Geodesic
Robust optimal PID controller design for attitude stabilization of flexible spacecraft
Kybernetika, Tome 54 (2018) no. 5, pp. 1049-1070
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This paper presents a novel robust optimal control approach for attitude stabilization of a flexible spacecraft in the presence of external disturbances. An optimal control law is formulated by using concepts of inverse optimal control, proportional-integral-derivative control and a control Lyapunov function. A modified extended state observer is used to compensate for the total disturbances. High-gain and second order sliding mode algorithms are merged to obtain the proposed modified extended state observer. The second method of Lyapunov is used to demonstrate its properties including the convergence rate and ultimate boundedness of the estimation error. The proposed controller can stabilize the attitude control system and minimize a cost functional. Moreover, this controller achieves robustness against bounded external disturbances and the disturbances caused by the elastic vibration of flexible appendages. Numerical simulations are provided to demonstrate the performance of the developed controller.
This paper presents a novel robust optimal control approach for attitude stabilization of a flexible spacecraft in the presence of external disturbances. An optimal control law is formulated by using concepts of inverse optimal control, proportional-integral-derivative control and a control Lyapunov function. A modified extended state observer is used to compensate for the total disturbances. High-gain and second order sliding mode algorithms are merged to obtain the proposed modified extended state observer. The second method of Lyapunov is used to demonstrate its properties including the convergence rate and ultimate boundedness of the estimation error. The proposed controller can stabilize the attitude control system and minimize a cost functional. Moreover, this controller achieves robustness against bounded external disturbances and the disturbances caused by the elastic vibration of flexible appendages. Numerical simulations are provided to demonstrate the performance of the developed controller.
DOI : 10.14736/kyb-2018-5-1049
Classification : 93C10, 93C95, 93D15
Keywords: robust optimal control; inverse optimal control; control Lyapunov function; extended state observer; flexible spacecraft 
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Pukdeboon, Chutiphon. Robust optimal PID controller design for attitude stabilization of flexible spacecraft. Kybernetika, Tome 54 (2018) no. 5, pp. 1049-1070. doi: 10.14736/kyb-2018-5-1049

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