Optimal Control Problems with Symmetry Breaking Cost Functions
Abstract
We investigate symmetry reduction of optimal control problems for left-invariant control systems on Lie groups, with partial symmetry breaking cost functions. Our approach emphasizes the role of variational principles and considers a discrete-time setting as well as the standard continuous-time formulation. Specifically, we recast the optimal control problem as a constrained variational problem with a partial symmetry breaking Lagrangian and obtain the Euler--Poincar\'e equations from a variational principle. By applying a Legendre transformation to it, we recover the Lie-Poisson equations obtained by A. D. Borum [Master's Thesis, University of Illinois at Urbana-Champaign, 2015] in the same context. We also discretize the variational principle in time and obtain the discrete-time Lie-Poisson equations. We illustrate the theory with some practical examples including a motion planning problem in the presence of an obstacle.
Cite
@article{arxiv.1701.06973,
title = {Optimal Control Problems with Symmetry Breaking Cost Functions},
author = {Anthony Bloch and Leonardo Colombo and Rohit Gupta and Tomoki Ohsawa},
journal= {arXiv preprint arXiv:1701.06973},
year = {2017}
}
Comments
Paper submitted to a journal on August 2016. Comments welcome