Title :
Optimal Control for Polynomial Systems Using Matrix Sum of Squares Relaxations
Author :
Ichihara, Hiroyuki
Author_Institution :
Dept. of Syst. Design & Inf., Kyushu Inst. of Technol., Fukuoka
fDate :
5/1/2009 12:00:00 AM
Abstract :
This note deals with a computational approach to an optimal control problem for input-affine polynomial systems based on a state-dependent linear matrix inequality (SDLMI) from the Hamilton-Jacobi inequality. The design follows a two-step procedure to obtain an upper bound on the optimal value and a state feedback law. In the first step, a direct usage of the matrix sum of squares relaxations and semidefinite programming gives a feasible solution to the SDLMI. In the second step, two kinds of polynomial annihilators decrease the conservativeness of the first design. The note also deals with a control-oriented structural reduction method to reduce the computational effort. Numerical examples illustrate the resulting design method.
Keywords :
linear matrix inequalities; optimal control; polynomials; state feedback; Hamilton-Jacobi inequality; control-oriented structural reduction method; input-affine polynomial systems; matrix sum; optimal control; polynomial systems; semidefinite programming; squares relaxations; state feedback law; state-dependent linear matrix inequality; Biology computing; Control system synthesis; Control systems; Design methodology; Linear matrix inequalities; Lyapunov method; Optimal control; Polynomials; State feedback; Upper bound; Polynomial systems; state feedback control; state-dependent linear matrix inequality (SDLMI); sum of squares (SOS);
Journal_Title :
Automatic Control, IEEE Transactions on
DOI :
10.1109/TAC.2009.2017159
