Keywords: pretraining, domain adaptation, robustness
Abstract: Models trained on a labeled source domain (e.g., bright, nearby astronomical objects) often generalize poorly when deployed on an out-of-distribution (OOD) target domain (e.g., faint, distant objects). In the domain adaptation setting where unlabeled target data is available, self-supervised pretraining (e.g., masked autoencoding or contrastive learning) is a promising method to mitigate this performance drop. Pretraining improves OOD error when the generic data augmentations used (e.g., masking or cropping) connect the source and target domains, which may be far apart in the input space. In this paper, we show on real-world tasks that standard fine-tuning after pretraining does not consistently improve OOD error over just supervised learning on labeled source data. To better leverage pretraining for distribution shifts, we propose Connect Later: after pretraining with generic augmentations to learn good representations within the source and target domains, fine-tune with targeted augmentations designed with knowledge of the distribution shift to better connect the domains. Connect Later improves average OOD error over standard fine-tuning and supervised learning with targeted augmentations on 4 real-world datasets: astronomical time-series classification (AstroClassification) by 12%, redshift prediction for astronomical time-series (Redshifts) by 0.03 RMSE (11% relative), wildlife species identification (iWildCam-WILDS) by 0.9%, and tumor detection (Camelyon17-WILDS), achieving the state-of-the-art on AstroClassification, iWildCam-WILDS with ResNet-50, and Camelyon17-WILDS with DenseNet121.
Submission Number: 82
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