Title :
A primal-dual interior-point method for robust optimal control of linear discrete-time systems
Author_Institution :
Inf. Syst. Lab., Stanford Univ., CA, USA
fDate :
9/1/2000 12:00:00 AM
Abstract :
This paper describes how to efficiently solve a robust optimal control problem using recently developed primal-dual interior-point methods. One potential application is model predictive control. The optimization problem considered consists of a worst case quadratic performance criterion over a finite set of linear discrete-time models subject to inequality constraints on the states and control signals. The scheme has been prototyped in Matlab. To give a rough idea of the efficiencies obtained, it is possible to solve problems with more than 10 000 primal variables and 40 000 constraints on a workstation. The key to the efficient implementation is an iterative solver in conjunction with a Riccati-recursion invertible pre-conditioner for computing the search directions
Keywords :
Riccati equations; computational complexity; discrete time systems; duality (mathematics); iterative methods; linear systems; optimal control; performance index; predictive control; robust control; Matlab; Riccati-recursion invertible pre-conditioner; iterative solver; linear discrete-time systems; model predictive control; primal-dual interior-point method; robust optimal control; worst case quadratic performance criterion; Constraint optimization; Mathematical model; Optimal control; Polynomials; Predictive control; Predictive models; Quadratic programming; Riccati equations; Robust control; Robust stability;
Journal_Title :
Automatic Control, IEEE Transactions on
