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Main Authors: Hajar, Joudi, Ghane, Reza, Hassibi, Babak
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.00319
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author Hajar, Joudi
Ghane, Reza
Hassibi, Babak
author_facet Hajar, Joudi
Ghane, Reza
Hassibi, Babak
contents In the past couple of decades, non-quadratic convex penalties have reshaped signal processing and machine learning; in robust control, however, general convex costs break the Riccati and storage function structure that make the design tractable. Practitioners thus default to approximations, heuristics or robust model predictive control that are solved online for short horizons. We close this gap by extending $H_\infty$ control of discrete-time linear systems to strictly convex penalties on state, input, and disturbance, recasting the objective with Bregman divergences that admit a completion-of-squares decomposition. The result is a closed-form, time-invariant, full-information stabilizing controller that minimizes a worst-case performance ratio over the infinite horizon. Necessary and sufficient existence/optimality conditions are given by a Riccati-like identity together with a concavity requirement; with quadratic costs, these collapse to the classical $H_\infty$ algebraic Riccati equation and the associated negative-semidefinite condition, recovering the linear central controller. Otherwise, the optimal controller is nonlinear and can enable safety envelopes, sparse actuation, and bang-bang policies with rigorous $H_\infty$ guarantees.
format Preprint
id arxiv_https___arxiv_org_abs_2505_00319
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond Quadratic Costs: A Bregman Divergence Approach to H$_\infty$ Control
Hajar, Joudi
Ghane, Reza
Hassibi, Babak
Systems and Control
In the past couple of decades, non-quadratic convex penalties have reshaped signal processing and machine learning; in robust control, however, general convex costs break the Riccati and storage function structure that make the design tractable. Practitioners thus default to approximations, heuristics or robust model predictive control that are solved online for short horizons. We close this gap by extending $H_\infty$ control of discrete-time linear systems to strictly convex penalties on state, input, and disturbance, recasting the objective with Bregman divergences that admit a completion-of-squares decomposition. The result is a closed-form, time-invariant, full-information stabilizing controller that minimizes a worst-case performance ratio over the infinite horizon. Necessary and sufficient existence/optimality conditions are given by a Riccati-like identity together with a concavity requirement; with quadratic costs, these collapse to the classical $H_\infty$ algebraic Riccati equation and the associated negative-semidefinite condition, recovering the linear central controller. Otherwise, the optimal controller is nonlinear and can enable safety envelopes, sparse actuation, and bang-bang policies with rigorous $H_\infty$ guarantees.
title Beyond Quadratic Costs: A Bregman Divergence Approach to H$_\infty$ Control
topic Systems and Control
url https://arxiv.org/abs/2505.00319