利用居民地建筑物数据和高分遥感影像评估地震烈度的方法初探

doi:10.3969/j.issn.0253-4967.2020.04.013

摘要/Abstract

摘要： 地震发生后, 政府和社会对地震烈度评定工作的时效性要求越来越高, 而遥感作为地震灾情获取的重要手段之一, 在地震应急救援工作中发挥着越来越重要的作用。文中在前人研究的基础上, 提出了一种利用遥感影像结合居民地建筑数据评估地震烈度的方法模型: 在已知居民地建筑物数据的情况下, 利用群体震害预测方法, 构建居民地房屋倒塌率与地震烈度之间的关系模型; 震后利用高分辨率遥感影像解译居民地房屋的倒塌率, 并与倒塌率预测模型进行比对, 反推该居民地遭遇的地震烈度。利用本方法对玉树县城内相邻但破坏情况相差巨大的2个街区进行了烈度计算, 计算结果与现场科考结果一致。经验证, 在利用遥感手段评估地震烈度时, 本方法能有效避免由建筑抗震性能差异造成的影响, 可较准确地评估地震烈度, 在地震应急工作中具有一定的应用价值。

关键词: 居民地, 遥感, 倒塌率, 地震应急, 地震烈度

Abstract: After destructive earthquakes, the assessment result of seismic intensity is an important decision-making basis for emergency rescue, recovery and reconstruction. This job requires higher timeliness by government and society. Because remote sensing technology is not affected by the terrible traffic conditions on the ground after the earthquake, large-scale seismic damage information in the earthquake area can be collected in a short time by the remote sensing image. The remote sensing technique plays a more and more important role in rapid acquisition of seismic damage information, emergency rescue decision-making, seismic intensity assessment and other work. On the basis of previous studies, this paper proposes a new method to assess seismic intensity by using remote sensing image, i.e. to interpret the building collapse rate of a residential quarter after an earthquake by high-resolution remote sensing images. If there already are detailed building data and building structure vulnerability matrix data of a residential area, we can calculate the building collapse rate under any intensity values in this residential area by using the theory of earthquake damage prediction. Assuming that the building collapse rate interpreted by remote sensing is equal to the building collapse rate predicted by using the existing data, it will be easy to calculate the actual seismic intensity of the residential area in this earthquake event. Based on this idea, according to the relevant standard specifications issued by China Earthquake Administration, this paper puts forward some functional models, such as the calculation model of building collapse rate based on remote sensing, the data matrix model of residential building structure, the prediction function matrix model of residential building collapse rate and the prediction model of residential building collapse rate. A formula for calculating seismic intensity by using remote sensing interpretation of collapse rate is also proposed. To test and verify the proposed method, this paper takes two neighboring blocks of Jiegu Town after the Yushu M7.1 earthquake in Qinghai Province as an example. The building structure matrix of the study block was constructed by using pre-earthquake 0.6m resolution satellite remote sensing image(QuickBird, acquired on November 6, 2004), post-earthquake 0.2m aerial remote sensing image(acquired by National Bureau of Surveying and Mapping, April 15, 2010) and some field investigation data. The building collapse rate in the two blocks was calculated by using the interpretation results of seismic damage from the Remote Sensing Technology Coordinating Group of China Seismological Bureau. The seismic damage matrix of building structures in Yushu area is constructed by using the abundant scientific data of the scientific investigation team of the project “Comprehensive Scientific Investigation of the Yushu M7.1 Earthquake in Qinghai Province” of China Seismological Bureau. On this basis, the collapse rate prediction function of different structures in Yushu area is constructed. According to the prediction function of collapse rate and the building structure matrix of the two blocks, the building collapse rate under different intensity values is predicted, and the curve of intensity-collapse rate function is drawn. By comparing the building collapse rate interpreted by remote sensing and the intensity-collapse rate function curve of this two blocks, the seismic intensity of both blocks are calculated to be the same value: Ⅸ degree, which is consistent with the results of the field scientific investigation of the earthquake. The validation shows that the method proposed in this paper can effectively avoid the influence caused by the difference of seismic performance of buildings and accurately evaluate seismic intensity when using remote sensing technique. The method has certain application value for earthquake emergency work.

Key words: residential area, remote sensing, collapse rate, earthquake emergency, seismic intensity

中图分类号:

P315.9

郭建兴, 张宇翔, 姬建中, 袁小祥, 肖本夫. 利用居民地建筑物数据和高分遥感影像评估地震烈度的方法初探[J]. 地震地质, 2020, 42(4): 968-980.

GUO Jian-xing, ZHANG Yu-xiang, JI Jian-zhong, YUAN Xiao-xiang, XIAO Ben-fu. A PRELIMINARY STUDY ON THE METHOD OF SEISMIC INTENSITY ASSESSMENT BASED ON RESIDENTIAL BUILDING DATA AND HIGH RESOLUTION REMOTE SENSING IMAGES[J]. SEISMOLOGY AND GEOLOGY, 2020, 42(4): 968-980.

参考文献

[1] 安立强, 张景发. 2011. 遥感技术在震害调查中的应用现状及发展趋势[J]. 地震工程与工程振动, 31(2): 182—188.
AN Li-qiang, ZHANG Jing-fa. 2011. Application situation and trend of remote sensing technology used in earthquake disaster survey[J]. Earthquake Engineering and Engineering Vibration, 31(2): 182—188(in Chinese).
[2] 陈鑫连, 魏成阶. 1995. 地震灾害的航空遥感快速评估与救灾决策 [M]. 北京: 科学出版社: 1—136.
CHEN Xin-lian, WEI Cheng-jie. 1995. Rapid Assessment of Earthquake Disasters by Aerial Remote Sensing and Disaster Relief Decision-making [M]. Science Press, Beijing: 1—136(in Chinese).
[3] 程家喻, 杨喆. 1993. 唐山地震人员震亡率与房屋倒塌率的相关分析[J]. 地震地质, 15(1): 82—87.
CHENG Jia-yu, YANG Zhe. 1993. Regression analysis of mortality and the ratio of collapsing houses by Tangshan earthquake[J]. Seismology and Geology, 15(1): 82—87(in Chinese).
[4] 窦爱霞. 2018. 基于机载LiDAR数据的建筑物震害识别特征参数研究 [D]. 北京: 中国地震局地质研究所: 1—111.
DOU Ai-xia. 2018. Study on earthquake damage identification feature parameters of buildings based on airborne LiDAR data [D]. Institute of Geology, China Earthquake Administration, Beijing: 1—111(in Chinese).
[5] 窦爱霞, 王晓青, 丁香, 等. 2012. 遥感震害快速定量评估方法及其在玉树地震中的应用[J]. 灾害学, 27(3): 75—80.
DOU Ai-xia, WANG Xiao-qing, DING Xiang, et al. 2012. Quantitative methods of rapid earthquake damage assessment using remote sensing and its application in Yushu earthquake[J]. Journal of Catastrophology, 27(3): 75—80(in Chinese).
[6] 郭华东, 张兵, 雷莉萍, 等. 2010. 玉树地震高倒塌率建筑物及诱因: 遥感认识[J]. 中国科学(D辑), 40(5): 538—540.
GUO Hua-dong, ZHANG Bing, LEI Li-ping, et al. 2010. Buildings with high collapse rate in Yushu earthquake and its inducements: Understanding by remote sensing[J]. Science in China(Ser D), 40(5): 538—540(in Chinese).
[7] 郭建兴. 2013. 基于数字地球平台的震害显示和提取技术研究 [D]. 北京: 中国地震局地震预测研究所.
GUO Jian-xing. 2013. Study of technology of display and extracting earthquake damage based on the digital earth platform [D]. Institute of Earthquake Science, China Earthquake Administration, Beijing(in Chinese).
[8] 郭建兴, 袁小祥, 韶丹. 2018. 基于 “数字地球”的无人机遥感地震应急系统研制[J]. 信息通信, (8): 65—68.
GUO Jian-xing, YUAN Xiao-xiang, SHAO Dan. 2018. Development of unmanned aerial vehicle remote sensing earthquake emergency system based on Digital Earth Platform[J]. Information&Communications, (8): 65—68(in Chinese).
[9] 贺素歌. 2013. SAR图像用于震害信息变化检测中的处理方法研究 [D]. 北京: 中国地震局地震预测研究所.
HE Su-ge. 2013. Topic study on SAR image processing methods applied to earthquake damage information extraction [D]. Institute of Earthquake Science, China Earthquake Administration, Beijing(in Chinese).
[10] 金鼎坚, 王晓青, 窦爱霞, 等. 2012. 雷达遥感建筑物震害信息提取方法综述[J]. 遥感技术与应用, 27(3): 449—457.
JIN Ding-jian, WANG Xiao-qing, DOU Ai-xia, et al. 2012. A review on the methods of earthquake-induced building damage information extraction from SAR images[J]. Remote Sensing Technology and Application, 27(3): 449—457(in Chinese).
[11] 雷莉萍, 刘良云, 张丽, 等. 2010. 汶川地震房屋倒塌的遥感监测与分析[J]. 遥感学报, 14(2): 333—344.
LEI Li-ping, LIU Liang-yun, ZHANG Li, et al. 2010. Assessment and analysis of collapsing houses by aerial images in the Wenchuan earthquake[J]. Journal of Remote Sensing, 14(2): 333—344(in Chinese).
[12] 李果, 孔祥皓, 刘凤晶, 等. 2016. “高分四号”卫星遥感技术创新[J]. 航天返回与遥感, 37(4): 7—15.
LI Guo, KONG Xiang-hao, LIU Feng-jing, et al. 2016. GF-4 satellite remote sensing technology innovation[J]. Spacecraft Recovery & Remote Sensing, 37(4): 7—15(in Chinese).
[13] 陆春玲, 王瑞, 尹欢. 2014. “高分一号”卫星遥感成像特性[J]. 航天返回与遥感, 35(4): 67—73.
LU Chun-ling, WANG Rui, YIN Huan. 2014. GF-1 satellite remote sensing characters[J]. Spacecraft Recovery & Remote Sensing, 35(4): 67—73(in Chinese).
[14] 潘腾, 关晖, 贺玮. 2015. “高分二号”卫星遥感技术[J]. 航天返回与遥感, 36(4): 16—24.
PAN Teng, GUAN Hui, HE Wei. 2015. GF-2 satellite remote sensing technology[J]. Spacecraft Recovery & Remote Sensing, 36(4): 16—24(in Chinese).
[15] 孙柏涛, 胡少卿. 2005. 基于已有震害矩阵模拟的群体震害预测方法研究[J]. 地震工程与工程振动, 25(6): 102—108.
SUN Bai-tao, HU Shao-qing. 2005. A method for earthquake damage prediction of building group based on existing earthquake damage matrix[J]. Earthquake Engineering and Engineering Vibration, 25(6): 102—108(in Chinese).
[16] 孙景江, 李山有, 戴君武, 等. 2016. 青海玉树7.1级地震震害 [M]. 北京: 地震出版社.
SUN Jing-jiang, LI Shan-you, DAI Jun-wu, et al. 2016. Earthquake Damage of Yushu M7.1 Earthquake in Qinghai Province [M]. Seismological Press, Beijing(in Chinese).
[17] 王晓青, 窦爱霞, 丁香, 等. 2015a. 地震烈度应急遥感评估研究与应用进展[J]. 地球信息科学学报, 17(12): 1536—1544.
WANG Xiao-qing, DOU Ai-xia, DING Xiang, et al. 2015a. Advance on the RS-based emergency seismic intensity assessment[J]. Journal of Geo-information Science, 17(12): 1536—1544(in Chinese).
[18] 王晓青, 窦爱霞, 王龙, 等. 2015b. 2013年四川芦山7.0级地震烈度遥感评估[J]. 地球物理学报, 58(1): 163—171.
WANG Xiao-qing, DOU Ai-xia, WANG Long, et al. 2015b. RS-based assessment of seismic intensity of the 2013 Lushan, Sichuan, China M_S7.0 earthquake[J]. Chinese Journal of Geophysics, 58(1): 163—171(in Chinese).
[19] 王晓青, 王龙, 章熙海, 等. 2009. 汶川8.0级地震震害遥感定量化初步研究: 以都江堰城区破坏为例[J]. 地震, 29(1): 174—181.
WANG Xiao-qing, WANG Long, ZHANG Xi-hai, et al. 2009. Primary quantitative study on earthquake damage extracted from remote sensing imagery: A case study of Doujiangyan due to the Wenchuan M8.0 earthquake[J]. Earthquake, 29(1): 174—181.
[20] 魏成阶, 张渊智. 1996. 地震烈度包络线的遥感与GIS方法快速生成[J]. 自然灾害学报, 5(3): 19—28.
WEI Cheng-jie, ZHANG Yuan-zhi. 1996. Application of remote sensing and GIS techniques in producing earthquake isoseismal[J]. Journal of Natural Disasters, 5(3): 19—28(in Chinese).
[21] 杨喆, 程家喻. 1994. 唐山地震房屋倒塌率与烈度相关分析[J]. 地震地质, 16(3): 284—288.
YANG Zhe, CHENG Jia-yu. 1994. Correlation analysis of percentage of collapsing houses and seismic intensity of Tangshan earthquake[J]. Seismology and Geology, 16(3): 284—288(in Chinese).
[22] 尹之潜. 1991. 地震灾害损失预测研究[J]. 地震工程与工程振动, 11(4): 87—96.
YIN Zhi-qian. 1991. A study for predicting earthquake disaster loss[J]. Earthquake Engineering and Engineering Vibration, 11(4): 87—96(in Chinese).
[23] 余博, 李如仁, 陈振炜, 等. 2019. “高分三号”卫星图像干涉测量试验[J]. 航天返回与遥感, 40(1): 66—73.
YU Bo, LI Ru-ren, CHEN Zhen-wei. et al. 2019. Image interferometry experiment of GF-3 satellite[J]. Spacecraft Recovery & Remote Sensing, 40(1): 66—73(in Chinese).
[24] 中国地震局. 2018. 地震灾害遥感评估建筑物破坏(DB/T 75-2018)[S]. 北京: 中国标准出版社.
China Earthquake Administration. 2018. Earthquake disaster assessment based on remote sensing: Building damage(DB/T 75-2018)[S]. Standards Press of China, Beijing(in Chinese).
[25] 中国国家标准化管理委员会. 2009. 建(构)筑物地震破坏等级划分(GB/T 24335-2009)[S]. 北京: 中国标准出版社.
Standardization Administration of China. 2009. Classification of earthquake damage to buildings and special structures(GB/T 24335-2009)[S]. Standards Press of China, Beijing(in Chinese).
[26] 中国国家标准化管理委员会. 2011. 地震现场工作第四部分: 灾害直接损失评估(GB/T 18208.4-2011)[S]. 北京: 中国标准出版社.
Standardization Administration of China. 2011. Post-earthquake field works(Part 4): Assessment of direct loss(GB/T 18208.4-2011)[S]. Standards Press of China, Beijing(in Chinese).