CAL-Net: Conditional Attention Lightweight Network for In-Orbit Landslide Detection
Yibin Fu, Weiming Li, Shuaishuai Fan, Yonghua Jiang, Hongyang Bai
Abstract
Landslides are common and highly threatening geological disasters, and detecting landslide occurrence areas using remote sensing images has important social significance for disaster warning, prediction, and proactive rescue. Currently, the most effective and direct application is in-orbit real-time detection, which obtains the boundary, location and other relevant information of the post-disaster areas by performing in-orbit calculations on the raw images, thereby shortening the relief cycle. However, challenges associated with this application are high efficiency and portability, while overcoming complex surface distributions to ensure high accuracy. In this article, we propose a lightweight network framework and deploy it on a civilian QK series environmental monitoring satellite, transmitting the detection results in graphic form to the ground station. This framework addresses the problems of parameter redundancy and low real-time performance in existing embedded device landslide detection methods. The model adopts a conditional attention mechanism, multifeature fusion, and asymmetric upsampling modules (AUMs). It employs only 3.045 MB of parameters, with a mean intersection over union (MIoU) of 88.38% and an F1-scores of 93.77%, striking a good balance between computational efficiency and accuracy, and its performance can meet the requirements of in-orbit applications. Additionally, we have labeled and published landslide samples that occurred in Luding, Sichuan Province, Southwest China, in September 2022, which is available at <uri xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">https://github.com/fuadou/project/tree/main/Luding_datasets</uri>.