Interpretable Gradient Descent for Kalman Gain
Optimization and Control
2025-07-23 v2 Systems and Control
Systems and Control
Abstract
We derive a decomposition for the gradient of the innovation loss with respect to the filter gain in a linear time-invariant system, decomposing as a product of an observability Gramian and a term quantifying the ``non-orthogonality" between the estimation error and the innovation. We leverage this decomposition to give a convergence proof of gradient descent to the optimal Kalman gain, specifically identifying how recovery of the Kalman gain depends on a non-standard observability condition, and obtaining an interpretable geometric convergence rate.
Keywords
Cite
@article{arxiv.2507.14354,
title = {Interpretable Gradient Descent for Kalman Gain},
author = {M. A. Belabbas and A. Olshevsky},
journal= {arXiv preprint arXiv:2507.14354},
year = {2025}
}