Natural Gradient Descent for Control
Abstract
This paper bridges optimization and control, and presents a novel closed-loop control framework based on natural gradient descent, offering a trajectory-oriented alternative to traditional cost-function tuning. By leveraging the Fisher Information Matrix, we formulate a preconditioned gradient descent update that explicitly shapes system trajectories. We show that, in sharp contrast to traditional controllers, our approach provides flexibility to shape the system's low-level behavior. To this end, the proposed method parameterizes closed-loop dynamics in terms of stationary covariance and an unknown cost function, providing a geometric interpretation of control adjustments. We establish theoretical stability conditions. The simulation results on a rotary inverted pendulum benchmark highlight the advantages of natural gradient descent in trajectory shaping.
Cite
@article{arxiv.2503.06070,
title = {Natural Gradient Descent for Control},
author = {Ramin Esmzad and Farnaz Adib Yaghmaie and Hamidreza Modares},
journal= {arXiv preprint arXiv:2503.06070},
year = {2025}
}
Comments
Submitted to ASME Letters in Dynamic Systems and Control (ALDSC)