The orbital energy platform for

high-energy missions


Satellives is building the modular energy infrastructure that powers the industrialisation of space.


Space operations are

power-constrained

Modern satellites are monoliths designed around scarcity. In classical designs, battery volume limits mission capability, creating single points of failure where a power loss means mission death.


As the $1.8T space economy demands high-energy applications like edge AI, quantum communication and in-space manufacturing, the monolithic satellite architecture is no longer viable.


INTRODUCING THE

"TILE" ARCHITECTURE

A fully functional flat satellite that stacks for launch and unfolds for power

  • Phase 1: Modularity

    We replace the monolithic satellite bus with a standardised, fault-tolerand architecture. Our 5cm-tall "Tiles" stack vertically for launch density and unfold horizontally via specific docking ports to create a seamless platform. This decentralised approach eliminates single points of failure: if one module degrades, the mission continutes, providing a level of redundancy that legacy satellite designs cannot match.

  • Phase 2: Reconfigurability

    Our platform is evolutionary. Utilising a patent-pending hinge system, individual tiles can physically "walk" to adjacent positions to self-reconfigure the platform's geometry in orbit. This hardware agility allows the infrastructure to adapt to new mission requirements dynamically, and self-repair by isolating damaged units. 

  • Phase 3: The Power Grid

    The ultimate vision is the decoupling of payload from infrastructure. We transform into a shared utility where clients dock standardised "payload boxes" directly to our grid, instantly accessing high-wattage power and station-keeping. This enables multiple high-energy missions to run in parallel, allowing customers to focus on revenue generation rather than building custom buses.

Satellives platforms enable

high-energy missions

Fiber Optics

Laser & Quantum Communications


High-bandwith laser terminals and quantum encryption keys demand continuous, high-wattage stability that legacy buses cannot sustain. Our platform delivers the persisten energy required, ensuring your secure connectivity links remain active without constraints.

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Semiconductors

In-Orbit Data Centres & Edge AI


Transform raw data into intelligence without the downlink bottleneck. We provide the massive power reserves needed for vacuum-cooled servers, enabling orbital cloud computing, real-time AI processing and safe backup storage.

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On Orbit Servicing

In-Space Manufacturing


From biomedical research to autonomous 3D printing, industrial production requires a stable, high-energy utility grid. Our reconfigurable platform acts as your power station and structural base so you can focus on the product, not the bus.

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Join the Orbital Grid

Built for

Sustainability & security

Deorbiting & debris mitigation


 resilience & fault tolerance


Future-proof cybersecurity

Our modular architecture allows for the surgical removal of defective hardware. Faulty tiles can be mechanically isolated, undocked, and deorbited, all while preserving the main platform's functionality.

By eliminating single points of failure, our platform ensures that missions continue uninterrupted, even if modules degrade. Our self-reconfiguring hinge system allows the grid to physically route power and data around damaged units, guaranteeing uptime for your critical high-energy payloads.

We secure your data with a hardened digital architecture designed for the post-quantum era. From command links to AI processing, our platform integrates Post-Quantum Cryptography (PQC) standards, ensuring your sensitive information remains secure against emerging threats.

Team

An international team with technical heritage from TU Wien Space Team, FHWN & ESA

Lilly Satellives
Kristóf Satellives