Orbital Mechanics
Advanced trajectory optimization, orbital rendezvous algorithms, and efficient path planning for multi-body gravitational environments.
Research Domain
Space Science
Orbital dynamics, sensing architectures and autonomy for deep space missions. We develop intelligent systems that enable spacecraft to make critical decisions autonomously.
Research Focus Areas
Autonomous Navigation
On-board decision-making systems for spacecraft that can handle docking, debris avoidance, and mission-critical maneuvers without ground control.
Sensing & Perception
Developing robust sensor fusion architectures that work in extreme environments with limited computational resources and intermittent communication.
Deep Space Communication
Efficient protocols for high-latency, low-bandwidth communication channels. Error correction and data compression for deep space missions.
Current Projects
Orbital Autonomy Kit
On-board decisioning for docking and debris avoidance with real-time trajectory optimization.
Learn more →Deep Space Navigation System
Autonomous navigation framework for missions beyond Earth orbit using celestial navigation and AI.
Learn more →Collaborate With Us
Partner on space missions
We work with space agencies, aerospace companies, and research institutions on cutting-edge space technology.