基于高分辨率无人机影像的地震地表破裂半自动提取方法--以2021年MS7.4青海玛多地震为例

doi:10.3969/j.issn.0253-4967.2022.06.008

地震地质 ›› 2022, Vol. 44 ›› Issue (6): 1484-1502.DOI: 10.3969/j.issn.0253-4967.2022.06.008

基于高分辨率无人机影像的地震地表破裂半自动提取方法--以2021年M_S7.4青海玛多地震为例

李东臣¹⁾(), 任俊杰¹^,²^,³⁾^,^*(), 张志文¹⁾, 刘亮⁴^,⁵⁾

1)应急管理部国家自然灾害防治研究院, 北京 100085
2)复合链生自然灾害动力学应急管理部重点实验室, 北京 100085
3)中国地震局地壳动力学重点实验室, 北京 100085
4)应急管理部国家减灾中心, 北京 100124
5)应急管理部卫星减灾应用中心, 北京 100124

收稿日期:2021-12-24 修回日期:2022-04-27 出版日期:2022-12-20 发布日期:2023-01-21
通讯作者: 任俊杰
作者简介:李东臣, 男, 1998年生, 现为应急管理部国家自然灾害防治研究院地球物理学专业在读硕士研究生, 主要从事机器学习、计算机视觉与构造地貌研究, E-mail: lidongchen20@mails.ucas.ac.cn。
基金资助:
国家自然科学基金(41941016);国家自然科学基金(U2139201);国家自然科学基金(41572193);应急管理部国家自然灾害防治研究院基本科研业务专项(ZDJ2017-24)

RESEARCH ON SEMI-AUTOMATIC EXTRACTION METHOD OF SEISMIC SURFACE RUPTURES BASED ON HIGH-RESOLUTION UAV IMAGE: TAKING THE 2021 M_S7.4 MADUO EARTHQUAKE IN QINGHAI PROVINCE AS AN EXAMPLE

LI Dong-chen¹⁾(), REN Jun-jie¹^,²^,³⁾^,^*(), ZHANG Zhi-wen¹⁾, LIU Liang⁴^,⁵⁾

1)National Institute of Natural Hazards, Ministry of Emergency Management of China, Beijing 100085, China
2)Key Laboratory of Compound and Chained Natural Hazards Dynamics, Ministry of Emergency Management of China, Beijing 100085, China
3)Key Laboratory of Crustal Dynamics, China Earthquake Administration(CEA), Beijing 100085, China
4)National Disaster Reduction Center of China, MEM, Beijing 100124, China
5)Satellite Application Center for Disaster Reduction, MEM, Beijing 100124, China;

Received:2021-12-24 Revised:2022-04-27 Online:2022-12-20 Published:2023-01-21
Contact: REN Jun-jie

摘要/Abstract

摘要：

精细刻画大地震形成的地表破裂的几何学特征对于深入理解发震断裂的运动学机制和变形规律具有重要意义。野外地质调查和影像目视解译等传统获取地震地表破裂的方法往往费时费力, 且难以获得其精细特征。文中依据面向对象、颜色空间色彩分割等理论, 基于高分辨率无人机影像, 提出了一种面向对象的“粗分割-精提取”方法, 以实现半自动提取地震地表破裂的矢量面。对2021年青海玛多 M_S7.4 地震的实验结果表明, 该方法能够有效去除与地表破裂光谱相似的河道等噪声, 快速准确地提取地表破裂带的精细结构。文中建立的地震地表破裂半自动化提取方法可为大地震发生后快速提取地表破裂精细结构和分析地表变形特征提供一个可行方案。

关键词: 面向对象, 色彩分割, 高分辨率无人机影像, 粗分割-精提取, 地震地表破裂

Abstract:

Field investigations of large earthquakes indicate that earthquakes with a magnitude greater than 6.5 often produce seismic surface rupture zones ranging from thousands of meters to tens of kilometers on the earth’s surface. The geometric structures of surface ruptures contain the kinematic characteristics of seismogenic structures, which can not only provide critical quantitative data for analyzing the spatial distribution law of co-seismic displacement of active faults and the width of active fault deformation zone, but also have an important significance for understanding the kinematic mechanism and deformation law of seismogenic faults.
At present, the conventional methods to obtain earthquake surface ruptures mainly include the field geological survey and visual interpretation of the remote sensing image. Although these two methods can get the rough geometry of coseismic surface ruptures, they both have certain limitations. The reliability of the field geological survey method is high. However, intra-continental earthquakes often occur in places with complicated topography, and lots of sites are difficult to reach, leading to incomplete data and failure to draw detailed features of the fracture zone. Meanwhile, the field geological survey is often time-consuming and laborious. Although the visual interpretation of remoting sensing images can be used to interpret surface fractures in areas that cannot be reached by the geological field survey, the result accuracy is vulnerable to the impacts of interpreters’ experience. The whole process of interpretation is still time-consuming and labor-intensive and the extraction results are mostly linear surface ruptures, so it is difficult to accurately obtain fine features such as the width of the surface rupture zone. Therefore, the automatic extraction of fine structures of seismic surface ruptures, especially micro-rupture surfaces, is an urgent problem in active tectonic studies.
The remote sensing images obtained through satellite platforms have low resolution and are susceptible to weather factors, and the extracted surface rupture fineness is not enough. The UAV platform, on the other hand, is low-cost to use, can fly at a low altitude, is not affected by clouds and fog, and can acquire images with a centimeter-level resolution, which provides conditions for extraction the fine structure of surface ruptures of large earthquakes. Thus, to solve the problem that it is difficult to obtain surface ruptures of large earthquakes quickly, this study proposes an object-oriented “Rough segmentation and Fine extraction” method based on object-oriented and color segmentation theories of color space, which realizes the semi-automatic extraction of features of seismic surface rupture zone. The processing workflow of the method is as follows: First, the original image is cropped by the custom irregular raster cropping method designed in this study to obtain ROI(the Region of Interest). Second, the color space of ROI is converted into HSV, and the HSV color space of ROI is segmented into surface rupture candidate area by using brightness and hue tone values. And then, the surface rupture candidate area is processed by expansion operation of binary mathematical morphology. Third, the surface rupture candidate area is transformed into a series of sub-area objects by the contour tracking method. Fourth, the surface rupture is refined using the spectral standard deviation, spectral mean and the length-width ratio of the smallest surrounding rectangle as characteristic parameters. Finally, the results are output as the vector surface of surface ruptures.
The effectiveness of the proposed method is analyzed by taking the high-resolution UAV image data of the M_S7.4 Maduo earthquake in Qinghai Province as an example. The results show that the proposed method can effectively remove the noises such as the river channel similar to the characteristics(i.e., the color and shape features)of the surface rupture and extract the delicate structures of the surface rupture zone quickly and accurately, except that several poor extraction results were caused by the limitation of image resolution and the destruction of surface rupture caused by river erosion. The extraction results are highly reliable and can be used to extract quantitative parameters of surface ruptures in large earthquakes. Thus, the semi-automatic extraction method of seismic surface ruptures established in this study can provide a feasible scheme for the rapid extraction of delicate structures from surface ruptures and analysis of surface deformation characteristics after a large earthquake.

Key words: object-oriented, color segmentation, high-resolution UAV images, Rough segmentation and Fine extraction, seismic surface rupture

中图分类号:

P315.2

李东臣, 任俊杰, 张志文, 刘亮. 基于高分辨率无人机影像的地震地表破裂半自动提取方法--以2021年M_S7.4青海玛多地震为例[J]. 地震地质, 2022, 44(6): 1484-1502.

LI Dong-chen, REN Jun-jie, ZHANG Zhi-wen, LIU Liang. RESEARCH ON SEMI-AUTOMATIC EXTRACTION METHOD OF SEISMIC SURFACE RUPTURES BASED ON HIGH-RESOLUTION UAV IMAGE: TAKING THE 2021 M_S7.4 MADUO EARTHQUAKE IN QINGHAI PROVINCE AS AN EXAMPLE[J]. SEISMOLOGY AND GEOLOGY, 2022, 44(6): 1484-1502.

图/表 12

图 1 面向对象的“粗分割-精提取”方法

Fig. 1 Object-oriented “rough segmentation-fine extraction” method.

图 2 2021年青海玛多 MS7.4 地震的地表破裂与余震分布断层数据来源于文献(邓起东, 2007); 玛多地震地表破裂来源于文献(Ren et al., 2021); 地震余震目录来源于文献(徐志国等, 2021); 底图遥感卫星影像来源于Google Earth; 研究区位于图中蓝色方框内

Fig. 2 Aftershock distribution and coseismic rupture zone of the 2021 MS7.4 Maduo earthquake, Qinghai.

图 3 自定义不规则多边形栅格裁剪结果 a 高分辨率无人机影像数据; b 裁剪结果。绿框为自定义不规则多边形

Fig. 3 Raster clipping result of custom irregular polygon.

图 4 HSV颜色空间色彩分割结果 a 阈值过高时的分割结果; b 阈值过低时的分割结果。白色区域即分割得到的地表破裂候选区

Fig. 4 The results of HSV color space color segmentation.

图 5 粗分割动态调整界面

Fig. 5 The dynamic adjustment interface of coarse extraction.

图 6 地表破裂候选区 a 原始影像; b 地表破裂的提取结果(红色即为提取结果的轮廓)。底图为原始影像灰度图

Fig. 6 The ROI area of coseismic surface ruptures.

图 7 精提取动态调整界面

Fig. 7 The dynamic adjustment interface of fine extraction.

图 8 地表破裂的提取结果 a 地表破裂所在范围的研究区原始影像; b 地表破裂提取结果, 底图为原始影像的灰度图; c-k 地表破裂轮廓线的细部结构

Fig. 8 Extraction results of surface rupture.

图 9 影像分块后的提取结果 a 河流处地表破裂的原提取效果; b 分块后河流处地表破裂的提取效果; c 图8f处的提取效果; d 分块后图8f处的提取效果, 其中绿色矢量面为原提取结果, 红色轮廓为分块后的提取结果

Fig. 9 Extraction results of image segmentation.

图 10 需求改变后的提取结果 a 本文的提取结果; b 需求改变后的提取结果; c、 e 本文提取结果轮廓的精细结构; d、 f 需求改变后提取结果轮廓的精细结构

Fig. 10 Extraction results after demand changes.

图 11 采用膨胀运算与否的提取结果 a 采用膨胀运算后的提取结果; b 未采用膨胀运算的提取结果; c、 e、 g 采用膨胀运算后提取结果轮廓的精细结构; d、 f、 h 未采用膨胀运算提取结果轮廓的精细结构

Fig. 11 Extraction results with or without expansion operation.

图 12 选取不同特征参数时的提取结果 a 本文的提取结果; b 仅使用子区域对象的光谱标准差为约束参数的提取结果; c、 e 本文提取结果轮廓的精细结构; d、 f 仅使用子区域对象的光谱标准差为约束参数的提取结果轮廓的精细结构

Fig. 12 Extraction results with different characteristic parameters.

参考文献 35

[1]	陈立春, 王虎, 冉勇康, 等. 2010. 玉树 M_S7.1 地震地表破裂与历史大地震[J]. 科学通报, 55(13): 1200-1205.
	CHEN Li-chun, WANG Hu, RAN Yong-kang, et al. 2010. The M_S7.1 Yushu earthquake surface ruptures and historical earthquakes[J]. Chinese Science Bulletin, 55(13): 1200-1205. (in Chinese)
[2]	邓起东. 2007. 中国活动构造图[CM]. 北京: 地震出版社.
	DENG Qi-dong. 2007. Map of Active Tectonics in China [CM]. Seismological Press, Beijing. (in Chinese)
[3]	邓起东, 闻学泽. 2008. 活动构造研究: 历史、进展与建议[J]. 地震地质, 30(1): 1-30.
	DENG Qi-dong, WEN Xue-ze. 2008. A review on the research of active tectonics: History, progress and suggestions[J]. Seismology and Geology, 30(1): 1-30. (in Chinese)
[4]	郭庆华, 胡天宇, 刘瑾, 等. 2021. 轻小型无人机遥感及其行业应用进展[J]. 地理科学进展, 40(9): 1550-1569. DOI
	GUO Qing-hua, HU Tian-yu, LIU Jin, et al. 2021. Advances in light weight unmanned aerial vehicle remote sensing and major industrial applications[J]. Progress in Geography, 40(9): 1550-1569. (in Chinese) DOI
[5]	胡焯源, 曹玉东, 李羊. 2017. 基于HSV颜色空间的车身颜色识别算法[J]. 辽宁工业大学学报(自然科学版), 37(1): 10-12.
	HU Zhuo-yuan, CAO Yu-dong, LI Yang. 2017. Car color recognition algorithm based on HSV color space[J]. Journal of Liaoning University of Technology(Natural Science Edition), 37(1): 10-12. (in Chinese)
[6]	黄雪青. 2008. 基于高分辨率遥感影像的信息提取[D]. 重庆: 重庆大学.
	HUANG Xue-qing. 2008. Information extraction based on high-resolution remote sensing images[D]. Chongqing University, Chongqing. (in Chinese)
[7]	鞠明明. 2013. 基于面向对象图像分析的围填海工程遥感信息提取技术研究[D]. 南京: 南京师范大学.
	JU Ming-ming. 2013. Remote-sensing-based information extraction of reclamation project using object-oriented image analysis technique[D]. Nanjing Normal University, Nanjing. (in Chinese)
[8]	李海兵, 孙知明, 潘家伟, 等. 2014. 2014年于田 M_S7.3 地震野外调查: 特殊的地表破裂带[J]. 地球学报, 35(3): 391-394.
	LI Hai-bing, SUN Zhi-ming, PAN Jia-wei, et al. 2014. Field study of the 12 February 2014 Yutian M_S7.3 earthquake: A special surface rupture zone[J]. Acta Geoscientica Sinica, 35(3): 391-394. (in Chinese)
[9]	李政国. 2008. 基于区域生长法的高空间分辨率遥感图像分割与实现[D]. 南宁: 广西大学.
	LI Zheng-guo. 2008. The segmentation and realization of high spatial resolution remote sensing image based on region growing algorithm[D]. Guangxi University, Nanning. (in Chinese)
[10]	李智敏, 李文巧, 李涛, 等. 2021. 2021年5月22日青海玛多 M_S7.4 地震的发震构造和地表破裂初步调查[J]. 地震地质, 43(3): 722-737. doi: 10.3969/j.issn.0253-4967.2021.03.016. DOI
	LI Zhi-min, LI Wen-qiao, LI Tao, et al. 2021. Seismogenic fault and coseismic surface deformation of the Maduo M_S7.4 earthquake in Qinghai, China: A quick report[J]. Seismology and Geology, 43(3): 722-737. (in Chinese)
[11]	刘超, 雷启云, 余思汗, 等. 2021. 基于无人机摄影测量技术的地震地表破裂带定量参数提取: 以1709年中卫南M7½地震为例[J]. 地震学报, 43(1): 113-123.
	LIU Chao, LEI Qi-yun, YU Si-han, et al. 2021. Using UAV photogrammetry technology to extract the quantitative parameters of earthquake surface rupture zone: A case study of the southern Zhongwei M7½ earthquake in 1709[J]. Acta Seismologica Sinica, 43(1): 113-123. (in Chinese)
[12]	陆可, 郑伯桢, 卢春盛, 等. 2021. 基于数学形态学改进的无人机影像配准算法[J]. 合肥工业大学学报(自然科学版), 44(10): 1406-1412, 1419.
	LU Ke, ZHENG Bo-zhen, LU Chun-sheng, et al. 2021. Improved UAV image registration algorithm based on mathematical morphology[J]. Journal of Hefei University of Technology(Natural Science), 44(10): 1406-1412, 1419. (in Chinese)
[13]	罗朝阳, 张鹏超, 姚晋晋, 等. 2020. 一种基于形态学的边缘检测算法[J]. 计算机应用与软件技术, 37(2): 177-181, 247.
	LUO Zhao-yang, ZHANG Peng-chao, YAO Jin-jin, et al. 2020. An edge detection algorithm based on morphology[J]. Computer Applications and Software, 37(2): 177-181, 247. (in Chinese)
[14]	潘家伟, 白明坤, 李超, 等. 2021. 2021年5月22日青海玛多 M_S7.4 地震地表破裂带及发震构造[J]. 地质学报, 95(6): 1655-1670.
	PAN Jia-wei, BAI Ming-kun, LI Chao, et al. 2021. Coseismic surface rupture and seismogenic structure of the 2021-05-22 Maduo(Qinghai) M_S7.4 earthquake[J]. Acta Geologica Sinica, 95(6): 1655-1670. (in Chinese)
[15]	铁瑞, 王俊, 贾连军, 等. 2016. 强震地震数据统计及其地表破裂特性研究[J]. 世界地震工程, 32(1): 112-116.
	TIE Rui, WANG Jun, JIA Lian-jun, et al. 2016. Data statistics of strong-moderate earthquake and characteristics research of ground rupture[J]. World Earthquake Engineering, 32(1): 112-116. (in Chinese)
[16]	王博, 王霞, 陈飞, 等. 2017. 航拍图像的路面裂缝识别[J]. 光学学报, 37(8): 126-132.
	WANG Bo, WANG Xia, CHEN Fei, et al. 2017. Pavement crack recognition based on aerial image[J]. Acta Optica Sinica, 37(8): 126-132. (in Chinese)
[17]	王琪. 2011. 关于运动目标特征提取以及车辆颜色识别算法的研究[D]. 成都: 电子科技大学.
	WANG Qi. 2011. Research on moving target feature extraction and vehicle color recognition algorithm[D]. University of Electronic Science and Technology of China, Chengdu. (in Chinese)
[18]	徐锡伟, 陈桂华. 2018. 活动断层避让问题探讨与建议[J]. 城市与减灾, (1): 8-13.
	XU Xi-wei, CHEN Gui-hua. 2018. Discussion and suggestion on active fault avoidance[J]. City and Disaster Reduction, (1): 8-13. (in Chinese)
[19]	徐锡伟, 闻学泽, 叶建青, 等. 2008. 汶川 M_S8.0地震地表破裂带及其发震构造[J]. 地震地质, 30(3): 597-629.
	XU Xi-wei, WEN Xue-ze, YE Jian-qing, et al. 2008. The M_S8.0 Wenchuan earthquake surface ruptures and its seismogenic structure[J]. Seismology and Geology, 30(3): 597-629. (in Chinese)
[20]	徐岳仁, 陈立泽, 申旭辉, 等. 2015. 基于GF-1卫星影像解译2014年新疆于田 M_S7.3 地震同震地表破裂带[J]. 地震, 35(2): 61-71.
	XU Yue-ren, CHEN Li-ze, SHEN Xu-hui, et al. 2015. Interpretating coseismic surface rupture zone of the 2014 Yutian M_S7.3 earthquake using GF-1 satellite images[J]. Earthquake, 35(2): 61-71. (in Chinese)
[21]	徐志国, 梁姗姗, 张广伟, 等. 2021. 2021年5月22日青海玛多 M_S7.4 地震发震构造分析[J]. 地球物理学报, 64(8): 2657-2670.
	XU Zhi-guo, LIANG Shan-shan, ZHANG Guang-wei, et al. 2021. Analysis of seismogenic structure of Madoi, Qinghai M_S7.4 earthquake on May 22, 2021[J]. Chinese Journal of Geophysics, 64(8): 2657-2670. (in Chinese)
[22]	杨莹辉, 陈强, 徐倩, 等. 2017. 汶川地震SAR形变场电离层影响校正与断层地表破裂线自动提取[J]. 地球物理学报, 60(8): 2948-2958.
	YANG Ying-hui, CHEN Qiang, XU Qian, et al. 2017. SAR ionosphere signal correction for deformation field of Wenchuan earthquake and extraction of fault surface rupture trace[J]. Chinese Journal of Geophysics, 60(8): 2948-2958. (in Chinese)
[23]	袁兆德, 刘静, 李雪, 等. 2021. 2014年新疆于田 M_S7.3 地震地表破裂带精细填图及其破裂特征[J]. 中国科学(D辑), 51(2): 276-298.
	YUAN Zhao-de, LIU Jing, LI Xue, et al. 2021. Detailed mapping of the surface rupture of the 12 February 2014 Yutian M_S7.3 earthquake, Altyn Tagh Fault, Xinjiang, China[J]. Science in China(Ser D), 51(2): 276-298. (in Chinese)
[24]	曾举, 李向新, 王涛. 2011. 基于Ecognition的高分辨率遥感影像水体提取研究[J]. 江西科学, 29(2): 263-266.
	ZENG Ju, LI Xiang-xin, WANG Tao. 2011. Study on object-oriented extracting water from high resolution remote sensing image[J]. Jiangxi Science, 29(2): 263-266. (in Chinese)
[25]	张波, 何文贵, 方良好, 等. 2015. 1936年甘肃康乐6¾级地震地表破裂带调查[J]. 地震研究, 38(2): 262-271, 333.
	ZHANG Bo, HE Wen-gui, FANG Liang-hao, et al. 2015. Surveys on surface rupture phenomena of Gansu Kangle M6¾ earthquake in 1936[J]. Journal of Seismological Research, 38(2): 262-271, 333. (in Chinese)
[26]	张志文, 任俊杰, 章小龙. 2021. 高精度无人机航测在2021年玛多 M_S7.4 地震地表破裂精细研究中的应用[J]. 震灾防御技术, 16(3): 1-11.
	ZHANG Zhi-wen, REN Jun-jie, ZHANG Xiao-long. 2021. Application of high-precision UAV aerial survey in the detailed study of surface rupture of Maduo M_S7.4 earthquake in 2021[J]. Technology for Earthquake Disaster Prevention, 16(3): 1-11. (in Chinese)
[27]	赵慧, 汪云甲. 2012. 融合多尺度分割与CART算法的矸石山提取[J]. 计算机工程与应用, 48(22): 222-225, 248.
	ZHAO Hui, WANG Yun-jia. 2012. Fusing muti-scale segmentation into CART algorithm on coal gangue extraction[J]. Computer Engineering and Applications, 48(22): 222-225, 248. (in Chinese)
[28]	Brooks B A, Minson S E, Glennie C L, et al. 2017. Buried shallow fault slip from the South Napa earthquake revealed by near-field geodesy[J]. Science Advances, 3(7): e1700525. DOI URL
[29]	Klinger Y, Xu X, Tapponnier P, et al. 2005. High-resolution satellite imagery mapping of the surface rupture and slip distribution of the M_W-7.8, 14 November 2001 Kokoxili earthquake, Kunlun Fault, Northern Tibet, China[J]. Bulletin of the Seismological Society of America, 95(5): 1970-1987. DOI URL
[30]	Ren J, Zhang Z, Gai H, et al. 2021. Typical Riedel shear structures of the coseismic surface rupture zone produced by the 2021 M_W7.3 Maduo earthquake, Qinghai, China, and the implications for seismic hazards in the block interior[J]. Natural Hazards Research, 1(4): 145-152. DOI URL
[31]	Ren Z, Zhang Z. 2019. Structural analysis of the 1997 M_W7.5 Manyi earthquake and the kinematics of the Manyi Fault, central Tibetan plateau[J]. Journal of Asian Earth Sciences, 179: 149-164. DOI URL
[32]	Rodriguez P M, Quintana M A, Prado R M, et al. 2021. Near-field high-resolution maps of the Ridgecrest earthquakes from aerial imagery[J]. Seismological Research Letters, 93(1): 494-499. DOI URL
[33]	Smith A R. 1978. Color gamut transform pairs[J]. Computer Graphics, 12(3): 12-19. DOI URL
[34]	Suzuki S, Abe K. 1985. Topological structural analysis of digitized binary images by border following[J]. Computer Vision, Graphics, and Image Processing, 30(1): 32-46. DOI URL
[35]	Xu X, Wen X, Yu G, et al. 2009. Coseismic reverse- and oblique-slip surface faulting generated by the 2008 M_W7.9 Wenchuan earthquake, China[J]. Geology, 37(6): 515-518. DOI URL

基于高分辨率无人机影像的地震地表破裂半自动提取方法--以2021年M_S7.4青海玛多地震为例

RESEARCH ON SEMI-AUTOMATIC EXTRACTION METHOD OF SEISMIC SURFACE RUPTURES BASED ON HIGH-RESOLUTION UAV IMAGE: TAKING THE 2021 M_S7.4 MADUO EARTHQUAKE IN QINGHAI PROVINCE AS AN EXAMPLE

RichHTML

PDF (PC)