Abstract
Space mission design places a premium on cost and operational efficiency. The search for new science and life beyond Earth calls for spacecraft that can deliver scientific payloads to geologically rich yet hazardous landing sites. At the same time, the last four decades of optimization research have put a suite of powerful optimization tools at the fingertips of the controls engineer. As we enter the new decade, optimization theory, algorithms, and software tooling have reached a critical mass to start seeing serious application in space vehicle guidance and control systems. This survey paper provides a detailed overview of recent advances, successes, and promising directions for optimization-based space vehicle control. The considered applications include planetary landing, rendezvous and proximity operations, small body landing, constrained attitude reorientation, endo-atmospheric flight including ascent and reentry, and orbit transfer and injection. The primary focus is on the last ten years of progress, which have seen a veritable rise in the number of applications using three core technologies: lossless convexification, sequential convex programming, and model predictive control. The reader will come away with a well-rounded understanding of the state-of-the-art in each space vehicle control application, and will be well positioned to tackle important current open problems using convex optimization as a core technology.
Original language | English (US) |
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Pages (from-to) | 282-315 |
Number of pages | 34 |
Journal | Annual Reviews in Control |
Volume | 52 |
DOIs | |
State | Published - Jan 2021 |
Externally published | Yes |
Bibliographical note
Publisher Copyright:© 2021 Elsevier Ltd
Keywords
- Atmospheric reentry
- Attitude reorientation
- Convex optimization
- Interplanetary trajectory
- Model predictive control
- Optimal control
- Orbit transfer and injection
- Rocket ascent
- Rocket landing
- Small body landing
- Spacecraft rendezvous
- Trajectory optimization