Sampling-Based Control via Entropy-Regularized Optimal Transport
Abstract
Sampling-based model predictive control methods like MPPI and CEM are essential for real-time control of nonlinear robotic systems, particularly where discontinuous dynamics preclude gradient-based optimization. However, these methods derive from information-theoretic objectives that are agnostic to the geometry of the control problem, leading to pathological behaviors such as mode-averaging when the cost landscape is complex. We present OT-MPC, a sampling-based algorithm that overcomes these limitations through an entropy-regularized optimal transport formulation. By computing an optimal coupling between candidate control sequences and low-cost proposals, OT-MPC refines candidates toward nearby promising samples while coordinating updates across the ensemble to maintain coverage of the solution space. We derive closed-form, gradient-free updates via the Sinkhorn algorithm, enabling real-time performance. Experiments on navigation, manipulation, and locomotion tasks demonstrate improved success rates over existing methods.
Cite
@article{arxiv.2605.02147,
title = {Sampling-Based Control via Entropy-Regularized Optimal Transport},
author = {Vincent Pacelli and Akash Ratheesh and Evangelos A. Theodorou},
journal= {arXiv preprint arXiv:2605.02147},
year = {2026}
}
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18 Pages