Robustness and Consistency in Linear Quadratic Control with Untrusted Predictions

Abstract

We study the problem of learning-augmented predictive linear quadratic control. Our goal is to design a controller that balances "consistency", which measures the competitive ratio when predictions are accurate, and "robustness", which bounds the competitive ratio when predictions are inaccurate. We propose a novel λ-confident policy and provide a competitive ratio upper bound that depends on a trust parameter λ∈ [0,1] set based on the confidence in the predictions and some prediction error . Motivated by online learning methods, we design a self-tuning policy that adaptively learns the trust parameter λ with a competitive ratio that depends on and the variation of system perturbations and predictions. We show that its competitive ratio is bounded from above by 1+O()/((1)+())+O(μVar) where μVar measures the variation of perturbations and predictions. It implies that when the variations of perturbations and predictions are small, by automatically adjusting the trust parameter online, the self-tuning scheme ensures a competitive ratio that does not scale up with the prediction error .

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