基于离散灾情信息的地震烈度分布快速判定方法研究*

Abstract

Abstract: According to analysis of disaster information feedbacks from previous destructive earthquakes,and combined with evolution mechanism and distribution characteristics of earthquake disasters,we put forward three methods for fast assessing seismic intensity distribution based on discrete disaster information.In addition,considering the calculation principle,data base,characteristics and determination results,the three methods could be applied in different scenarios.The simple and easy Tyson-polygon method is can be used during the initial period of earthquake emergency in which little disaster information is acquired roughly,and needs to be combined with influences of earthquake source,rupture process and terrain conditions on damage distribution for obtaining relatively reasonable disaster distribution assessment result.The Kriging-interpolation method,which is a spatial interpolation method based on geo-statistics,has strict requirements on data distribution, and its result is better in assessing the disaster scope and can be used as a reference of disaster assessment correction and emergency decision-making after comprehensive adjusting with seismic rupture process and the earthquake aftershock distribution when a certain amount of disaster information is acquired whereas the disaster situation is not clear.The ellipse fitting by distance standard deviation method is based on the hypothesis that seismic intensity distribution is oval,sensitive to data and can be used for fitting disaster information with high credibility or reported from professional source,and its result can be used as a reference of disaster field investigation and evaluation of earthquake intensity distribution.

Key words: Seismic intensity distribution, Earthquake disaster information, Spatial interpolation

CLC Number:

P315.7

YANG Tian-qing, XI Nan, ZHANG Yi, LI Jie-fei. Fast Determination Method of Seismic Intensity Distribution Based on Discrete Disaster Information[J]. EARTHQUAKE, 2016, 36(2): 48-59.

References

[1]Gail M.Atkinson,David J.Wald.“Did You Feel It?”Intensity Data:A Surprisingly Good Measure of Earthquake Ground Motion[J].Seismological Research Letters,2007,78(3):362-368.
[2]帅向华,胡素平,刘钦,等.地震灾情网络媒体获取与处理模型[J].自然灾害学报,2013,22(3): 178-184.
[3]胡素平,帅向华.网络地震灾情信息智能处理模型与地震烈度判定方法研究[J].震灾防御技术, 2012,7(4):420-430.
[4]杨天青,姜立新,席楠.地震速报灾情信息过滤与推漫方法研究———以芦山7.0级地震为例[J].自然灾害学报,2015,24(1):96-103.
[5]聂高众,安基文,邓砚,地震应急灾情服务进展[J].地震地质,2012,34(4):782-791.
[6]全国标准化技术委员会.GB/T 18207.1—2008防震减灾术语第1部分:基本术语[S].北京:中国标准出版社.
[7]万熙琼. 突发事件的网络传播机制及其应急管理研究[D].复旦大学,硕士论文,2009.
[8]全国标准化技术委员会.GB/T 18208.3地震现场工作第3部分调查规范[S].北京:中国标准出版社.
[9]全国标准化技术委员会.2008.GB/T 17742—2008中国地震烈度表啊[S].北京:中国标准出版社.
[10]杨天青,姜立新,董曼,等.基于余震序列分布信息的地震极灾区快速判断方法研究[J].灾害学,2015,30(1):8-15.
[11]徐锡伟,陈桂华,于贵华,等.芦山地震发震构造及其与汶川地震关系讨论[J].地学前缘Earth Science Frontier,2013,20(3):11-20.
[12]张勇,许力生,陈运泰.芦山4.20地震破裂过程及其致灾特征初步分析[J].地球物理学报,2013,56(4):1 408-1 411.
[13]温瑞智,任叶飞,黄旭涛,等.芦山7.0级地震强震动记录及其震害相关性[J].地震工程与工程振动,2013,33(4):1-14.
[14]陈健飞. 地理信息系统导论[M].北京:科学出版社,2003.
[15]赵翠萍,周连生,陈章立.2013年四川芦山MS7.0级地震震源破裂过程及其构造意义[J].科学通报,2013,58(20):184-190.
[16]陈晨,胥颐.芦山MS7.0级地震余震序列重新定位及构造意义[J].地球物理学报,2013,66(12):4 028-4 036.
[17]汪素云,俞言祥,高阿甲,等.中国分区地震动衰减关系的确定[J].中国地震,2000,16(2):99-106.
[18]李闽峰,李圣强,陈颙.探讨地震宏观破坏场分布的影响因素[J].中国地震,2000,16(4):293-306.
[19]闻学泽.断层与地震构造基础[R].2014年全国测震台网技术骨干培训班讲稿(杭州),2014.
[20]胡聿贤. 地震工程学[M].北京:地震出版社,1988.

Fast Determination Method of Seismic Intensity Distribution Based on Discrete Disaster Information

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	GUAN Zhao-xuan, WAN Yong-ge, ZHOU Ming-yue, WANG Run-yan, SONG Ze-yao, HUANG Shao-hua, GU Pei-yuan. Seismogenic Fault Plane and Geodynamic Discussion of the 2024 Wushi M_S7.1 Earthquake, Xinjiang, China [J]. EARTHQUAKE, 2024, 44(2): 1-11.
[2]	LI Yue, LIU Zhen-hui, MA Han-yu, WANG Yi-xi, SHAO Yong-xin. Permeability Changes of Tianjin Typical Observation Wells and Coseismic Response Mechanism to Maduo M_S7.4 Earthquake [J]. EARTHQUAKE, 2024, 44(2): 33-51.
[3]	JING Tao, Boonphor Phetphouthongdy, Chansouk Sioudom, LIU Yang-yang, LI Ji-geng, KANG Chun-li, MA Wei-yu. Analysis of Outgoing Longwave Radiation Changes before and after the Dengta M_S5.1 Earthquake Based on Tidal Additional Tectonic Stress [J]. EARTHQUAKE, 2024, 44(2): 52-62.
[4]	YANG Yan-ming, SU Shu-juan, WANG Lei. Determination of Rupture Direction and Seismogenic Structure of the 2020 Heerlinger M_L4.5 Earthquake in Hohhot, Inner Mongolia [J]. EARTHQUAKE, 2024, 44(2): 63-85.
[5]	WANG Ting-ting, BIAN Yin-ju, REN Meng-yi, YANG Qian-li, HOU Xiao-lin. Seismic Event Recognition Software [J]. EARTHQUAKE, 2024, 44(2): 104-119.
[6]	SONG Cheng, ZHANG Yong-xian, XIA Cai-yun, BI Jin-meng, ZHANG Xiao-tao, WU Yong-jia, XU Xiao-yuan. Retrospective Study on the Forecasting of the Three M_S≥5.0 Earthquakes Since 2019 in North China Based on PI Method [J]. EARTHQUAKE, 2024, 44(2): 120-134.
[7]	LIU Jun-qing, ZHANG Xiao-gang, ZHANG Yu, CAI Hong-lei, CHEN Zhuo, BAO Xiu-min. Study of Seismic Moment Tensor Inversion by Multi-point Sources for Jishishan M_S6.2 Earthquake on December 18, 2023, in Gansu Province, China [J]. EARTHQUAKE, 2024, 44(2): 169-177.
[8]	HUANG Feng, XIONG Ren-wei, LIN Jing-dong, ZHAO Zheng, YANG Pan-xin. Geomorphic Index and Activity Characteristics of the Mid-Segment of Jiali Fault [J]. EARTHQUAKE, 2024, 44(1): 1-18.
[9]	SHU Tian-tian, LUO Yan, ZHU Yin-jie. The Source Rupture Process and the Strong Ground Motion Estimation of the 2022 M_S6.8 Earthquake in Luding, Sichuan [J]. EARTHQUAKE, 2024, 44(1): 19-36.
[10]	WU Xu, XUE Bing, LI Jiang, ZHU Xiao-yi, ZHANG Bing, HUANG Shi. Design and Implementation of Borehole Comprehensive Observation Timing System [J]. EARTHQUAKE, 2024, 44(1): 37-49.
[11]	BO Wan-ju, ZHANG Li-cheng, SU Guo-ying, XU Dong-zhuo, ZHAO Li-jun. Thoughts on Monitoring and Forecasting Methods of Strong Earthquake with Crust Deformation Data [J]. EARTHQUAKE, 2024, 44(1): 64-77.
[12]	YUE Xiao-yuan, LI Yan-e, ZHONG Shi-jun, WANG Wei, WANG Yan, MA Liang. Anormalies of b-value Changes before M≥4.0 Earthquake in Tangshan Old Seismic Region [J]. EARTHQUAKE, 2024, 44(1): 94-108.
[13]	JIA Xin-ye, BAI Shao-qi, JIA Yan-jie, LIU Fang, NA Re. Study on Lg Wave Attenuation and Site Response Characteristics in Central and Western of Inner Mongolia, China [J]. EARTHQUAKE, 2024, 44(1): 109-117.
[14]	CHEN Guang-qi, WU Yan-qiang, XIA Ming-yao, LI Zhi-yuan. The Japan Noto Peninsula M7.6 Earthquake on January 1, 2024: Focal Characteristics, Disaster Situation and Emergency Response [J]. EARTHQUAKE, 2024, 44(1): 141-152.
[15]	YANG Pan-xin, XIONG Ren-wei, HU Chao-zhong, GAO Yuan. Preliminary Analysis of the Seismogenic Tectonics for the 2023 Jishishan M_S6.2 Earthquake in Gansu Province [J]. EARTHQUAKE, 2024, 44(1): 153-159.