Probable Domain Generalization via Quantile Risk Minimization
Abstract
Domain generalization (DG) seeks predictors which perform well on unseen test distributions by leveraging data drawn from multiple related training distributions or domains. To achieve this, DG is commonly formulated as an average- or worst-case problem over the set of possible domains. However, predictors that perform well on average lack robustness while predictors that perform well in the worst case tend to be overly-conservative. To address this, we propose a new probabilistic framework for DG where the goal is to learn predictors that perform well with high probability. Our key idea is that distribution shifts seen during training should inform us of probable shifts at test time, which we realize by explicitly relating training and test domains as draws from the same underlying meta-distribution. To achieve probable DG, we propose a new optimization problem called Quantile Risk Minimization (QRM). By minimizing the -quantile of predictor's risk distribution over domains, QRM seeks predictors that perform well with probability . To solve QRM in practice, we propose the Empirical QRM (EQRM) algorithm and provide: (i) a generalization bound for EQRM; and (ii) the conditions under which EQRM recovers the causal predictor as . In our experiments, we introduce a more holistic quantile-focused evaluation protocol for DG and demonstrate that EQRM outperforms state-of-the-art baselines on datasets from WILDS and DomainBed.
Cite
@article{arxiv.2207.09944,
title = {Probable Domain Generalization via Quantile Risk Minimization},
author = {Cian Eastwood and Alexander Robey and Shashank Singh and Julius von Kügelgen and Hamed Hassani and George J. Pappas and Bernhard Schölkopf},
journal= {arXiv preprint arXiv:2207.09944},
year = {2023}
}
Comments
NeurIPS 2022 camera-ready (+ minor corrections)