Identification of potential landslide hazards is of great significance for disaster prevention and control. CNN (Convolutional Neural Networks), RNN (Recurrent Neural Networks) and many other deep learning methods have been used to identify landslide hazards. However, most samples are made with a fixed window size, which affects recognition accuracy to some extent. This paper presents a multi-window hidden danger identification CNN method according to the scale of the landslide in the experimental area. Firstly, the hidden danger area is preliminarily screened by InSAR deformation processing technology. Secondly, based on topography, geology, hydrology and human activities, a total of 15 disaster-prone factors are used to create factor datasets for in-depth learning. According to the general scale of the landslide, models with four window sizes of 48 × 48, 32 × 32, 16 × 16 and 8 × 8 are trained, respectively, and several window models with better recognition effect and suitable for the scale of landslide in the experimental area are selected for the accurate identification of landslide hazards. The results show that, among the four windows, 16 × 16 and 8 × 8 windows have the best model recognition effect. Then, according to the scale of the landslide, these optimal windows are pertinently selected, and the precision, recall rate and F-measure of the multi-window deep learning model are improved (82.86%, 78.75%, 80.75%). The research results prove that the multi-window identification method of landslide hazards combining InSAR technology and factors predisposing to disasters is effective, which can play an important role in regional disaster identification and enhance the scientific and technological support ability of geological disaster prevention and mitigation.
Detecting areas where a landslide or a mudslide might occur is critical for emergency response, disaster recovery, and disaster cost estimation. Previous works have reported that a variety of convolutional neural networks (CNNs) significantly outperform traditional approaches for landslide/mudslide detection. These approaches always consider features from the local window and neighborhood information. The CNNs mainly focus on the features derived at a local scale, which might be inefficient for recognizing complex landslide and mudslide scenes. To effectively identify landslide and mudslide risks at a local and global scale, this paper integrates attentions into the architecture of state-of-the-art CNNs—including Faster RCNN—to develop an attention-enhanced region proposal network for multi-scale landslide/mudslide detection. In detail, we employed the attentions to process the region proposals generated by a region proposal network and then combined the results obtained from the attentions and region proposal network to identify whether the object included in a region proposal was a landslide/mudslide. Based on our developed dataset and the Bijie dataset, the experimental results prove that: (1) although the state-of-the-art CNNs for object detection can precisely detect landslides and mudslides, they are inadequate in dealing with similarity to non-landslide/non-mudslide regions; and (2) the proposed method, which integrates global features from attention layers into local features derived from CNNs, outperforms the unmodified CNNs in detecting non-landslides and non-mudslides. Our findings prove that the representations at the local and global scale might be significant for precise landslide and mudslide detection.
The effectiveness of landslide disaster prevention depends largely on the quality of early identification of potential hazards, and how to comprehensively, deeply, and accurately identify such hazards has become a major difficulty in landslide disaster management. Existing deep learning methods for potential landslide hazard identification often use fixed-size window modeling and ignore the different window sizes required by landslides of different scales. To address this problem, we propose an adaptive identification method for potential landslide hazards based on multisource data. Taking Yongping County, China, as the study area, we create a multisource factor dataset based on the landslide disaster background in terms of topography, geology, human activities, hydrology, and vegetation as the sample for the identification model after processing. Moreover, we combine differential interferometric synthetic aperture radar (D-InSAR) and multitemporal InSAR (MT-InSAR) to process the surface deformation of the study area, and we measure the deformation richness based on the average of the pixel deformation difference within the current window of a pixel point in the image. Therefore, convolutional neural networks (CNNs) with different window sizes are adaptively selected. The results show that the precision of adaptive identification of potential landslide hazards in the study area is 85.30%, the recall is 83.03%, and the F1 score is 84.15%. The recognition rate for potential hazards reaches 80%, which is better than the fixed-window modeling result and proves the effectiveness of the proposed method. This method can help to improve intelligent identification systems for potential landslide hazards, and also contribute to the identification of other potential geological hazards, such as mudslides and collapses.
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