A Constrained Bayesian Approach to Out-of-Distribution Prediction
Keywords: uncertainty quantification, probabilistic modeling, domain generalization, test-time adaptation
Abstract: Consider the problem of out-of-distribution prediction given data from multiple environments. While a sufficiently diverse collection of training environments will facilitate the identification of an invariant predictor, with an optimal generalization performance, many applications only provide us with a limited number of environments. It is thus necessary to consider adapting to distribution shift using a handful of labeled test samples. We propose a constrained Bayesian approach for this task, which restricts to models with a worst-group training loss above a prespecified threshold. Our method avoids a pathology of the standard Bayesian posterior, which occurs when spurious correlations improve in-distribution prediction. We also show that on certain high-dimensional linear problems, constrained modeling improves the sample efficiency of adaptation. Synthetic and real-world experiments demonstrate the robust performance of our approach.
Supplementary Material: pdf
TL;DR: Adapting to distribution shift by using a small number of training environments to define constraints
Other Supplementary Material: zip
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