Asynchronous Splitting Design for Model Predictive Control
Abstract
This paper focuses on the design of an asynchronous dual solver suitable for embedded model predictive control (MPC) applications. The proposed solver relies on a state-of-the-art variance reduction (VR) scheme, previously used in the context of stochastic proximal gradient methods, and on the alternating minimization algorithm (AMA). The resultant algorithm, a stochastic AMA with VR, shows geometric convergence (in the expectation) to a suboptimal solution of the MPC problem and, compared to other state-of-the-art dual asynchronous algorithms, allows to tune the probability of the asynchronous updates to improve the quality of the estimates. We apply the proposed algorithm to a specific class of splitting methods, i.e., the decomposition along the length of the prediction horizon, and provide preliminary numerical results on a practical application, the longitudinal control of an Airbus passenger aircraft.
Cite
@article{arxiv.1609.05801,
title = {Asynchronous Splitting Design for Model Predictive Control},
author = {Laura Ferranti and Ye Pu and Colin N. Jones and Tamas Keviczky},
journal= {arXiv preprint arXiv:1609.05801},
year = {2016}
}
Comments
This technical report is an extended version of the paper "Asynchronous Splitting Design for Model Predictive Control" submitted to the 2016 Conference on Decision and Control