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IEEE Spectrum

The Rebirth of High Frequency STEM Needs Leaders From Every Generation at the Table Are Battery PoweredTrailers the Shortcut to Cleaner Long Haul Freight? IEEE Honors Robotics Pioneer Toshio Fukuda VHF Propagation: What Every RF Engineer Should Know IEEE’s Global Museum Brings Engineering History to You AI’s Wild Power Demands Are Quietly Rewriting Grid Rules Why Engineers Who Speak Up Build Stronger and Safer Careers Why Mentorship Is the Most Underrated Leadership Skill Is Melbourne the Place Where AI and Clean Energy Finally Align? The History and Mystery of Fireworks Poetry for Engineers: Nine Lives of Nikola Tesla How a Forgotten Wire Turned a Cheap Chip Into a Brainlike Neuron How the U.S. Engineered Its Sovereignty This Senior Member Solves Complex Product Lifecycle Challenges Why Does a Bank Need a Chief Scientist? What it Means to Be a Mathematician When AI Does the Math How IEEE Awardee Karen Panetta Became Bewitched by Engineering Make an Origami Circuit Board AI Learns the "Dark Art" of RF Chip Design Home Broadband Is the Killer App 5G Was Never Designed For How Smarter Grids Could Save Americans $100 Billion On Power Can AI Learn to Read the Room? Commemorating 70 Years of Artificial Intelligence War Taught this Ukrainian Entrepreneur the Value of Resilience IEEE Rolls Out Large Language Models Virtual Training Course Andrew Ng: Unbiggen AI How AI Will Change Chip Design Atomically Thin Materials Significantly Shrink Qubits
The Orbital Data Center Hype Machine Is Already in Orbit
https://www.facebook.com/48576411181 · 2026-07-01 · via IEEE Spectrum

The lowest-cost place to put AI will be in space, and that will be true within two years, maybe three at the latest,” SpaceX founder Elon Musk told the World Economic Forum in Davos this past January, as his company was preparing to go public.

Later that month, SpaceX filed an application with the Federal Communications Commission for an orbital data center constellation of up to 1 million satellites in low Earth orbit, 500 to 2,000 kilometers above Earth. And just three days before the IPO, he discussed some initial design specifications for a new AI-1 satellite data center in a video interview.

Musk is prone to hyperbole when it comes to timelines. Full self-driving cars by 2017. First human mission to Mars in 2024. Ten thousand Optimus humanoid robots by the end of 2025. Et cetera. For orbital data centers, which he says will be a cost-effective alternative to terrestrial data centers within three years, the math won’t make sense for several years, if ever.

Consider this: There are roughly 14,500 active satellites in orbit. Musk’s Starlink constellation accounts for about two thirds of those. Both the launch cadences and satellite-manufacturing capacity would have to scale up astronomically to deploy a million orbital data center satellites.

For context, there have been roughly 7,000 orbital launches in all of human history. To loft 1 million satellites into low Earth orbit on SpaceX’s Starship, which is designed to carry up to 60 satellites per vehicle, would require 16,666 launches exclusively devoted to satellite deployments. Considering that SpaceX launched a record 165 orbital missions in 2025, even at 10 times that cadence, it would take a decade. And how long would it take to build 1 million satellites, given Starlink’s current pace of around 4,000 per year and a generous tenfold increase in capacity? Short of a manufacturing revolution, try 25 years.

The reality is that the vision of massive constellations of orbital data centers is nowhere close to being realized.

As this month’s cover story, “Why Orbital Data Centers Are So Hard” by Andrew Cavalier of ABI Research, makes clear, the reality is that the vision of massive constellations of orbital data centers is nowhere close to being realized.

Dina Genkina, IEEE Spectrum’s computing and hardware editor, put the idea into perspective: “Starcloud (a startup that has applied to the FCC for an 88,000 orbital data center satellite constellation) sent one Nvidia H100 GPU in space so far. Their radiator was too weak to let the chip run at full power.”

As Cavalier shows, cooling even a single Nvidia H100 GPU in space is difficult: It draws 700 watts, which will require 1.4 square meters of radiator at 60 °C. A 40-kilowatt rack of servers will need an 80-m² radiator; a 100-megawatt data center will require 2,500 of those radiators. Some astronomers are understandably concerned that a million satellites with giant radiative wings would blot out the stars.

So if the economics doesn’t make sense, if the chips are at the mercy of the radiative ravages of space, and if humanity will lose its view of the stars, not to mention increasing the risk of triggering the Kessler syndrome, why are the hyperscalers hyping orbital data centers?

Genkina offered the obvious answer: sweet, sweet moolah. “The Elon Musk part of it is honestly genius because he’s got xAI building the data centers, SpaceX sending them to space, and Tesla building solar panels,” Genkina says. “It’s almost like he’s paying himself.”