Full-Order Sliding Mode Control for the Attitude of the Spacecraft under Input Saturation

Yong Guo; Chao Xiao; Dawei Zhang; Ai Jun Li; Chang Qing Wang

doi:10.1061/JAEEEZ.ASENG-4598

Full-Order Sliding Mode Control for the Attitude of the Spacecraft under Input Saturation

Yong Guo, Chao Xiao, Dawei Zhang, Ai Jun Li, Chang Qing Wang

School of Automation

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

This paper proposes a robust finite-time attitude controller for spacecraft with input saturation by utilizing the full-order sliding mode control (FOSMC). Using the hyperbolic tangent function and homogeneity theory, a new full-order sliding mode (FOSM) surface was developed which makes the states of the system reach the equilibrium point in finite time. Based on the strengths of the designed FOSM surface, a robust attitude controller that makes the errors of the system converge to zero in finite time was developed for spacecraft without chattering and singularity problems. The effectiveness of the presented controller was verified via rigorous theoretical analysis and simulation results.

Original language	English
Article number	04023049
Journal	Journal of Aerospace Engineering
Volume	36
Issue number	5
DOIs	https://doi.org/10.1061/JAEEEZ.ASENG-4598
State	Published - 1 Sep 2023

Keywords

Attitude control
Finite-time control
Input saturation
Robust control
Sliding mode control

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10.1061/JAEEEZ.ASENG-4598

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title = "Full-Order Sliding Mode Control for the Attitude of the Spacecraft under Input Saturation",

abstract = "This paper proposes a robust finite-time attitude controller for spacecraft with input saturation by utilizing the full-order sliding mode control (FOSMC). Using the hyperbolic tangent function and homogeneity theory, a new full-order sliding mode (FOSM) surface was developed which makes the states of the system reach the equilibrium point in finite time. Based on the strengths of the designed FOSM surface, a robust attitude controller that makes the errors of the system converge to zero in finite time was developed for spacecraft without chattering and singularity problems. The effectiveness of the presented controller was verified via rigorous theoretical analysis and simulation results.",

keywords = "Attitude control, Finite-time control, Input saturation, Robust control, Sliding mode control",

author = "Yong Guo and Chao Xiao and Dawei Zhang and Li, {Ai Jun} and Wang, {Chang Qing}",

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T1 - Full-Order Sliding Mode Control for the Attitude of the Spacecraft under Input Saturation

AU - Guo, Yong

AU - Xiao, Chao

AU - Zhang, Dawei

AU - Li, Ai Jun

AU - Wang, Chang Qing

PY - 2023/9/1

Y1 - 2023/9/1

N2 - This paper proposes a robust finite-time attitude controller for spacecraft with input saturation by utilizing the full-order sliding mode control (FOSMC). Using the hyperbolic tangent function and homogeneity theory, a new full-order sliding mode (FOSM) surface was developed which makes the states of the system reach the equilibrium point in finite time. Based on the strengths of the designed FOSM surface, a robust attitude controller that makes the errors of the system converge to zero in finite time was developed for spacecraft without chattering and singularity problems. The effectiveness of the presented controller was verified via rigorous theoretical analysis and simulation results.

AB - This paper proposes a robust finite-time attitude controller for spacecraft with input saturation by utilizing the full-order sliding mode control (FOSMC). Using the hyperbolic tangent function and homogeneity theory, a new full-order sliding mode (FOSM) surface was developed which makes the states of the system reach the equilibrium point in finite time. Based on the strengths of the designed FOSM surface, a robust attitude controller that makes the errors of the system converge to zero in finite time was developed for spacecraft without chattering and singularity problems. The effectiveness of the presented controller was verified via rigorous theoretical analysis and simulation results.

KW - Attitude control

KW - Finite-time control

KW - Input saturation

KW - Robust control

KW - Sliding mode control

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DO - 10.1061/JAEEEZ.ASENG-4598

M3 - 文章

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SN - 0893-1321

VL - 36

JO - Journal of Aerospace Engineering

JF - Journal of Aerospace Engineering

IS - 5

M1 - 04023049

ER -

Full-Order Sliding Mode Control for the Attitude of the Spacecraft under Input Saturation

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