Distributed control algorithms are known to reduce overall computation time compared to centralized control algorithms. However, they can result in inconsistent solutions leading to the violation of safety-critical constraints. Inconsistent solutions can arise when two or more agents compute concurrently while making predictions on each others control actions. To address this issue, we propose an iterative algorithm called Synchronization-Based Cooperative Distributed Model Predictive Control, which we presented in [1]. The algorithm consists of two steps: 1. computing the optimal control inputs for each agent and 2. synchronizing the predicted states across all agents. We demonstrate the efficacy of our algorithm in the control of multiple small-scale vehicles in our Cyber-Physical Mobility Lab.
@article{arxiv.2409.10215,
title = {Synchronization-Based Cooperative Distributed Model Predictive Control},
author = {Julius Beerwerth and Maximilian Kloock and Bassam Alrifaee},
journal= {arXiv preprint arXiv:2409.10215},
year = {2024}
}
Comments
This work was submitted to the Symposium on Systems Theory in Data and Optimization as an extended abstract