Bitemporal Remote Sensing Image Change Detection Network Based on Siamese-Attention Feedback Architecture

Recently, deep learning-based change detection methods for bitemporal remote sensing images have achieved promising results based on fully convolutional neural networks. However, due to the inherent characteristics of convolutional neural networks, if the previous block fails to correctly segment the entire target, erroneous predictions might accumulate in the subsequent blocks, leading to incomplete change detection results in terms of structure. To address this issue, we propose a bitemporal remote sensing image change detection network based on a Siamese-attention feedback architecture, referred to as SAFNet. First, we propose a global semantic module (GSM) on the encoder network, aiming to generate a low-resolution semantic change map to capture the changed objects. Second, we introduce a temporal interaction module (TIM), which is built through each encoding and decoding block, using the feature feedback between two temporal blocks to enhance the network's perception ability of the entire changed target. Finally, we propose two auxiliary modules-the change feature extraction module (CFEM) and the feature refinement module (FRM)-which are further used to learn the fine boundaries of the changed target. The deep model we propose produced satisfying results in dual-temporal remote sensing image change detection. Extensive experiments on two remote sensing image change detection datasets demonstrate that the SAFNet algorithm exhibits state-of-the-art performance.

Automated summary

This study proposes a bitemporal remote sensing image change detection network called SAFNet, which is based on a Siamese-attention feedback architecture and achieves satisfying results using deep learning and fully convolutional neural networks. The network addresses the issue of incomplete change detection results by introducing a global semantic module (GSM), a temporal interaction module (TIM), and two auxiliary modules (CFEM and FRM).