基于ALOS-PALSAR DEM的山体阴影图识别断裂线性——以西秦岭地区为例

doi:10.3969/j.issn.0253-4967.2022.01.009

地震地质 ›› 2022, Vol. 44 ›› Issue (1): 130-149.DOI: 10.3969/j.issn.0253-4967.2022.01.009

基于ALOS-PALSAR DEM的山体阴影图识别断裂线性——以西秦岭地区为例

张波¹⁾(), 王爱国¹⁾, 田勤俭²⁾, 葛伟鹏¹⁾, 贾伟³⁾, 姚赟胜¹⁾, 袁道阳⁴⁾

1)甘肃兰州地球物理国家野外科学观测研究站, 兰州 730000
2)中国地震灾害防御中心, 北京 100029
3)海南省地震局, 海口 570203
4)兰州大学地质科学与矿产资源学院, 兰州 730000

收稿日期:2021-01-28 修回日期:2021-03-27 出版日期:2022-02-20 发布日期:2022-04-20
作者简介:张波, 男, 1986年生, 2020年于中国地震局地质研究所获构造地质学博士学位, 副研究员, 主要研究方向为新生代构造与活动构造, 电话: 13919015394, E-mail: kjwxn999@163.com。
基金资助:
中国地震局地震科技星火计划项目(XH19045Y);中国地震局地震预测研究所基本科研业务专项(2021IESLZ06);国家重点研发计划项目(2018YFC1503206);甘肃省青年科技基金(20JR10RA504)

IDENTIFYING FAULT LINEAMENT BASED ON ALOS-PALSAR DEM: A CASE STUDY FROM THE WEST QINLING MOUNTAINS

ZHANG Bo¹⁾(), WANG Ai-guo¹⁾, TIAN Qin-jian²⁾, GE Wei-peng¹⁾, JIA Wei³⁾, YAO Yun-sheng¹⁾, YUAN Dao-yang⁴⁾

1) Gansu Lanzhou Geophysics National Observation and Research Station, Lanzhou 730000, China
2) China Earthquake Disaster Prevention Center, Beijing 100029, China
3) Hainan Earthquake Agency, Haikou 570203, China
4) School of Earth Sciences, Lanzhou University, Lanzhou 730000, China

Received:2021-01-28 Revised:2021-03-27 Online:2022-02-20 Published:2022-04-20

摘要/Abstract

摘要：

在传统的断裂解译工作中, 人们更重视高分辨率的光学影像和DEM, 而对中分辨率DEM的重视程度较低。文中基于分辨率为12.5m的ALOS-PALSAR DEM和断裂线性解译标志, 对断裂几何学研究薄弱的西秦岭“V”形断裂系进行了目视解译。所得结果包括: 1)新发现了多条断裂线性带, 例如位于礼县-罗家堡断裂和两当-江洛断裂之间的以NE向为主的断裂线性带; 2)完善了已知活动断裂的几何展布图像; 3)西秦岭的断裂线性呈“V”形, NW、 NE 2组断裂的构造转换方式主要包括相互截切和弧形过渡。研究结果表明, ALOS-PALSAR DEM具有突出的断裂线性显示能力, 是高分辨率光学遥感图像的有效补充。研究结果对于完善西秦岭“V”形断裂系的几何图像具有重要意义, 也是进一步深入开展断裂几何学、运动学研究的基础。

关键词: ALOS-PALSAR DEM, 西秦岭“V”形断裂系, 断裂线性, 断裂解译

Abstract:

The most significant feature of active faults on remote sensing images is fault lineament. How to identify and extract fault lineament is an important content of active fault research. The rapid development of remote sensing technology has provided people with extremely rich remote sensing data, and has also created the problem of how to choose suitable data for fault interpretation. In the traditional fault interpretation, people pay more attention to high-resolution optical images and high-resolution DEM, but optical remote sensing images are greatly affected by factors such as weather condition, vegetation and human impacts, and the time and economic costs for obtaining high-resolution DEM are relatively high. Due to the low resolution, the medium-resolution DEM(such as Aster GDEM, SRTM1, SRTM3, etc.)is generally used to automatically extract structural lineament, and then analyze the overall regional structural features, but it is rarely used to visually interpret active faults. ALOS-PALSAR DEM is generated from SAR images acquired by the phased array L-band synthetic aperture radar mission sensor of the Japanese ALOS satellite. It is currently a free DEM with the highest resolution(resolution of 12.5m)and the widest coverage. Based on ALOS-PALSAR DEM and ArcGIS 10.4 software, this paper generates a hillshade map and visually interprets the fault lineaments in the West Qinling Mountains. When generating a hillshade map, we set the light azimuths to be oblique or orthogonal to the overall trend of the linear structures, the light azimuths to be consistent with the slope direction of the hillslope, and the light dips to be a medium incident angle. Based on the hillshade map generated from ALOS-PALSAR DEM, this paper summarizes the typical performance and interpretation markers of fault lineaments on the hillshade map(generated by DEM), and visually interprets the V-shaped fault system in West Qinling Mountains where the research on fault geometry is limited based on the interpretation markers. The results of the research are as follows: First, this study discovers a number of fault lineament zones, including the fault lineament located between the Lintan-Dangchang Fault and the Guanggaishan-Dieshan Fault, the NE-directed fault lineament zone between the Lixian-Luojiapu Fault and the Liangdang-Jiangluo Fault, and the arc-shaped dense fault lineament zones distributed south of the Hanan-Daoqizi Fault and the Wudu-Kangxian Fault; Second, this study completes the geometric distribution images of the known active faults, such as the western and eastern sections of the Lintan-Dangchang Fault, the western and eastern sections of the Liangdang-Jiangluo Fault; Third, fault lineaments in the West Qinling Mountains exhibit a “V” shape, with two groups of fault lineaments trending NW and NE, whose tectonic transformation mainly consists of two kinds: mutual cutting and arc transition. The Lintan-Dangchang Fault cuts the Lixian-Luojiapu Fault, the Lintan-Dangchang Fault and the Guanggaishan-Dieshan Fault are connected with the Liangdang-Jiangluo Fault in arc shape, and the Tazang Fault is connected with the Hanan-Daoqizi Fault in arc shape. The research results show that ALOS-PALSAR DEM has an outstanding capability to display fault lineaments due to its topographic attributes and strong surface penetration. In circumstances when the surface is artificially modified strongly, the spectrum of ground objects is complex and the vegetation is dense, the ALOS-PALSAR DEM can display fault lineament that cannot be displayed on optical remote sensing images, indicating that the medium-resolution DEM is an effective supplement to high-resolution optical remote sensing images in the fault lineament interpretation. The research results are of great significance for improving the geometric image of the V-shaped fault system in the West Qinling Mountains. It is also the basis for further research on fault geometry, kinematics, regional geodynamics and seismic hazard.

Key words: ALOS-PALSAR DEM, V-shaped fault system of the West Qinling Mountains, fault lineament, fault interpretation

中图分类号:

P542.3

张波, 王爱国, 田勤俭, 葛伟鹏, 贾伟, 姚赟胜, 袁道阳. 基于ALOS-PALSAR DEM的山体阴影图识别断裂线性——以西秦岭地区为例[J]. 地震地质, 2022, 44(1): 130-149.

ZHANG Bo, WANG Ai-guo, TIAN Qin-jian, GE Wei-peng, JIA Wei, YAO Yun-sheng, YUAN Dao-yang. IDENTIFYING FAULT LINEAMENT BASED ON ALOS-PALSAR DEM: A CASE STUDY FROM THE WEST QINLING MOUNTAINS[J]. SEISMOLOGY AND EGOLOGY, 2022, 44(1): 130-149.

图/表 13

图 1 区域地形地貌、活动断裂和历史地震分布 F1东昆仑断裂; F2阿万仓断裂; F3龙日坝断裂; F4岷江断裂; F5虎牙断裂; F6塔藏断裂; F7白龙江断裂; F8光盖山-迭山断裂; F9临潭-宕昌断裂; F10西秦岭北缘断裂; F11龙门山断裂; F12哈南-稻畦子断裂; F13武都-康县断裂; F14两当-江洛断裂; F15礼县-罗家堡断裂; F16贵德断裂; F17临洮断裂; F18马衔山断裂; F19通渭断裂; F20清水断裂; F21会宁-义岗断裂; F22六盘山断裂。断裂展布、断裂性质和地震信息来自文献(国家地震局震害防御司, 1995; 邓起东等, 2007; 贾伟等, 2012; Sun et al., 2015; 杨晓平等, 2015; 李新男, 2017; 任俊杰等, 2017; 王爱国等, 2018; 张波等, 2018, 2020, 2021;袁道阳等, 2019; Li et al., 2020)

Fig. 1 Regional topography and distribution of active faults and historical earthquakes.

图 2 基于3种中分辨率DEM生成的山体阴影图对比

Fig. 2 Comparison of hillshade maps generated from three kinds of medium-resolution DEMs.

图 3 入射方向与断裂线性的关系

Fig. 3 The relationship between light azimuths and fault lineaments.

图 4 入射角与断裂线性的关系

Fig. 4 The relationship between light dip and fault lineaments.

图 5 山体阴影图上异常亮、暗色调的原理 a 均一亮色; b 异常亮色; c 异常暗色; d 亮、暗交替; e 断续亮色

Fig. 5 The principle of unusually bright and dark tones on the hillshade map.

图 6 西秦岭“V”形断裂系的DEM解译标志 a 白龙江断裂多儿沟一带的线性亮、暗色条带; b 哈南-稻畦子断裂汉王镇以南的线性亮、暗色条带; c 临潭-宕昌断裂西段南支科才乡一带的断续亮暗特征; d 哈南-稻畦子断裂岳家山一带的线性暗色条带; e 临潭-宕昌断裂小林沟—崖湾里一带的亮、暗色调交替; f 两当-江洛断裂立斗村一带的纹理差异边界。红色箭头指示线性亮色,绿色箭头指示线性暗色, 红色虚线代表断层位置

Fig. 6 DEM interpretation markers of the V-shaped fault system in West Qinling.

图 7 西秦岭“V”形断裂系的DEM解译标志 a 白龙江断裂迭部县城南一带的断续亮色条带; b 白龙江断裂金钱沟一带的线性亮暗边界; c 临潭-宕昌断裂东段分支——禾驮断裂在申都乡一带的冲沟和山脊同步左旋偏转; d 临潭-宕昌断裂与光盖山-迭山断裂之间在草滩沟一带的冲沟和山脊同步左旋。红色箭头指示线性, 绿色实线代表冲沟, 红色虚线代表断层线性

Fig. 7 DEM interpretation markers of the V-shaped fault system in West Qinling.

图 8 基于ALOS-PALSAR DEM解译的断裂线性分布图

Fig. 8 Fault lineaments based on ALOS-PALSAR DEM interpretation.

图 9 西秦岭NW向断裂系的断裂线性

Fig. 9 Fault lineament of NW-trending fault system in West Qinling Mountains.

图 10 西秦岭NE向断裂系内新发现的断裂线性

Fig. 10 Fault lineament of the newly-discovered NE-trending fault system in West Qinling Mountains.

图 11 礼县-罗家堡断裂祁山镇一带的隐约断裂线性 a 祁山镇一带的Google Earth图像; b 祁山镇一带的ALOS-PALSAR DEM图像

Fig. 11 The faint fault lineament in the Qishan town area of the Lixian-Luojiapu Fault.

图 12 两当-江洛断裂的马泉沟—峡街村一带的断裂线性 a 马泉沟—峡街村一带的Google Earth图像; b 马泉沟—峡街村一带的ALOS-PALSAR DEM图像

Fig. 12 Fault lineament located between the Maquangou village and Xiajie village along the Liangdang-Jiangluo Fault.

图 13 白龙江断裂少下村以南的断裂线性 a 少下村南的Google Earth图像; b 少下村南的ALOS-PALSAR DEM图像

Fig. 13 Fault lineament south of Shaoxia village along the Bailongjiang Fault.

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基于ALOS-PALSAR DEM的山体阴影图识别断裂线性——以西秦岭地区为例

IDENTIFYING FAULT LINEAMENT BASED ON ALOS-PALSAR DEM: A CASE STUDY FROM THE WEST QINLING MOUNTAINS

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