The earthquake of Nepal in 2015 and its aftershocks caused many landslides with its enormous destruction posing huge potential threats to residential lives and properties in the affected regions. Rapid and accurate detection of post-earthquake landslide is in urgent demand. Traditional pixel-based change detection methods, however, delivered a large amount of over-recognized objects. In view of this, a principal component analysis (PCA) based change detection method was proposed to recognize post-earthquake landslides. Katmandu, the capital and largest city of Nepal, was selected as the study area. First of all, to remove noise and abundant information, an orthogonal transformation was applied to before-earthquake and post-earthquake Landsat-8 images of Katmandu respectively. In subsequence, converted set of features, as the first principal component (PC1), was used for change detection. Last but not the least, non-landslides were eliminated by NDVI, PC3 and slope feature from previous results. Validation of the detected results with high-resolution images from Google Earth shows that the proposed method is able to identify landslides with relatively high accuracy (93.0%). And it also proves the applicability of Landsat-8 satellite imagery for landslide mapping with its multispectral information. The post-earthquake landslides are generally found in areas of large surface slopes (between 20° and 50° ) of the Sun Koshi Valley, which is in the Northeast of the study area. The research findings suggest that the proposed method is effective in identifying post-earthquake landslides, thus assisting post-earthquake rescue and reconstruction.
Key words
landslide mapping /
remote sensing /
principal component transformation /
change detection /
feature selection /
Nepal earthquake
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References
[1] 武新宁,易俊梅,周淑丽,等.尼泊尔Ms 8.1级地震活动构造及次生地质灾害研究[J].水文地质工程地质,2017,44(4):137-144.
[2] 彭 令,徐素宁,梅军军,等.地震滑坡高分辨率遥感影像识别[J].遥感学报,2017,21(4):509-518.
[3] 王治华.滑坡图像自动识别浅议[J].地球信息科学学报,2013,15(5):726-733,782.
[4] 丁 超, 冯光财, 周玉杉,等.尼泊尔地震触发滑坡识别和雪崩形变分析[J].武汉大学学报(信息科学版),2018,43(6):847-853,950.
[5] 张雅莉,马金珠,张 鹏,等.快鸟影像在典型古滑坡识别应用中的研究[J].长江科学院院报,2015,32(11):130-135.
[6] BORGHUIS A M, CHANG K, LEE H Y. Comparison between Automated and Manual Mapping of Typhoon-triggered Landslides from SPOT5 Imagery[J]. International Journal of Remote Sensing, 2007, 28(8):1843-1856.
[7] 李 松,李亦秋,安裕伦.基于变化检测的滑坡灾害自动识别[J].遥感信息,2010(1):27-31.
[8] ZHAO W, LI A N, NAN X, et al. Postearthquake Landslides Mapping from Landsat8 Data for the 2015 Nepal Earthquake Using a Pixel-based Change Detection Method[J]. IEEE Journal of Selected Topics in Applied Earth Observations & Remote Sensing, 2017, 10(5): 1758-1768.
[9] 罗永红, 李石桥, 王梓龙. 尼泊尔地震诱发地质灾害发育特征及影响因素分析[J].地质灾害与环境保护,2017, 28(3):33-40.
[10]郭沉稳,姚令侃,段书苏,等.汶川、芦山、尼泊尔地震触发崩塌滑坡分布规律[J].西南交通大学学报,2016,51(1):71-77.
[11]许石罗,牛瑞卿,武雪玲,等.基于主成分分析与粒子群优化的遥感影像变化检测[J].测绘科学,2017,42(4):151-156.
[12]李成龙,张景发.基于主成分分析的遥感震害变化检测方法与应用[J].地震,2013,33(2):103-108.
[13]莫德林,刘克江,曹彬才,等.基于主成分分析的遥感图像变化检测[J].影像技术,2013,25(5):53-56.
[14]张海涛. 基于高分影像的滑坡提取关键技术研究[D].武汉:中国地质大学, 2017.
[15]丁 辉,张茂省,李 林.基于多特征面向对象区域滑坡现象识别[J].遥感技术与应用,2013,28(6):1107-1113.
[16]林齐根, 邹振华, 祝瑛琦,等. 基于光谱、空间和形态特征的面向对象滑坡识别[J].遥感技术与应用, 2017, 32(5):931-937.
[17]容丽娜.基于面向对象分类的高分辨率遥感影像变化检测研究[D].西安:西安科技大学,2017.
[18]杨树文.工程地质地学信息遥感自动提取技术[M].北京:电子工业出版社,2013.
[19] LEE D S, SHAN J, BETHEL J S. Class-guided Building Extraction from Ikonos Imagery[J]. Photogrammetric Engineering & Remote Sensing, 2003, 69(2): 143-150.
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