VFM-UDA++: Improving Network Architectures and Data Strategies for Unsupervised Domain Adaptive Semantic Segmentation

Abstract: Unsupervised Domain Adaptation (UDA) has shown remarkably strong generalization from a labeled source domain to an unlabeled target domain while requiring relatively little data. At the same time, large-scale pretraining without labels of so-called Vision Foundation Models (VFMs), has also significantly improved downstream generalization. This motivates us to research how UDA can best utilize the benefits of VFMs. The earlier work of VFM-UDA showed that beyond state-of-the-art (SotA) results can be obtained by replacing non-VFM with VFM encoders in SotA UDA methods. In this work, we take it one step further and improve on the UDA architecture and data strategy themselves. We observe that VFM-UDA, the current SotA UDA method, does not use multi-scale inductive biases or feature distillation losses, while it is known that these can improve generalization. We address both limitations in VFM-UDA++ and obtain beyond SotA generalization on standard UDA benchmarks of up to +5.3 mIoU. Inspired by work on VFM fine-tuning, such as Rein, we also explore the benefits of adding more easy-to-generate synthetic source data with easy-to-obtain unlabeled target data and realize a +6.6 mIoU over the current SotA. The improvements of VFM-UDA++ are most significant for smaller models, however, we show that for larger models, the obtained generalization is only 2.8 mIoU from that of fully-supervised learning with all target labels. Based on these strong results, we provide essential insights to help researchers and practitioners advance UDA.