Change detection typically involves identifying regions with changes between bitemporal images taken at the same location. Besides significant changes, slow changes in bitemporal images are also important in real-life scenarios. For instance, weak changes often serve as precursors to major hazards in scenarios like slopes, dams, and tailings ponds. Therefore, designing a change detection network that simultaneously detects slow and fast changes presents a novel challenge. In this paper, to address this challenge, we propose a change detection network named Flow-CDNet, consisting of two branches: optical flow branch and binary change detection branch. The first branch utilizes a pyramid structure to extract displacement changes at multiple scales. The second one combines a ResNet-based network with the optical flow branch's output to generate fast change outputs. Subsequently, to supervise and evaluate this new change detection framework, a self-built change detection dataset Flow-Change, a loss function combining binary tversky loss and L2 norm loss, along with a new evaluation metric called FEPE are designed. Quantitative experiments conducted on Flow-Change dataset demonstrated that our approach outperforms the existing methods. Furthermore, ablation experiments verified that the two branches can promote each other to enhance the detection performance.
View on arXiv@article{li2025_2507.02307,
title={ Flow-CDNet: A Novel Network for Detecting Both Slow and Fast Changes in Bitemporal Images },
author={ Haoxuan Li and Chenxu Wei and Haodong Wang and Xiaomeng Hu and Boyuan An and Lingyan Ran and Baosen Zhang and Jin Jin and Omirzhan Taukebayev and Amirkhan Temirbayev and Junrui Liu and Xiuwei Zhang },
journal={arXiv preprint arXiv:2507.02307},
year={ 2025 }
}