Pioneering sovereign space operation system for the future of space exploration. Reduce satellite operator OPEX by up to 60% via autonomous, software-driven operations.
At Re CAE, we're pioneering the next generation of space operations. By leveraging artificial intelligence and machine learning, we enable autonomous, software-driven satellite operations that drastically reduce dependency on ground control.
The Re CAE platform operates on sovereign principles—providing complete, end-to-end autonomy for space operations without external dependencies. In a rapidly evolving space economy, this independence is critical.
A comprehensive, integrated platform built on high-fidelity analysis and real-time adaptability. Three core pillars define our approach.
One integrated platform governing satellite attitude, orbit, and mission operations. Eliminate data silos. Enable coherent decision-making across all orbital mechanics.
Physics-based astrodynamics and structural models predict satellite behavior with unprecedented accuracy. Pre-empt failures. Optimize maneuvers before execution.
Seamless integration with third-party ground stations, proprietary hardware, and cloud infrastructure. No vendor lock-in. Your system. Your control.
Three core capabilities define autonomous space operations in the modern era.
Reduce dependency on ground-control infrastructure. Execute mission-critical decisions autonomously in real time. Operate with complete operational sovereignty.
Reduce communication latency and bandwidth requirements. Process data at the edge. Transmit only critical insights groundside. Scale across limited-connectivity environments.
Streamline space debris mitigation strategy. Adapt to environmental changes in milliseconds. Predict and respond to threats autonomously. Future-proof operations.
Four specialized tools powering autonomous satellite operations and space situational awareness.
Neural-network prediction of re-entry trajectory and survivability of space debris. Thermal flux analysis and structural dynamics modeling for precision impact forecasting.
High-fidelity astrodynamics and orbital-mechanics simulation of debris. Propagate complex trajectories, model perturbations, and forecast collision scenarios with absolute precision.
Autonomous Attitude & Orbit Control System that minimizes manual intervention. Real-time attitude determination, propellant-optimal maneuvers, and autonomous contingency response.
Cloud-based full-spectrum mission control with high-fidelity analytics. Telemetry processing, health monitoring, autonomous scheduling, and decision support for multi-satellite fleets.
Collaborating with leading organizations in space, technology, and sustainability.
Pioneering space operations with 15+ years of combined aerospace expertise.
Co-founder & CEO
PhD Computational Physics. Ex-CEA (French Atomic Energy Commission). Leading Re CAE's vision for sovereign, autonomous space operations.
Co-founder & CTO
PhD Numerical Fluid Dynamics. Ex-CEA & CNES. Architecting high-fidelity simulation and autonomous control systems.
