Attitude Coordination Control for Formation Flying Spacecraft Based on the Rotation Matrix

Yong Guo; Jin Hua Guo; Ai Jun Li; Chang Qing Wang

doi:10.1061/(ASCE)AS.1943-5525.0000759

Attitude Coordination Control for Formation Flying Spacecraft Based on the Rotation Matrix

Yong Guo, Jin Hua Guo, Ai Jun Li, Chang Qing Wang

School of Automation

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

15 Scopus citations

Abstract

Two attitude coordination controllers that make the system converge to the equilibrium point in finite time are designed for spacecraft formation flying with actuator saturation constraints. The first finite-time attitude coordination controller is suitable for the situation that all states of the closed-loop system are available. To deal with the problem of failing to measure angular velocity, a novel filter is presented in the second finite-time attitude coordination controller. Because the model of spacecraft formation flying is established based on the rotation matrix, the closed-loop system does not have the drawback of unwinding. The theoretical analysis and simulation results are given to prove the validity of the proposed controllers.

Original language	English
Article number	04017051
Journal	Journal of Aerospace Engineering
Volume	30
Issue number	5
DOIs	https://doi.org/10.1061/(ASCE)AS.1943-5525.0000759
State	Published - 1 Sep 2017

Keywords

Actuator saturation
Coordination control
Finite-time control
Output feedback
Spacecraft formation flying

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10.1061/(ASCE)AS.1943-5525.0000759

Cite this

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title = "Attitude Coordination Control for Formation Flying Spacecraft Based on the Rotation Matrix",

abstract = "Two attitude coordination controllers that make the system converge to the equilibrium point in finite time are designed for spacecraft formation flying with actuator saturation constraints. The first finite-time attitude coordination controller is suitable for the situation that all states of the closed-loop system are available. To deal with the problem of failing to measure angular velocity, a novel filter is presented in the second finite-time attitude coordination controller. Because the model of spacecraft formation flying is established based on the rotation matrix, the closed-loop system does not have the drawback of unwinding. The theoretical analysis and simulation results are given to prove the validity of the proposed controllers.",

keywords = "Actuator saturation, Coordination control, Finite-time control, Output feedback, Spacecraft formation flying",

author = "Yong Guo and Guo, {Jin Hua} and Li, {Ai Jun} and Wang, {Chang Qing}",

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AU - Guo, Yong

AU - Guo, Jin Hua

AU - Li, Ai Jun

AU - Wang, Chang Qing

PY - 2017/9/1

Y1 - 2017/9/1

N2 - Two attitude coordination controllers that make the system converge to the equilibrium point in finite time are designed for spacecraft formation flying with actuator saturation constraints. The first finite-time attitude coordination controller is suitable for the situation that all states of the closed-loop system are available. To deal with the problem of failing to measure angular velocity, a novel filter is presented in the second finite-time attitude coordination controller. Because the model of spacecraft formation flying is established based on the rotation matrix, the closed-loop system does not have the drawback of unwinding. The theoretical analysis and simulation results are given to prove the validity of the proposed controllers.

AB - Two attitude coordination controllers that make the system converge to the equilibrium point in finite time are designed for spacecraft formation flying with actuator saturation constraints. The first finite-time attitude coordination controller is suitable for the situation that all states of the closed-loop system are available. To deal with the problem of failing to measure angular velocity, a novel filter is presented in the second finite-time attitude coordination controller. Because the model of spacecraft formation flying is established based on the rotation matrix, the closed-loop system does not have the drawback of unwinding. The theoretical analysis and simulation results are given to prove the validity of the proposed controllers.

KW - Actuator saturation

KW - Coordination control

KW - Finite-time control

KW - Output feedback

KW - Spacecraft formation flying

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JO - Journal of Aerospace Engineering

JF - Journal of Aerospace Engineering

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M1 - 04017051

ER -

Attitude Coordination Control for Formation Flying Spacecraft Based on the Rotation Matrix

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