Enhancing Orbital Debris Remediation with Reconfigurable Space-Based Laser Constellations

TL;DR

This paper proposes a reconfigurable satellite laser constellation system that dynamically adapts to debris distribution, significantly improving orbital debris remediation capabilities through an optimization framework and receding horizon approach.

Contribution

It introduces the R-L2D-ESP optimization framework for dynamic constellation reconfiguration, enhancing debris removal effectiveness over static systems.

Findings

Reconfigurable constellations outperform static ones in debris remediation capacity.

Dynamic reconfiguration enables deorbiting more debris objects.

Sensitivity analysis highlights key parameters affecting performance.

Abstract

Orbital debris poses an escalating threat to space missions and the long-term sustainability of Earth's orbital environment. The literature proposes various approaches for orbital debris remediation, including the use of multiple space-based lasers that collaboratively engage debris targets. While the proof of concept for this laser-based approach has been demonstrated, critical questions remain about its scalability and responsiveness as the debris population continues to expand rapidly. This paper introduces constellation reconfiguration as a system-level strategy to address these limitations. Through coordinated orbital maneuvers, laser-equipped satellites can dynamically adapt their positions to respond to evolving debris distributions and time-critical events. We formalize this concept as the Reconfigurable Laser-to-Debris Engagement Scheduling Problem (R-L2D-ESP), an optimization framework that determines the optimal sequence of constellation reconfigurations and laser engagements to maximize debris remediation capacity, which quantifies the constellation's ability to nudge, deorbit, or perform just-in-time collision avoidance maneuvers on debris objects. To manage the complexity of this combinatorial optimization problem, we employ a receding horizon approach. Our experiments reveal that reconfigurable constellations significantly outperform static ones, achieving greater debris remediation capacity and successfully deorbiting substantially more debris objects. Additionally, our sensitivity analyses identify the key parameters that influence remediation performance the most, providing essential insights for future system design. These findings demonstrate that constellation reconfiguration represents a promising advancement for laser-based debris removal systems, offering the adaptability and scalability necessary to enhance this particular approach to orbital debris remediation.