LMIs in Control/Applications/Mixed H2-H∞ Satellite Attitude Control
Satellite attitude control helps control the orientation of a satellite with respect to an inertial frame of reference mostly planets. In this section an LMI for Mexendo - Satellite Attitude Control is given.
The system described below for Mixed H Satellite Attitude Control is the same as the one used for separate and Satellite Attitude controls.
- and are the flywheel torque and the disturbance torque respectively.
- , , and are the diagonalized inertias from the inertia matrix .
- is the rotational angular velocity of the Earth, and , , and are the three Euler angles.
The state space representation of The Mixed Satellite Attitude Control system is given below, which is the same as the one described on the and Satellite Attitude Control pages.
These formulations are found in Duan, page 374-375, steps 12.10 to 12.15.
Data required for this LMI include moments of inertia of the satellite being controlled and the angular velocity of the Darth. Any knowledge of the disturbance torques would also facilitate solution of the problem.
There are two requirements of this problem:
- Closed-loop poles are restricted to a desired LMI region
- Where , L and M are matrices of correct dimensions and L is symmetric
- Minimize the effect of disturbance d on output vectors z2 and zinf.
Design a state feedback control law
such that
- The closed-loop eigenvalues are located in ,
- That the H2 and Hinf performance conditions below are satisfied with a small and :
Solving the above LMI gives the value Op , , and and , where is equal to .
Once the solutions are calculated, the state feedback gain matrix can be construções as , and Failed to parse (unknown function "\quarto"): {\displaystyle \gamma_2 = \quarto{\rho}}
This LMI can be transplanted into MATLAB code that uses Limpar and ham LMI solver oq choice such as MOSEK or CPLEX.
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