共查询到19条相似文献,搜索用时 578 毫秒
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利用华北流动地震台阵观测的垂直分向连续波形数据, 通过计算功率谱密度和相应的概率密度函数, 对华北地区地震环境噪声特征进行了分析研究. 结果表明, 东部平原和沉积盆地2 Hz以上的高频环境噪声水平与全球新高噪声模型(NHNM)相近, 周期3——18 s的平均噪声水平低于NHNM和新低噪声模型(NLNM)的平均值; 山区及西部高原的高频噪声水平明显低于NHNM, 周期1——18 s的噪声水平大多明显低于NHNM和NLNM的平均值; 不同区域18 s以上周期的噪声水平差异相对较小. 流动地震台阵部分台站的环境噪声存在明显的昼夜变化, 个别台站噪声水平明显高于周边台站, 表明这些台站受人类活动干扰较大. 不同台站的噪声水平分析表明, 将台站布设在摆坑内, 能在一定程度上降低高频和低频段的噪声水平. 台站环境噪声特征的研究结果可为流动地震台阵观测数据质量的定量评估, 观测期间的台站优化调整等提供重要依据. 相似文献
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地震台站台基噪声功率谱概率密度函数Matlab实现 总被引:3,自引:3,他引:0
选取2015年四川数字测震台网中筠连和华蓥山地震台记录的垂直分向连续波形数据,利用Matlab软件,计算地震台站台基噪声功率谱概率密度函数,分析地震台站环境噪声特征。结果表明,台站环境噪声功率谱密度概率密度分布对地震事件波形(体波、面波)、人为噪声(台站周围人为活动、车辆及机器噪声等高频干扰)、系统瞬变(数据丢失、地震计小故障)以及仪器标定信号等反映较好。使用台基噪声功率谱概率密度函数方法,有利于监测地震台站数据记录,提高观测数据质量。 相似文献
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宽频带地震观测台站仪器勘选工作包括野外仪器测试、台基背景噪声水平计算及分析、台站综合评价。通过陆良大萨卜龙宽频带地震观测台站仪器勘选,对测试设备系统组成及辅助工具进行总结,形成用于减小气温、气流对地震计干扰的四级防护架设方法,梳理了测试数据中对于天然地震事件、干扰事件(非天然地震事件)的预处理方法。对测试数据进行干扰评估,干扰频度N=0.03 <0.5,且非天然地震事件持续时间占记录时间的百分比R=0.01%<0.5%,表明勘选台址几乎不受干扰;对预处理数据进行噪声计算与分析,结果发现,在1—20 Hz频带,台基噪声三分量平均功率谱密度与全球低噪声模型NLNM相比,平均偏高17—38 dB,RMS有效值小于3.16×10-8m/s,表明勘选台站周边无明显干扰源,台基背景噪声水平达Ⅰ类台站建设标准。综合评价认为,该勘选点位观测环境较好,可作为宽频带地震观测台站建设站点。 相似文献
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对福建气枪源探测实验中所接入315个实时传输台站分1~10 Hz、0.1~1 Hz、10~60 s 3个频段进行台网噪声水平评估研究。统计240个小时的背景噪声记录,得到各台站的噪声水平MODE线,再利用本文提出的全球新高低噪声模型线与MODE线所占面积比来量化台网噪声水平,根据不同色标将台网噪声水平划分为十个等级进行评估,评选出优质台站。进一步研究背景噪声对气枪激发效果的影响,验证了台站接收能力与背景噪声密切相关,分析了不同台基(固定、加密、流动、海底)环境噪声水平的影响,得出环境噪声水平由低到高分别为固定台、加密台、流动台、海底台。通过台网噪声评估能有效提高气枪震源信号的检测能力,也为优质台站重点维护提供重要参考。 相似文献
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为进一步加强对福建地区噪声特性的认识以及提升台站地震观测质量,计算了2014年福建地震台网宽频带地震仪连续观测数据的功率谱概率密度函数,并分析其影响因素和不同频段时空变化特性。结果表明:人文噪声平均水平最高地区位于福建沿海福州至厦门一带,07:00—18:00的功率谱密度要明显高于其它时间段,12:00左右出现间歇性低谷期,夜间有不同程度的降低,日变化除了在春节假期大幅下降外,均处于较为稳定态势;福建地区次级微震主要成分是Rayleigh波,主频约为2.7 s,主微震主频约为16 s,次级微震平均水平最高地区也位于沿海一带,向内陆方向呈衰减趋势,其日变化明显,与台风和潮高有较高的相关性。 相似文献
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选取四川省数字测震台网2015年1月1日至2018年12月31日期间60个固定台站的三分量连续波形记录,计算了台站噪声加速度功率谱密度及相应的概率密度函数分布,统计了不同频率下的噪声功率谱密度值分布,对不同区域、不同频率下背景噪声水平的变化特征予以分析。结果表明:大部分地震台站的高频段噪声由于受到台站附近人为的、规律的作息生活和生产方式的影响,呈现明显的季节性变化和日变化,即夏季噪声水平升高,冬季降低,在农历春节期间达到全年最低值,地理空间分布特征不明显;第二类地脉动冬季噪声水平升高,夏季降低,季节性变化明显,平均变化为1—5 dB,且冬季峰值出现的频率向长周期方向移动1—2 s,呈现明显的地理空间分布特征,川东地区平均噪声水平最高,攀西地区次之,川西高原最低;与第二类地脉动相比,第一类地脉动观测到的噪声能量较弱,季节性变化不明显,地理空间分布的噪声水平差异明显减小;在20 s以上的长周期部分,台站噪声未呈明显的季节性和地理空间分布差异。此外,将地震计安置在山洞和井下,可以有效地降低台站周围干扰源、温度和压强对高频段和长周期观测的影响,噪声水平低于地表安装方式。 相似文献
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2011年3月11日,日本本州三陆冲发生9.0级特大地震,由864个台站组成的高灵敏度测震台网Hi—net、1028个台站组成的强震台网K-net、688个台站组成的基盘强震台网KK—net、83个宽频带地震台站组成的宽频带台网F—net以及205个台站组成的日本气象厅(JMA)地震台网组成的日本地震监测系统, 相似文献
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本文采用多通道相关分析方法测量并分析研究了国内地震观测常用的6种进口地震数据采集器的自噪声.结果表明:6种进口地震数据采集器无论在普通增益还是高增益模式下,当频带范围处于1 Hz以下时,自噪声均低于NLNM低噪声模型(灵敏度按750 V·s/m换算);在低增益模式下,当频带范围处于1 Hz以上时,各数据采集器的自噪声与NLNM低噪声模型高低交错,须根据观测目的谨慎使用;Q330HRS和Reftek-130/130S型数据采集器的高增益模式较适合测量宽频带地震计的自噪声. 相似文献
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根据前人和作者最新深部地球物理探测研究成果,完成了中国东部大陆(105°E以东)1°×1°壳-幔结构比值R(R=C/L,C为地壳厚度,L为岩石层厚度)分布图的编绘.研究了R值分布与东部大陆岩石层分块、大地构造形态特征;R值分布与东部大陆地震活动的非均匀性特征;R值分布的动力学内涵.结果表明:1.R值等值线特征反映了岩石层块体划分、大地构造形态,R值特征与岩石层块体划分、大地构造形态有其深部成因上的联系;2.高R值区对应地震高活动区,因而R值可作为地震区划、地震危险性评定的定量指标,R值是地震活动的动力因子. 相似文献
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使用中国地震台网888个宽频带地震台站2010年1月至2011年6月记录的连续波形垂直向分量, 进行了中国大陆背景噪声强度时空分布研究, 得到了中国大陆周期为10 s的背景噪声强度的时空分布图像。 背景噪声强度的时间分布具有一定的季节性和周期性变化特征, 研究表明2011年1~3月间的背景噪声强度最高。 背景噪声强度空间分布显示, 中国大陆背景噪声强度呈现明显的分区特性, 其分布与地质结构无明显相关性, 表明背景噪声场的强度高于场地效应。 其中, 东南沿海地区的背景噪声强度最大, 向内陆地区逐渐衰减, 至青藏高原地区背景噪声强度减至最小。 这种方向性的强度分布很可能与菲律宾和太平洋的潮汐等因素有关, 受印度洋的影响不大; 而到新疆地区, 背景噪声的强度又有一定程度增加, 表明这一地区的背景噪声主要不是来源于中国东南海域, 而是来自于欧亚大陆内部。 本研究得到的背景噪声强度可以为多个地区的微震强度提供基础数据资料, 也可以为背景噪声互相关的地震学研究提供参考。 更为重要的是, 还可以为基于背景噪声提取面波衰减研究提供基础数据, 进而实现从背景噪声中提取面波衰减。 相似文献
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Successive waveforms of the vertical component recorded by 888 broadband seismic stations in the China Seismography Network from January,2010 to June,2011 are used to investigate the temporal and spatial distribution of ambient noise intensity,and the images of ambient noise intensity at the period of 10 s in the Chinese Mainland are obtained. The temporal variation of ambient noise intensity shows some seasonal and periodic characteristics. The maximum ambient noise intensity occurred from January,2011 to March,2011. The spatial distribution images of ambient noise intensity show obvious zoning features,which doesnt correlate with surface geology,suggesting that the noise field is stronger than the site factors. The strength in southeastern coastal areas reaches its maximum and generally decreases toward to inland areas,and arrives at the minimum in the Qinghai-Tibetan Plateau. The zonal intensity distribution is probably correlated with ocean tides from the Philippine Ocean and the Pacific Ocean. It also shows that the influence from the Indian Ocean seems small. However, the ambient noise intensity increases to a certain degree in the Xinjiang area,indicating that the main source of ambient noise in the western area of the Chinese Mainland is not derived from the East and South China Sea,but rather from the deep interior of the Eurasian continent. The ambient noise intensity obtained in this study can supply reference for seismology research based on ambient noise correlation. Moreover,it can supply basic data for attenuation research based on ambient noise, and thus help achieve the object of retrieving the attenuation of Rayleigh waves from ambient noise. 相似文献
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针对现阶段地震人员死亡评估模型在评估特定区域地震时评估结果误差较大的问题,结合中国地震灾害特点、人口分布情况等,将中国大陆划分为西北、西南和大陆东部三个地区,并对各区域按照人口密度进行分级。采用多元非线性回归方法,选取震中烈度、震区面积、抗震设防烈度参数建立分区域的地震灾害人员死亡评估模型。研究结果表明,该模型在西北、西南地区的验证结果较好,适用于中国地震灾害情况,可以用于震后快速盲评估,在一定程度上能够避免评估不同震级、相同震中烈度和人口密度的地震时,出现相同结果的情况;虽然该模型在震例较少的大陆东部地区以及城市直下型地震中评估结果需要进一步改进,但为解决特定区域地震死亡评估中误差较大问题提供了思路,能够为震后应急指挥和救援提供数据参考。 相似文献
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Distribution of apparent stress in western China 总被引:2,自引:0,他引:2
Introduction Seismological data (mainly focal mechanism data) has shown to be capable of providing important constraint on the geodynamical models of the eastern Asia in the perspective of stress orientation, stress state (compressional, tensional, or shear), and the source of stress (HUAN, et al, 1979; Xu, et al, 1992). One of the outstanding problems left is the stress level. In principle, within the framework of elasticity, it is impossible to obtain the information of the absolute stress… 相似文献
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UNIFIED EARTHQUAKE CATALOG FOR CHINA’S SEAS AND ADJACENT REGIONS AND ITS COMPLETENESS ANALYSIS 下载免费PDF全文
China’s seas and adjacent regions are affected by interactions among the Eurasian plate, the western Pacific plate, and the Philippine Sea plate. Both intraplate and plate-edge earthquakes have occurred in these regions and the seismic activities are frequent. The coastal areas of China are economically developed and densely populated. With the development and utilization of marine energy and resources along with the development of national economy, the types and quantity of construction projects in the marine and coastal areas have increased, once an earthquake happens, it will cause huge damage and loss to these areas, therefore, the earthquake-related research for these sea areas cannot be ignored and the need for study on these areas is increasingly urgent. One type of essential basic data for marine seismic research is a complete, unified earthquake catalog, which is an important database for seismotectonics, seismic zoning, earthquake prediction, earthquake prevention, and disaster reduction. Completeness and reliability analysis of an earthquake catalog is one of the fundamental research topics in seismology.
At present, four editions of earthquake catalogs have been officially published in China, as well as the earthquake catalogue compiled in the national fifth-generation earthquake parameter zoning map, these catalogs are based on historical data, seismic survey investigations, and various instrumental observations. However, these catalogs have earlier data deadlines and contain the earthquake records for only the offshore regions of China, which are extensions of coastal land. Distant sea regions, subduction zones, and adjacent sea regions have not been included in these catalogs. Secondly, there were no cross-border areas involved in the compilation of earthquake catalogs in the past. It was not required to use magnitudes measured by other countries’ seismic networks and observation agencies to develop an earthquake catalog with a uniform magnitude scale, moreover, there was no formula suitable for the conversion of magnitude scale in China’s seas areas and adjacent regions. Little research has been conducted to compile and analyze the completeness of a unified earthquake catalog for China’s seas and adjacent regions. Therefore, in this study, we compiled earthquake data from the seismic networks of China and other countries for China’s seas and adjacent regions. The earthquake-monitoring capabilities of different sea areas at different time periods were evaluated, and the temporal and spatial distribution characteristics of epicentral location accuracy for China’s seas and adjacent regions were analyzed. We used the orthogonal regression method to obtain conversion relationships between the surface wave magnitude, body wave magnitude, and moment magnitude for China’s seas and adjacent regions, and established magnitude conversion formulae between the China Seismic Network and the ML magnitude of the Taiwan Seismic Network and the MS magnitude of the Philippine Seismic Network. Finally, we developed an earthquake catalog with uniform magnitude scales for China’s seas and adjacent regions.
On the basis of the frequency-magnitude distribution obtained from the magnitude-cumulative frequency relationship (N-T) and the Gutenberg-Richter(GR)law, we conducted a completeness analysis of the unified earthquake catalog for China’s seas and adjacent regions, Then, we identified the beginning years of each magnitude interval at different focal depth ranges and different seismic zones in the earthquake catalog.
This study marks the first time that a unified earthquake catalog has been compiled for China’s seas and adjacent regions, based on the characteristics of seismicity in the surrounding sea regions, which fills the gap in the compilation of the earthquake catalogue of China’s seas and adjacent areas. The resulting earthquake catalog provides a basis for seismotectonics, seismicity study, and seismic hazard analysis for China’s seas and adjacent regions. The catalog also provides technical support for the preparation of seismic zoning maps as well as for earthquake prevention and disaster reduction in project planning and engineering construction in the sea regions. In addition, by evaluating the earthquake-monitoring capability of the seismic networks in China’s seas and adjacent regions and analyzing the completeness of the compiled unified earthquake catalog, this study provides a scientific reference to improve the earthquake-monitoring capability and optimizing the distribution of the seismic networks in these regions. 相似文献
At present, four editions of earthquake catalogs have been officially published in China, as well as the earthquake catalogue compiled in the national fifth-generation earthquake parameter zoning map, these catalogs are based on historical data, seismic survey investigations, and various instrumental observations. However, these catalogs have earlier data deadlines and contain the earthquake records for only the offshore regions of China, which are extensions of coastal land. Distant sea regions, subduction zones, and adjacent sea regions have not been included in these catalogs. Secondly, there were no cross-border areas involved in the compilation of earthquake catalogs in the past. It was not required to use magnitudes measured by other countries’ seismic networks and observation agencies to develop an earthquake catalog with a uniform magnitude scale, moreover, there was no formula suitable for the conversion of magnitude scale in China’s seas areas and adjacent regions. Little research has been conducted to compile and analyze the completeness of a unified earthquake catalog for China’s seas and adjacent regions. Therefore, in this study, we compiled earthquake data from the seismic networks of China and other countries for China’s seas and adjacent regions. The earthquake-monitoring capabilities of different sea areas at different time periods were evaluated, and the temporal and spatial distribution characteristics of epicentral location accuracy for China’s seas and adjacent regions were analyzed. We used the orthogonal regression method to obtain conversion relationships between the surface wave magnitude, body wave magnitude, and moment magnitude for China’s seas and adjacent regions, and established magnitude conversion formulae between the China Seismic Network and the ML magnitude of the Taiwan Seismic Network and the MS magnitude of the Philippine Seismic Network. Finally, we developed an earthquake catalog with uniform magnitude scales for China’s seas and adjacent regions.
On the basis of the frequency-magnitude distribution obtained from the magnitude-cumulative frequency relationship (N-T) and the Gutenberg-Richter(GR)law, we conducted a completeness analysis of the unified earthquake catalog for China’s seas and adjacent regions, Then, we identified the beginning years of each magnitude interval at different focal depth ranges and different seismic zones in the earthquake catalog.
This study marks the first time that a unified earthquake catalog has been compiled for China’s seas and adjacent regions, based on the characteristics of seismicity in the surrounding sea regions, which fills the gap in the compilation of the earthquake catalogue of China’s seas and adjacent areas. The resulting earthquake catalog provides a basis for seismotectonics, seismicity study, and seismic hazard analysis for China’s seas and adjacent regions. The catalog also provides technical support for the preparation of seismic zoning maps as well as for earthquake prevention and disaster reduction in project planning and engineering construction in the sea regions. In addition, by evaluating the earthquake-monitoring capability of the seismic networks in China’s seas and adjacent regions and analyzing the completeness of the compiled unified earthquake catalog, this study provides a scientific reference to improve the earthquake-monitoring capability and optimizing the distribution of the seismic networks in these regions. 相似文献