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Coping with Change: Learning Invariant and Minimum Sufficient Representations for Fine-Grained Visual Categorization
Fine-grained visual categorization (FGVC) is a challenging task due to
similar visual appearances between various species. Previous studies always
implicitly assume that the training and test data have the same underlying
distributions, and that features extracted by modern backbone architectures
remain discriminative and generalize well to unseen test data. However, we
empirically justify that these conditions are not always true on benchmark
datasets. To this end, we combine the merits of invariant risk minimization
(IRM) and information bottleneck (IB) principle to learn invariant and minimum
sufficient (IMS) representations for FGVC, such that the overall model can
always discover the most succinct and consistent fine-grained features. We
apply the matrix-based R{\'e}nyi's -order entropy to simplify and
stabilize the training of IB; we also design a ``soft" environment partition
scheme to make IRM applicable to FGVC task. To the best of our knowledge, we
are the first to address the problem of FGVC from a generalization perspective
and develop a new information-theoretic solution accordingly. Extensive
experiments demonstrate the consistent performance gain offered by our IMS.Comment: Manuscript accepted by CVIU, code is available at Githu
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