English

Symbolic Optimal Control

Optimization and Control 2018-09-05 v2 Systems and Control

Abstract

We present novel results on the solution of a class of leavable, undiscounted optimal control problems in the minimax sense for nonlinear, continuous-state, discrete-time plants. The problem class includes entry-(exit-)time problems as well as minimum time, pursuit-evasion and reach-avoid games as special cases. We utilize auxiliary optimal control problems (`abstractions') to compute both upper bounds of the value function, i.e., of the achievable closed-loop performance, and symbolic feedback controllers realizing those bounds. The abstractions are obtained from discretizing the problem data, and we prove that the computed bounds and the performance of the symbolic controllers converge to the value function as the discretization parameters approach zero. In particular, if the optimal control problem is solvable on some compact subset of the state space, and if the discretization parameters are sufficiently small, then we obtain a symbolic feedback controller solving the problem on that subset. These results do not assume the continuity of the value function or any problem data, and they fully apply in the presence of hard state and control constraints.

Keywords

Cite

@article{arxiv.1709.07333,
  title  = {Symbolic Optimal Control},
  author = {Gunther Reissig and Matthias Rungger},
  journal= {arXiv preprint arXiv:1709.07333},
  year   = {2018}
}

Comments

corrected Theorem V.6; simplified definitions of plants, controllers and closed-loops; references added; full proof of Th VII.3 rather than just a sketch

R2 v1 2026-06-22T21:50:39.581Z