A fault-tolerant and robust controller using model predictive path integral control for free-flying space robots

A fault-tolerant and robust controller using model predictive path integral control for free-flying space robots

The use of manipulators in space missions has become popular, as their applications can be extended to various space missions such as on-orbit servicing, assembly, and debris removal. Due to space reachability limitations, such robots must accomplish their tasks in space autonomously and under sever...

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Bibliographic Details
Published in:Frontiers in robotics and AI Vol. 9; p. 1027918
Main Authors: Raisi, Mehran, Noohian, Amirhossein, Fallah, Saber
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 07-12-2022
Subjects:
model predictive path integral control
parameter uncertainity
planner-estimator model predictive path integral controller
Robotics and AI
space debris removal
space robots
parameter uncertainity
space debris removal
space robots
planner-estimator model predictive path integral controller
model predictive path integral control
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Summary:The use of manipulators in space missions has become popular, as their applications can be extended to various space missions such as on-orbit servicing, assembly, and debris removal. Due to space reachability limitations, such robots must accomplish their tasks in space autonomously and under severe operating conditions such as the occurrence of faults or uncertainties. For robots and manipulators used in space missions, this paper provides a unique, robust control technique based on Model Predictive Path Integral Control (MPPI). The proposed algorithm, named Planner-Estimator MPPI (PE-MPPI), comprises a planner and an estimator. The planner controls a system, while the estimator modifies the system parameters in the case of parameter uncertainties. The performance of the proposed controller is investigated under parameter uncertainties and system component failure in the pre-capture phase of the debris removal mission. Simulation results confirm the superior performance of PE-MPPI against vanilla MPPI.
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This article was submitted to Space Robotics, a section of the journal Frontiers in Robotics and AI
Edited by: Arun Misra, McGill University, Canada
Karol Seweryn, Space Research Center, Polish Academy of Sciences, Poland
Reviewed by: Serdar Kalaycioglu, Ryerson University, Canada
ISSN:2296-9144
2296-9144
DOI:10.3389/frobt.2022.1027918