大地震震前热异常提取方法的对比研究--以2014年 MW6.9 于田地震为例

doi:10.3969/j.issn.0253-4967.2022.06.009

摘要/Abstract

摘要：

地震震前热参数异常提取方法的可靠性对于地震震前热参数异常变化研究至关重要。文中以2014年2月12日于田 M_W6.9 地震为典型震例, 以2008年汶川 M_W7.9 地震为验证震例, 对目前研究中广泛使用的2种异常提取方法: ZS(Z-score)法和RST(Robust satellite technology)法在实际震例中的提取效果、对异常变化的敏感程度、对背景信息的抑制能力和对地震信息的指示性4个方面进行了详细的定性和定量化评估。于田地震震前, 地表温度和长波辐射出现了多次间歇性突发异常, 随着地震的邻近, 异常出现的频次增加, 异常空间分布逐渐向断裂带周围集中, 最大异常变化出现在地震前一个月。2种方法提取结果的差异主要表现在异常变化出现的频率和幅度上, RST法得到的异常频次和幅度都高于ZS法。为探究造成差异的原因, 我们进一步结合地震前后2个地震平静年的数据, 对2种方法进行了定量化评估, 结果表明: 1)ZS法和RST法对于微弱异常变化都具有一定的敏感性; 2)ZS法相较于RST法对于其他因素引起的热参数异常变化的抑制作用更强; 3)针对地表温度数据, ZS法的提取结果对地震震中的指示性略优于RST法, 而RST法对于长波辐射数据的效果则更好; ZS法的归一化距离指数最大值出现的时段距离发震时段更近; 4)汶川地震的定量化对比结果与于田地震略有不同, 这可能是受到研究区地物类型分布的影响。综合上述研究成果, 我们认为ZS法是更为简便有效的地震热参数异常提取方法。针对震前热参数异常提取方法的对比研究有助于我们了解不同方法的优缺点和适用性, 提高地震热参数异常提取的可靠性。

关键词: 于田M_W6.9地震, 震前热异常, ZS法, RST法, 定性与定量对比

Abstract:

The reliability of anomaly extracting methods is crucial for pre-seismic thermal anomalies research. However, there is a lack of relevant researches. We compared two commonly used anomaly extracting methods, Z-score(ZS)and Robust satellite technology(RST)method, taking the 2014 Yutian earthquake as a typical example and the 2008 Wenchuan earthquake as a validation. The four aspects of extracted results are compared qualitatively and quantitatively, including the extraction effect, sensitivity to slight change, suppression of background information and indication of seismic information in the actual earthquake case. Moreover, the extracted results of validation case are used to validate the reliability of typical case results. Many intermittent anomalies in surface temperature and outgoing longwave radiation appeared before Yutian earthquake. The frequency of anomalies increases with the proximity of earthquake. The spatial distribution of surface temperature and outgoing longwave radiation anomalies gradually concentrated around the fault zone at the same time. The largest surface temperature and outgoing longwave radiation anomalies occurred one month before Yutian earthquake. The difference between the extraction results of ZS and RST method is mainly manifested in the frequency and amplitude of anomaly changes. The frequency and amplitude of anomaly changes obtained by RST method are higher than those obtained by ZS method. To further explore the reason for these differences, we further evaluate the two methods quantitatively by combining the data of two non-seismic years before and after Yutian earthquake respectively. The sensitivity of anomaly extraction method represents its ability to identify the slight changes of thermal parameters caused by the seismogenic process. The two methods are sensitive to slight changes, but the RST method is better than ZS method. The background information represents normal variation in surface temperature and outgoing longwave radiation caused by non-seismic factors. Suppression of background information determines the accuracy of extraction results. The comparison results show that both methods have certain suppression effect to background information, but the ZS method is better. The spatial distribution of pre-seismic thermal anomalies is an important index for predicting earthquake information(e.g. time of occurrence and location of epicenter). The results of quantitative comparison through normalized distance index show that for surface temperature data, ZS method is slightly better than RST method in indicating the location of epicenter. However, RST method is better for outgoing longwave radiation data. The maximum value of normalized distance index of ZS method occurred closer to the origin time of earthquake. We used the same quantitative evaluation method for the validation earthquake case. The verification results show that in addition to the sensitivity to anomaly changes, the comparison results of the two earthquake examples are similar in terms of the ability to suppress background information and indicate earthquake information. The difference is that ZS method has a better ability to suppress background information and RST method is better in indicating earthquake epicenter in the verification earthquake example. The main reason for the difference in extraction effect between the two methods is that the RST method averages the ground feature classification, and the difference between the observed value and the average value of the classification makes the RST method have a certain amplification effect on the weak signal. The difference between the typical earthquake case and the verification earthquake case is mainly due to the different complexity of the object types in the regions. Based on the above research results, we believe that ZS method and RST method have certain ability to extract pre-seismic anomalies. However, comparatively speaking, the RST method also has a good effect on the extraction of anomalies caused by other factors, and there is uncertainty in the ground feature classification. We believe that ZS method is a more appropriate and simple anomaly extraction method in the general seismic anomaly change extraction.

Key words: Yutian M_W6.9 earthquake, pre-seismic thermal anomalies, ZS method, RST method, qualitative and quantitative comparison

中图分类号:

吴玮莹, 单新建, 屈春燕, 李新艳. 大地震震前热异常提取方法的对比研究--以2014年 M_W6.9 于田地震为例[J]. 地震地质, 2022, 44(6): 1503-1520.

WU Wei-ying, SHAN Xin-jian, QU Chun-yan, LI Xin-yan. COMPARATIVE STUDY ON THERMAL ANOMALIES DETECTION METHOD BEFORE STRONG EARTHQUAKE: TAKING THE 2014 M_W6.9 YUTIAN EARTHQUAKE AS AN EXAMPLE[J]. SEISMOLOGY AND GEOLOGY, 2022, 44(6): 1503-1520.

图/表 13

图 1 地震异常提取的流程图

Fig. 1 Flow chart of seismic anomalies extraction.

图 2 研究区的区域构造背景图

Fig. 2 Tectonic map of the study area.

图 3 2014于田地震震前3个月的地表温度和长波辐射ZS 8d平均值的三维时空特征分布图图m为包含发震时段的结果

Fig. 3 Surface temperature(ST) and outgoing longwave radiation(OLR) three-dimensional maps based on 8-day averaged Z-score index values for 3 months before the 2014 Yutian earthquake.

图 4 2014年于田地震震前3个月的地表温度和长波辐射REIRA 8d平均值的三维时空特征分布图图m为包含发震时段的结果

Fig. 4 Surface temperature(ST) and outgoing longwave radiation(OLR) three-dimensional maps based on 8-day averaged REIRA index values for 3 months before the 2014 Yutian earthquake.

图 5 地表温度(a)和长波辐射(b)敏感性测试数据时间序列图

Fig. 5 Time series plot of sensitivity test data for ST(a) and OLR(b).

图 6 利用2009年地表温度(a、 c)和长波辐射(b、 d)数据通过ZS法、 RST法提取得到设定异常提取天数(a、 b)和准确率(c、 d)

Fig. 6 Artificial anomaly extraction days(a and b)and accuracy rate(c and d)obtained from 2009 surface temperature(a and c)and outgoing longwave radiation(b and d)data extracted by ZS and RST methods.

图 7 利用2015年地表温度(a、 c)和长波辐射(b、 d)数据通过ZS法、 RST法提取得到设定异常提取天数(a、 b)和准确率(c、 d)

Fig. 7 Artificial anomaly extraction days(a and b)and accuracy rate(c and d)obtained from 2015 surface temperature(a and c)and outgoing longwave radiation(b and d)data extracted by ZS and RST methods.

图 8 2009年(a、 c)和2015年(b、 d)地表温度(a、 b)和长波辐射(c、 d)异常像元密度在不同异常标准下的统计结果

Fig. 8 Statistical results of surface temperature(a and b)and outgoing longwave radiation(c and d) anomaly pixel densities under different anomaly standards in 2009(a and c)and 2015(b and d).

图 9 基于地表温度(a)和长波辐射(b)数据的ZS法和RST法对地震震中指示性的比较结果图

Fig. 9 Comparison of epicentre indication ability of surface temperature(a) and long wave radiation(b)obtained by ZS and RST methods.

表1 ZS法、 RST法计算得到最大NWI值时段距离地震发震的天数(数字表示震前天数)

Table1 The days from the maximum NWI value period to the occurrence of earthquake calculated by ZS and RST methods (The number represents the days before the earthquake)

热参数	异常标准
	2		2.5		3
	ZS	RST	ZS	RST	ZS	RST
ST	18	18	18	0	1	18
OLR	101	101	2	101	13	101

表2 ZS法、 RST法针对验证震例计算得到的最大NWI值时段距离地震发震天数(数字表示震前天数)

Table2 The days between the maximum NWI value period and the earthquake occurrence calculated by ZS and RST methods from the verification earthquake case(The number represents the days before the earthquake)

异常标准	2		2.5		3
方法	ZS	RST	ZS	RST	ZS	RST
ST	7	41	7	34	70	45
OLR	45	45	19	43	14	43

图 10 针对验证震例的异常变化敏感性(a、 b)、对背景信息抑制能力(c、 d) 和对地震信息指示性(e、 f)的测试结果图

Fig. 10 The test results of sensitivity to anomaly change(a and b), ability to suppress background information(c and d)and indicate seismic information(e and f)of the verification earthquake case.

图 11 ZS法和RST法信号部分和噪声部分在整个研究时段内每天最大值与最小值的差异时间序列曲线 a、 b 信号部分的时间序列曲线; c、 d 噪声部分的时间序列曲线; a、 c 利用ST数据得到的结果; b、 d 利用OLR数据得到的结果

Fig. 11 The time series curve of difference values between the maximum and minimum values of the signal part and the noise part of the ZS method and the RST method for each day during the whole study period.

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