基于偏度的地震热红外异常提取

doi:10.3969/j.issn.0253-4967.2020.06.015

地震地质 ›› 2020, Vol. 42 ›› Issue (6): 1509-1524.DOI: 10.3969/j.issn.0253-4967.2020.06.015

• 新技术应用 • 上一篇

基于偏度的地震热红外异常提取

刘文宝¹⁾, 孟庆岩^2),*, 张继超¹⁾, 张颖²⁾, 卢显³⁾, 孟亚飞²⁾

1)辽宁工程技术大学, 测绘与地理科学学院, 阜新 123000;
2)中国科学院空天信息创新研究院, 北京 100101;
3)中国地震台网中心, 北京 100045

收稿日期:2020-01-15 修回日期:2020-07-13 出版日期:2020-12-20 发布日期:2021-02-24
通讯作者: * 孟庆岩, 男, 1971年生, 研究员, 主要从事城市陆表环境遥感、地震红外遥感方面的研究, E-mail: mengqy@radi.ac.cn。
作者简介:刘文宝, 男, 1993年生, 2017年于辽宁工程技术大学获测绘工程专业学士学位, 现为辽宁工程技术大学测绘工程专业在读硕士研究生, 研究方向为地震热红外遥感, E-mail: 1092410795@qq.com。
基金资助:
国家重点研发计划项目(2019YFC1509202, 2019YFC1509200)、国家高分辨率对地观测重大科技专项项目 “环境保护遥感动态监测信息服务系统(二期)”(05-Y30B01-9001-19/20-1)和亚太地震二期项目 “地震前兆特征的星地一体化观测研究”共同资助

SEISMIC THERMAL INFRARED ANOMALY EXTRACTION BASED ON SKEWNESS

LIU Wen-bao¹⁾, MENG Qing-yan²⁾, ZHANG Ji-chao¹⁾, ZHANG Ying²⁾, LU Xian³⁾, MENG Ya-fei²⁾

1)School of Geomatics, Liaoning Technical University, Fuxin 123000, China;
2)Aerospace Information Research Institute, Chinese Academy of Sciences, Beijing 100101, China;
3)China Earthquake Networks Center, Beijing 100045, China

Received:2020-01-15 Revised:2020-07-13 Online:2020-12-20 Published:2021-02-24

摘要/Abstract

摘要： 地震热异常的存在已被大量震例研究所证实, 但天气仍是热异常精细提取的限制因素。为此, 文中在提取热异常时先采用时间域差值, 后计算空间域差值以去除天气因素的影响; 引入偏度异常数据监测算法, 针对不同样本数选择不同阈值判断热异常。基于以上新算法分析了2016年12月8日呼图壁M_S6.2、 2017年8月8日九寨沟M_S7.0和2017年8月9日精河M_S6.6地震的热异常时空分布情况。结果表明: 1)先采用时间域差值、后计算空间域差值将减少云对温度空间分布差异造成的热异常假象; 2)在样本数满足异常判断需求的前提下, 当背景场数量发生变化时, 不同样本数对应不同阈值的热异常面积基本不变, 热异常判断阈值的稳定性更强; 3)九寨沟M_S7.0地震的震前热异常整体围绕震中从NW军功断裂向NE陇县-宝鸡断裂以顺时针移动; 呼图壁M_S6.2地震的震前热异常从南往北整体向震中移动; 精河M_S6.6地震的震前热异常整体从NW的塔斯特-巴尔雷克断裂附近向震中移动且呈条状; 4)分析多年热异常与地震间的关系发现, TPR随震级的增大升高, 即震级越高则震前发生地震热异常的概率越大, 该发现对未来地震预报具有重要意义。

关键词: 地震热异常, 偏度, 背景场, 时间域差值, 空间域差值

Abstract: The seismic thermal anomaly has been confirmed by a large number of earthquake case studies, but the weather factor is still the limiting factor for the fine extraction of thermal anomalies. In the past, in order to eliminate the short-term noise of meteorology, the spatial domain difference value was used to replace the temperature value in the original remote sensing image, but the cloud mask will affect the spatial domain mean value, which makes the spatial domain difference value not representative. This causes thermal anomalies due to differences in cloud masks and spatial distribution of temperature. In previous RST studies, the thermal anomaly thresholds were judged to be different values of 1.6, 2, 3, and 4, and there was no stable value. When the number of background fields changes under the same threshold, the thermal anomaly area will change. Therefore, when constructing the background field, the time domain difference is used first and then the spatial domain difference is calculated to remove the weather influencing factors. By introducing skewness abnormal data monitoring algorithm, different sample numbers correspond to different thresholds in thermal abnormality judgment. In this experiment, the areas of 32.70°~42.72°N and 96.37°~106.65°E in Gansu, Qinghai and Sichuan were used as the study area. The new algorithm is used to analyze the spatial and temporal distribution of thermal anomalies in Hutubi M_S6.2 earthquake on December 8, 2016, Jiuzhaigou M_S7.0 earthquake on August 8, 2017, and Jinghe M_S6.6 earthquake on August 9, 2017. Statistical analysis is made on the statistical relationship between earthquakes of magnitude 4 and above and thermal anomalies in the study area from January 1, 2003 to August 31, 2019. Experiments and results show that: 1)By analyzing the annual mean surface temperature map in 2004, it was found that the night temperature in Qinghai Province in the study area was lower than that in other areas, and the night temperature in the southern Gansu and desert areas in the northeast of the study area was relatively high. On June 26, 2004, most of the cloudless images were in the low-temperature region of Qinghai Province, which resulted in a low average value of the spatial domain. The temperature difference between the high-temperature and cloudless regions of Qinghai Province and Gansu Province was relatively large, so the spatial domain difference caused the false thermal anomalies. The difference in time domain is calculated before calculating the difference in spatial domain, and the thermal anomaly almost disappears. Using the difference in time domain and then calculating the difference in spatial domain will eliminate the false thermal anomaly caused by the difference in temperature and spatial distribution of clouds. 2)Through experiments, it is found that the skewness in different sample numbers used in this paper corresponds to different thresholds and the position and area of thermal anomalies are closest when the RST threshold is 4.5. When the RST is at a threshold of 4.5 and the number of background fields is 12, 14, and 16, respectively, the thermal anomaly area becomes smaller as the number of background fields increases, but for the skewness of different thresholds corresponding to different sample numbers in the background when the number of fields is 12, 14, and 16, respectively, the change in thermal anomaly area is small. It is obtained that under the premise that the number of samples satisfies the abnormality judgment, different sample numbers corresponding to different thresholds will basically keep the thermal anomaly area unchanged when the number of background fields changes, and the thermal anomaly threshold judgment stability gets stronger. 3)By extracting the thermal anomalies of Hutubi M_S6.2 earthquake on December 8, 2016, Jiuzhaigou M_S7.0 earthquake on August 8, 2017, and Jinghe M_S6.6 earthquake on August 9, 2017, it was found that the thermal anomaly before the Jiuzhaigou M_S7.0 earthquake moved around the epicenter from the northwest Jungong Fault to the northeast Longxian-Baoji Fault in a clockwise direction; Before the Hutubi M_S6.2 earthquake, the whole thermal anomaly moved from south to north to the epicenter; Before the Jinghe M_S6.6 earthquake, the overall thermal anomaly moved from the vicinity of the northwest Tuster-Ballake Fault to the epicenter and was “/” shaped. 4)There were 210 earthquakes with M_S≥4.0 in the study area, and a total of 98 thermal anomalies occurred. The total number of thermal anomalies corresponding to the earthquake is 46, accounting for 46.94%; the number of earthquakes with thermal anomalies found in 210 earthquakes is 53, accounting for 25.2%, among them, 73.6%were preceded by thermal anomalies. By analyzing the relationship between thermal anomalies over the years and earthquakes, it is found that the TPR value increases with the magnitude of earthquake. Although the number of strong earthquakes in the study area is small and the TPR value of strong earthquakes in this experiment is not representative, the overall trend shows that the probability of earthquake thermal anomalies increases with the increase of the earhtquake magnitude. The greater the probability of occurrence of seismic thermal anomalies during strong earthquakes, the greater the significance is for future earthquake prediction. In this paper, we use two types of data, cloud and surface temperature, to optimize the algorithm to remove the influence of weather factors on seismic thermal anomalies. However, the influence of topography and ground features on temperature still exists, and there is currently no good way to judge and rule it out.

Key words: seismic thermal anomaly, skewness, background field, time domain difference, spatial domain difference

中图分类号:

P315.72⁺8

刘文宝, 孟庆岩, 张继超, 张颖, 卢显, 孟亚飞. 基于偏度的地震热红外异常提取[J]. 地震地质, 2020, 42(6): 1509-1524.

LIU Wen-bao, MENG Qing-yan, ZHANG Ji-chao, ZHANG Ying, LU Xian, MENG Ya-fei. SEISMIC THERMAL INFRARED ANOMALY EXTRACTION BASED ON SKEWNESS[J]. SEISMOLOGY AND GEOLOGY, 2020, 42(6): 1509-1524.

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基于偏度的地震热红外异常提取

SEISMIC THERMAL INFRARED ANOMALY EXTRACTION BASED ON SKEWNESS

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