Computationally Efficient Trajectory Optimization for Linear Control Systems with Input and State Constraints
Abstract
This paper presents a trajectory generation method that optimizes a quadratic cost functional with respect to linear system dynamics and to linear input and state constraints. The method is based on continuous-time flatness-based trajectory generation, and the outputs are parameterized using a polynomial basis. A method to parameterize the constraints is introduced using a result on polynomial nonpositivity. The resulting parameterized problem remains linear-quadratic and can be solved using quadratic programming. The problem can be further simplified to a linear programming problem by linearization around the unconstrained optimum. The method promises to be computationally efficient for constrained systems with a high optimization horizon. As application, a predictive torque controller for a permanent magnet synchronous motor which is based on real-time optimization is presented.
Cite
@article{arxiv.1211.5761,
title = {Computationally Efficient Trajectory Optimization for Linear Control Systems with Input and State Constraints},
author = {Jean-Francois Stumper and Ralph Kennel},
journal= {arXiv preprint arXiv:1211.5761},
year = {2012}
}
Comments
Proceedings of the American Control Conference (ACC), pp. 1904-1909, San Francisco, USA, June 29 - July 1, 2011