Exploration

XR for Flight and Orbital Operations

Research into XR-based systems that support understanding of flight dynamics, orbital mechanics, and spatial orientation. This work explores how immersive interaction can improve comprehension of motion, trajectory, and operational context in space environments.

Autonomous and Assisted Operations:

Exploration of interaction models that support human oversight of autonomous and semi-autonomous systems. This work emphasizes situational awareness, coordination, and effective human involvement.

Human System Integration:

Study of how humans interact with tools, interfaces, and information systems in complex and constrained environments. This research focuses on aligning system design with human cognition and performance.

Research into how altered physical conditions affect perception, interaction, and task performance. Findings inform the design of interaction systems suitable for microgravity and reduced gravity environments.

Multi Domain Mission Analysis:

Research into XR-based systems that support analysis across orbital, geospatial, and operational domains simultaneously. This work focuses on integrating diverse data sources to improve understanding, planning, and decision making in complex space related missions.

Geospatial and Orbital Visualization:

Development of immersive and interactive visualizations for geospatial and orbital data. The goal is to improve insight into spatial relationships, dynamics, and large-scale system behavior.