Abstract
Despite increasing efforts in the mapping of landslides using Sentinel-1 and -2, research on their combination for discerning historical landslides in forest areas is still lacking, particularly using object-oriented machine learning approaches. This study was accomplished to test the efficiency of Sentinel-derived features and digital elevation model (DEM) derivatives for mapping old and new landslides, using object-oriented random forest. Two forest subsets were selected including a protected and non-protected forest in northeast Iran. Landslide samples were obtained from CORONA images and aerial photos (old landslides), and also field mensuration and high-resolution images (new landslides). Segment objects were generated from a set combination of Sentinel-1A, Sentinel-2A, and some topographic-derived indices using multiresolution segmentation algorithm. Various object features were derived from the main channels of Sentinel images and DEM derivatives in the seven main groups, including spectral layers, spectral indices, geometric, contextual, textural, topographic, and hydrologic features. A single database was created, including landslide samples and Sentinel- and DEM-derived object features. Roughly 20% of landslide-affected objects and non-landslide-affected objects were randomly selected as an input for training the random forest classifier. Two-thirds of the selected objects were assigned as learning samples for classification, and the remainder were used for testing the accuracy of landslide and non-landslide classification. Results indicated that: (1) The sensitivity of mapping historical landslides was 86.6% and 80.3% in the protected and non-protected forests, respectively; (2) the object features of Sentinel-2A and DEM obtained the highest importance with the total scores of 55.6% and 32%, respectively in the protected forests, and 65.4% and 21% respectively in the non-protected forests; (3) the features derived from the combination of Sentinel-1 and -2A demonstrated a total importance of 10% for mapping new landslides; and (4) textural features were obtained in approximately two-thirds of the total scores for mapping new landslides, however a combination of topographic, spectral, textural, and contextual features were the effective predictors for mapping old landslides. This research proposes applying a synergetic analysis of Sentinel- and DEM-derived features for mapping historical landslides; however, there are no uniformly pre-defined influential variables for mapping historical landslides in different forest areas.
Highlights
Landslide mapping is tied to a collection of image-derived features, conditioning, and triggering factors using satellite imagery and digital elevation model (DEM) derivatives in forest ecosystems
Landslide mapping was conducted by incorporating the first-order statistics of satellite-derived features such as the spectral information of main bands [11,12,13], spectral indices [6,10,14,15,16,17,18,19,20,21,22], or the second-order statistics of satellite-derived features, such as geometry [12,15,23], mean difference to neighbors [11,12,15,23], and textures derived from the gray-level co-occurrence matrix (GLCM) [6,9,10,12,23,24,25,26,27,28,29,30] of images—ranging from optical [8,9,11,31,32,33] to radar [18,34,35,36,37], or a combination of them [18,29,38,39,40]
This study aimed to answer the following questions: (1) Does the combination of Sentinel-1 and -2A based on the object-oriented random forest lead to satisfactory accuracy for discerning landslides from non-landslides in forest areas? (2) What are the most important object features for mapping old and new landslides in forest areas? (3) Which sub-features have a higher effect on differentiating landslide- from non-landslide objects in the protected and non-protected forests?
Summary
Landslide mapping is tied to a collection of image-derived features, conditioning, and triggering factors using satellite imagery and digital elevation model (DEM) derivatives in forest ecosystems. There is a need to compare influential Sentinel-derived features for mapping historical landslides in the forest regions. Different characteristics of satellite data can be applied to mapping, classifying, identifying influential triggers, and assessing susceptibility and risk of landslide hazards [7]. In addition to satellite-derived features, some topographic and hydrologic features, such as the slope and terrain ruggedness index (TRI), have enhanced the accuracy of landslide mapping from satellite data [9,10,13,23,29,41] as well
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