English

Distributionally Robust Kalman Filter

Systems and Control 2026-01-19 v3 Systems and Control Optimization and Control

Abstract

We study state estimation for discrete-time linear stochastic systems under distributional ambiguity in the initial state, process noise, and measurement noise. We propose a noise-centric distributionally robust Kalman filter (DRKF) based on Wasserstein ambiguity sets imposed directly on these distributions. This formulation excludes dynamically unreachable priors and yields a Kalman-type recursion driven by least-favorable covariances computed via semidefinite programs (SDP). In the time-invariant case, the steady-state DRKF is obtained from a single stationary SDP, producing a constant gain with Kalman-level online complexity. We establish the convergence of the DR Riccati covariance iteration to the stationary SDP solution, together with an explicit sufficient condition for a prescribed convergence rate. We further show that the proposed noise-centric model induces a priori spectral bounds on all feasible covariances and a Kalman filter sandwiching property for the DRKF covariances. Finally, we prove that the steady-state error dynamics are Schur stable, and the steady-state DRKF is asymptotically minimax optimal with respect to worst-case mean-square error.

Keywords

Cite

@article{arxiv.2512.06286,
  title  = {Distributionally Robust Kalman Filter},
  author = {Minhyuk Jang and Astghik Hakobyan and Insoon Yang},
  journal= {arXiv preprint arXiv:2512.06286},
  year   = {2026}
}
R2 v1 2026-07-01T08:12:46.006Z