LAUSR

Supervised remote sensing (RS) image segmentation has achieved remarkable success with large amounts of manually labeled data, which may be difficult to acquire in some practical application scenarios. Semisupervised RS image segmentation can efficiently utilize the knowledge embedded in unlabeled data to improve recognition performance, which is of great significance for the generalization application of segmentation models. In this work, we propose an end-to-end semisupervised RS image segmentation method based on weak-to-strong consistency learning (WSCL). Specifically, a common strong data augmentation technique for image segmentation is introduced to provide powerful input perturbation to decouple self-biased cognition. By forcing weakly augmented and strongly augmented perspectives from the same sample to be consistent, WSCL not only enables the model to steadily learn knowledge contained in unlabeled data but also alleviates overfitting. In addition, a novel sparse dual-view cross-sample image generation method is presented to generate new training samples, which helps provide a more comprehensive diversity of perturbations. Furthermore, an adaptive reweighting strategy based on the entropy maps of the outputs of strongly perturbed samples is proposed to suppress noise, guiding the training process in a positive direction. Extensive experiments demonstrate the significant advantage of WSCL over other advanced methods, achieving new state-of-the-art under several evaluation metrics on DFC22, iSAID, MER, MSL, Vaihingen, and GID-15 datasets. The source code is open-sourced at https://github.com/xiaoqiang-lu/WSCL.