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Singularity-Avoidance Prescribed Performance Attitude Tracking of Spacecraft

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arxiv 2206.12761 v1 pith:6Z2BT56H submitted 2022-06-26 eess.SY cs.SY

Singularity-Avoidance Prescribed Performance Attitude Tracking of Spacecraft

classification eess.SY cs.SY
keywords controlperformanceproblemconstraintschemeprescribedproposedstate
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The attitude tracking problem with preassigned performance requirements has earned tremendous interest in recent years, and the Prescribed Performance Control (PPC) scheme is often adopted to tackle this problem. Nevertheless, traditional PPC schemes have inherent problems, which the solution still lacks, such as the singularity problem when the state constraint is violated and the potential over-control problem when the state trajectory approaches the constraint boundary. This paper proposes a Singularity-Avoidance Prescribed Performance Control scheme (SAPPC) to deal with these problems. A novel shear mapping-based error transformation is proposed to provide a globally non-singular error transformation procedure, while a time-varying constraint boundary is employed to exert appropriate constraint strength at different control stages, alleviating the potential instability caused by the over-control problem. Besides, a novel piece-wise reference performance function (RPF) is constructed to provide a relevant reference trajectory for the state responding signals, allowing precise control of the system's responding behavior. Based on the proposed SAPPC scheme, a backstepping controller is developed, with the predefined-time stability technique and the dynamic surface control technique employed to enhance the controller's robustness and performance. Finally, theoretical analysis and numerical simulation results are presented to validate the proposed control scheme's effectiveness and robustness.

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