Quantifying and Improving Transferability in Domain Generalization

TL;DR

This paper introduces a formal measure of transferability in domain generalization, analyzes existing algorithms, and proposes a new method that improves transferability and outperforms current state-of-the-art approaches.

Contribution

It defines and quantifies transferability in domain generalization, provides theoretical bounds, and develops a new algorithm that enhances feature transferability.

Findings

Many algorithms do not learn highly transferable features.

The proposed algorithm improves transferability across benchmarks.

Theoretical bounds relate transferability to target error.

Abstract

Out-of-distribution generalization is one of the key challenges when transferring a model from the lab to the real world. Existing efforts mostly focus on building invariant features among source and target domains. Based on invariant features, a high-performing classifier on source domains could hopefully behave equally well on a target domain. In other words, the invariant features are \emph{transferable}. However, in practice, there are no perfectly transferable features, and some algorithms seem to learn "more transferable" features than others. How can we understand and quantify such \emph{transferability}? In this paper, we formally define transferability that one can quantify and compute in domain generalization. We point out the difference and connection with common discrepancy measures between domains, such as total variation and Wasserstein distance. We then prove that our transferability can be estimated with enough samples and give a new upper bound for the target error based on our transferability. Empirically, we evaluate the transferability of the feature embeddings learned by existing algorithms for domain generalization. Surprisingly, we find that many algorithms are not quite learning transferable features, although few could still survive. In light of this, we propose a new algorithm for learning transferable features and test it over various benchmark datasets, including RotatedMNIST, PACS, Office-Home and WILDS-FMoW. Experimental results show that the proposed algorithm achieves consistent improvement over many state-of-the-art algorithms, corroborating our theoretical findings.