Optimization of fault-tolerant thruster configurations for satellite control

Abstract The fault tolerance of spacecraft actuators significantly affects the reliability of satellites and the likelihood of successful missions. To enhance the fault tolerance of the actuators, this study derives optimal fault-tolerant configurations of fixed thrusters that maximize the controllability of a fully-actuated or underactuated satellite. The proposed method optimizes thrust and torque directions generated by the thrusters. Thus a cost function in terms of the thruster locations and directions is defined as the summation of the generated control forces and torques with respect to the body-fixed frame. The optimal configuration is obtained by the successive use of an energy potential method that is motivated by Thomson’s problem. Some numerical examples are provided that show the effectiveness of the proposed formulation and optimization method.

[1]  Farhad Fani Saberi,et al.  Design and Analysis of Gimbal Thruster Configurations for 3-Axis Satellite Attitude Control , 2015 .

[2]  Takashi Matsuno,et al.  Three Dimensional Attitude Control of an Underactuated Satellite with Thrusters , 2011, Int. J. Autom. Technol..

[3]  Peter Wiktor,et al.  An Optimal Thruster Configuration Design and Evaluation For Quick STEP , 1994 .

[4]  Yasuhiro Yoshimura Optimal Fault-Tolerant Configurations of Control Moment Gyros , 2015 .

[5]  N. Horri,et al.  Practical Implementation of Attitude-Control Algorithms for an Underactuated Satellite , 2012 .

[6]  Roberto Alonso,et al.  Robust optimal solution to the attitude/force control problem , 2000, IEEE Trans. Aerosp. Electron. Syst..

[7]  Takashi Matsuno,et al.  Global Trajectory Design for Position and Attitude Control of an Underactuated Satellite , 2016 .

[8]  C. Samson,et al.  Time-varying exponential stabilization of a rigid spacecraft with two control torques , 1997, IEEE Trans. Autom. Control..

[9]  Christopher Masaru Pong,et al.  Autonomous Thruster Failure Recovery for Underactuated Spacecraft , 2010 .

[10]  Y. Tsuda,et al.  System design of the Hayabusa 2—Asteroid sample return mission to 1999 JU3 , 2013 .

[11]  N. Harris McClamroch,et al.  Attitude stabilization of a rigid spacecraft using two momentum wheel actuators , 1993 .

[12]  Mahmut Reyhanoglu,et al.  Attitude stabilization of a rigid spacecraft using two control torques: A nonlinear control approach based on the spacecraft attitude dynamics , 1994, Autom..

[13]  Silvio Simani,et al.  Robust FDI applied to thruster faults of a satellite system , 2010 .

[14]  Panagiotis Tsiotras,et al.  A novel approach to the attitude control of axisymmetric spacecraft , 1995, Autom..

[15]  J. Burdick,et al.  Controllability with unilateral control inputs , 1996, Proceedings of 35th IEEE Conference on Decision and Control.

[16]  Marcel J. Sidi,et al.  Spacecraft Dynamics and Control: A Practical Engineering Approach , 1997 .