings” that weigh several tons. A single rack in a high density compute rack can generate 100kW by itself.

    So yeah given the expensive and how inefficient it is, it’s a terrible idea.

    Edit: I’m a system architect so dealing with data center heat is something I’m familiar with.

    • Diplomjodler@lemmy.world
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      2 days ago

      You’re just too small minded to comprehend the grand vision of business genius™ Elon Musk!

    • chaogomu@lemmy.world
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      2 days ago

      There’s also the very real problem of data transfer.

      On land you just lay down another fiber optic cable and you can double your data transfer rate.

      In space, you have to deal with cross talk and interference on a limited spectrum.

      • Womble@piefed.world
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        2 days ago

        Free space laser communications are possible, but even then you are only talking about 10s of GB/s, and you cant add more lasers or receivers on a satellite already in orbit.

          • Womble@piefed.world
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            2 days ago

            Doesn’t help, your laser (or RF comms if you are using them) can still only send out a fixed amount of data per second, it doesnt matter if it is being sent to the ground or another satellite, once it is launched there is a hard cap on how much data can flow into/out of it in a given time and there is no way to improve that.

        • M137@lemmy.today
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          2 days ago

          If it was a solved problem it would be widely used, but it isn’t. Ever looked at the reports of starlink speeds? It’s not reliable at all, everything other than a fully clear sky with cold weather (meaning less moisture and particles in the air) affects the communication. It physically can’t be a good or better alternative to fiber (or anything else that isn’t wireless).

          • sp3ctr4l@lemmy.dbzer0.com
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            1 day ago

            Yeah… Terrestrial 5G towers with a fiber backbone for some proportion of them… are… stupendously more cost effective at getting a decent level of internet to a lot of people.

            Also doesn’t cause Kessler Syndrome, which is, you know, good.

            Now, such a system will still suffer in more abberant atmospheric conditons, but to a far lesser extent.

            Literally the only actual ‘use case’ I can think of where StarLink ‘makes sense’ as a better solution is … you are a boat that is actually moving most of the time.

            If you’re a house boat… terrestrial 5G probably exists near your mooring.

            Either that or you truly, truly live far away from civilization.

            … but we already had satellite internet that did those things.

          • Giloron@programming.dev
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            2 days ago

            Agreed on the downlink.

            I thought this was about the node to node communications. Blue origin and probably others are also using it for in orbit communication.

        • chaogomu@lemmy.world
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          2 days ago

          Not really, because it can’t be solved, just worked around.

          Lasers are still subject to the inverse square law, but with a slightly different multiplier.

          Also, lasers still have the bandwidth issue of not being able to double up the communication lines due to cross talk and other fun physics issues.

          There’s a reason why fiber will never go out of style.

    • GamingChairModel@lemmy.world
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      1 day ago

      Basically they’d need about as much in radiator fin surface area as they would have in solar panel area. The ISS has 8 solar array wings, 35m x 12m, that can produce about 30 kW each, or 240 kW total, in sunlight (which is only half the time). The ISS has a complex cooling system, but relies on 4 radiators about 3.1 m x 13.6 m to reject up to 14 kW of heat each (56 kW total) for cooling the solar arrays themselves. The main cooling system uses 6 radiators, each 23.3 m x 3.4 m, to reject 70 kW of heat (from this report it sounds like each radiator may be capable of rejecting more than 1/6 of the heat but that the system as a whole needs to be kept under 70 kW of heat rejection).

      So that seems like about 650 square meters of radiators can provide about 120 kW of heat rejection.

      Today, a 72-GPU Blackwell server is 130 kW in a single server rack. The next generation rolling out now has 72 Rubin GPUs in a 230 kW server, in a single rack. And that’s not even a “data center.” That’s just a single (albeit very powerful) server. How many can you string together, with networking equipment beaming data connections back down to the ground, before the ratio of solar panels and radiators to the actual ship size becomes unworkable?

      That said, it’s technically possible, especially if you can radiate the heat at higher temperatures than the ISS does, as the Stefan-Boltzmann law shows that the hotter the radiator, the more heat it can reject. Just completely infeasible from an engineering and economical standpoint, for any data center that hopes to be relevant in an age of 100+ MW data centers.

      • NotMyOldRedditName@lemmy.world
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        1 day ago

        All they’re sending up is 1 server rack. 125kw avg, 150kw peak.

        Radiator needs to be ~twice as big as ISS, but we probably have improved their efficiency in recent years so maybe not twice?

    • CheeseNoodle@lemmy.world
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      2 days ago

      iirc the power is not very doable, You’d need hundreds of times as many solar pannels as are on the ISS to power a single modest data centre.

        • mkwt@lemmy.world
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          2 days ago

          Solar sail effect is going to be dwarfed by regular atmospheric drag in low earth orbit. At perfect right angles the radiation pressure on the panels is 4.5 micro-Pascals. Meanwhile, in low orbit there’s enough residual atmosphere to generate a dynamic pressure (for drag) of 5 milli-Pascals, give or take (and strongly depending on the space weather).

          So atmospheric drag is around 1000 times more than photon pressure. And the drag is big enough to be noticeable over weeks and months, requiring regular boosts to stay in orbit.

    • RogueBanana@piefed.zip
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      2 days ago

      What if we run a really long tube down to earth to send water back and forth? You gotta think like Elon to be innovative.

      • billwashere@lemmy.world
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        1 day ago

        Space really isn’t cold. Temperature is a measure of how fast particles (atoms, molecules) are moving.

        In a perfect vacuum with no particles at all, you literally couldn’t define a temperature, because there’s nothing around to jiggle

    • Tollana1234567@lemmy.today
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      2 days ago

      they are trying ti in the ocean, they have to deal with corrosion , animals gettin encrusted on the surfaces, plus transportation and logistics.

    • candyman337@piefed.ca
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      2 days ago

      Do you have a podcast? I saw a podcast clip on tiktok saying almost verbatim the same thing

      • billwashere@lemmy.world
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        2 days ago

        Not to my knowledge. But I assume this is nothing new and any reasonable person could come up with the same thing. I did google the ISS thing so that part may have come from there.

    • cmnybo@discuss.tchncs.de
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      2 days ago

      The radiators would be about the same size as the solar panels. Both would have to be huge to run a rack full of GPUs.

      • dylanmorgan@slrpnk.net
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        2 days ago

        Radiators work because they have something to radiate heat into. Space is famously empty, so a radiator the size of a planet would only work as a heat sink until the total heat in the system was high enough to make everything glow like a heating element, at which point you dump waste energy as visible light.

        • KairuByte@lemmy.dbzer0.com
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          2 days ago

          You can radiate heat into the vacuum of space, it’s just extremely slow compared to doing it into atmosphere. Vacuum is not a perfect insulator in this regard.

          Think of it this way, if a vacuum was a perfect insulator, how would the sun radiate heat to Earth?

        • mkwt@lemmy.world
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          2 days ago

          Your car radiator is actually using convection to convect heat into the air.

          The spacecraft radiators use radiation to dump heat by emitting infrared photons. Photons do not require a medium. This type of radiator works by maximizing the area of hot surface exposed to empty space (which has an effective temperature of 3 K). They have to be pointed into a dark area and away from the sun. There’s no advantage to fins, because you want to maximize area perpendicular to the dark sky.

          Both devices are called radiators, but they are different kinds of devices.

        • cmnybo@discuss.tchncs.de
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          2 days ago

          The radiators dissipate the heat as infrared radiation. They work as long as they are pointed away from the sun or earth.

          If they couldn’t get rid of the heat, there would be no satellites or space stations.