Robust Least-Squares Optimization for Data-Driven Predictive Control: A Geometric Approach
Abstract
The paper studies a geometrically robust least-squares problem that extends classical and norm-based robust formulations. Rather than minimizing residual error for fixed or perturbed data, we interpret least-squares as enforcing approximate subspace inclusion between measured and true data spaces. The uncertainty in this geometric relation is modeled as a metric ball on the Grassmannian manifold, leading to a min-max problem over Euclidean and manifold variables. The inner maximization admits a closed-form solution, enabling an efficient algorithm with a transparent geometric interpretation. Applied to robust finite-horizon linear-quadratic tracking in data-enabled predictive control, the method improves upon existing robust least-squares formulations, achieving stronger robustness and favorable scaling under small uncertainty.
Cite
@article{arxiv.2511.09242,
title = {Robust Least-Squares Optimization for Data-Driven Predictive Control: A Geometric Approach},
author = {Shreyas Bharadwaj and Bamdev Mishra and Cyrus Mostajeran and Alberto Padoan and Jeremy Coulson and Ravi N. Banavar},
journal= {arXiv preprint arXiv:2511.09242},
year = {2026}
}
Comments
Accepted to the 8th Annual Learning for Dynamics & Control Conference June 17-19 2026, USC, Los Angeles, USA