Linear Quadratic Control with Risk Constraints

TL;DR

This paper introduces a risk-constrained extension to the classical LQ control problem, explicitly managing extreme events by limiting predictive variance and deriving explicit, stable, risk-aware controllers that adapt to noise characteristics.

Contribution

It formulates a new risk constraint for LQ control, providing explicit, closed-form solutions for risk-aware controllers that account for noise skewness and ensure stability.

Findings

Explicit risk-aware controller in closed form

Controller adjusts for noise skewness and heavy tails

Proven stability in key system cases

Abstract

We propose a new risk-constrained formulation of the classical Linear Quadratic (LQ) stochastic control problem for general partially-observed systems. Our framework is motivated by the fact that the risk-neutral LQ controllers, although optimal in expectation, might be ineffective under relatively infrequent, yet statistically significant extreme events. To effectively trade between average and extreme event performance, we introduce a new risk constraint, which explicitly restricts the total expected predictive variance of the state penalty by a user-prescribed level. We show that, under certain conditions on the process noise, the optimal risk-aware controller can be evaluated explicitly and in closed form. In fact, it is affine relative to the minimum mean square error (mmse) state estimate. The affine term pushes the state away from directions where the noise exhibits heavy tails, by exploiting the third-order moment~(skewness) of the noise. The linear term regulates the state more strictly in riskier directions, where both the prediction error (conditional) covariance and the state penalty are simultaneously large; this is achieved by inflating the state penalty within a new filtered Riccati difference equation. We also prove that the new risk-aware controller is internally stable, regardless of parameter tuning, in the special cases of i) fully-observed systems, and ii) partially-observed systems with Gaussian noise. The properties of the proposed risk-aware LQ framework are lastly illustrated via indicative numerical examples.