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ESTABLISHING UPLINK...
ESTABLISHING UPLINK...
Combining space-based solar power with distributed edge computing to create autonomous, resilient infrastructure that operates beyond terrestrial limitations.
The building blocks of our orbital infrastructure
Multi-junction solar arrays capturing 24/7 sunlight at 40%+ efficiency. Up to 12x more energy than terrestrial systems.
Distributed compute nodes running containerized workloads with Kubernetes orchestration in LEO.
Hardware-root-of-trust with E2EE, autonomous key management, and isolated execution environments.
Inter-satellite links creating resilient, self-healing network topology with dynamic routing.
Real-time trajectory calculation, collision avoidance, and predictive power allocation.
Lightweight containerd-based runtime optimized for space conditions with automatic failover.
Six layers of abstraction from orbital mechanics to user applications
User workloads, containers, serverless functions
Kubernetes-based workload scheduling across nodes
Zero-trust, E2EE, hardware root of trust
Mesh networking, edge routing, inter-node communication
Satellite nodes, solar power systems, compute resources
Physics engine, orbital mechanics, positioning
Requests flow top-down, responses bottom-up
Each layer operates independently
Higher layers abstract lower complexity
Designed for reliability in the harshest environment
Continuous solar power, zero carbon footprint
Not bound by terrestrial infrastructure or politics
Immune to earthquakes, floods, and terrestrial disruptions
Direct line-of-sight to ground stations
No single points of failure by design
Energy Comparison:
Terrestrial solar: ~150 W/m², 6-8h/day = 1.0 kWh/m²/day Space solar: ~500 W/m², 24h/day = 12 kWh/m²/day Efficiency gain: 12x more energy per m²
Coverage Calculation:
Orbital period: 90 min Daily orbits: 16 passes Coverage area: ~2,800 km diameter per pass 1 node = 70M km² average coverage