Low-complexity method for hybrid MPC with local guarantees

TL;DR

This paper introduces a low-complexity, iterative method for hybrid model predictive control problems with piece-wise affine dynamics, offering convergence guarantees and suitability for embedded systems.

Contribution

The authors develop a novel operator splitting-based algorithm that avoids mixed-integer programming, providing local convergence guarantees and efficient computation for hybrid MPC.

Findings

Achieves good closed-loop performance with significantly reduced computation times.

Provides local convergence and optimality guarantees unlike other low-complexity methods.

Competitive with ADMM in suboptimality and speed, but with added convergence assurances.

Abstract

Model predictive control problems for constrained hybrid systems are usually cast as mixed-integer optimization problems (MIP). However, commercial MIP solvers are designed to run on desktop computing platforms and are not suited for embedded applications which are typically restricted by limited computational power and memory. To alleviate these restrictions, we develop a novel low-complexity, iterative method for a class of non-convex, non-smooth optimization problems. This class of problems encompasses hybrid model predictive control problems where the dynamics are piece-wise affine (PWA). We give conditions such that the proposed algorithm has fixed points and show that, under practical assumptions, our method is guaranteed to converge locally to local minima. This is in contrast to other low-complexity methods in the literature, such as the non-convex alternating directions method of multipliers (ADMM), for which no such guarantees are known for this class of problems. By interpreting the PWA dynamics as a union of polyhedra we can exploit the problem structure and develop an algorithm based on operator splitting procedures. Our algorithm departs from the traditional MIP formulation, and leads to a simple, embeddable method that only requires matrix-vector multiplications and small-scale projections onto polyhedra. We illustrate the efficacy of the method on two numerical examples, achieving good closed-loop performance with computational times several orders of magnitude smaller compared to state-of-the-art MIP solvers. Moreover, it is competitive with ADMM in terms of suboptimality and computation time, but additionally provides local optimality and local convergence guarantees.