安徽省地电监测能力综合评价

以影响地电观测质量的主要因素及映震能力作为地电台站监测能力的主要评价指标,对安徽省5个地电台站的监测能力进行了综合评价,得到了安徽省地电前兆的基本情况,为安徽省未来的地电台站建设奠定了基础.     

内蒙古区域地震台网监测能力研究

国际上新近发展的“基于概率的完整性震级”(PMC)方法,具有可考察地震定位中由于台站人为选择等造成的台网监测能力下降,以及避免传统基于G-R关系的统计算法因地震数目过少而无法评估等优点.本研究利用PMC方法,计算得到内蒙古区域地震台网39个台站对周边地震事件的检测概率及台网检测概率.单台检测概率结果显示:PMC方法能够客观地反映39个台站对地震事件的检测能力;因台网布局等影响,内蒙古区域地震台网中西部和中东部地区的台站检测能力较强,而靠近蒙古、俄罗斯边境的台站, 阿拉善右旗附近地区的台站,以及邻近吉林、黑龙江等地区的台站检测能力较低.合成检测概率结果显示,由于邻省台站的引入,全区80%的地区基于概率的最小完整性震级M_P达到2.2左右,其余地区M_P达到3.3左右.为提高地震台网监测能力,建议在监测能力较弱的中蒙交界地区、东北部地区,以及阿拉善左旗以西地区适度加密台站,进一步优化台网布局.      

中国地震台网监测能力评估和台站检测能力评分(2008—2015年)

针对中国地震台网"十五"项目建成后的地震监测能力科学评估的需求,为进一步优化台网布局、提升边疆海域等重点地区监测能力,本研究利用"基于概率的完整性震级"（PMC）方法,对中国地震台网1001个台站以及2008-10-01-2015-09-17期间实际产出的地震观测资料进行了研究,分析了指定震级档下的检测概率P_E和最小完整性震级M_P的分布.除台网整体监测能力分布外,为直观地用单分值表述逐个台站的地震检测能力,本文发展了基于等振幅曲线的"地震检测能力评分表",给出了国家台和区域台每个台站的地震检测能力评分统计特征和空间分布特征.此外,研究中还采用设定"最佳"地震监测能力目标函数的方式,模拟了通过改进观测条件可获得的地震台网监测能力提升的理论结果.研究结果表明,我国华北和东南沿海等东部地区地震监测能力较高,西部尤其是青藏高原南部地区M_p仅约为4.5,近海海域M_p仅约为3.5;从单个地震台站的运行效益角度,台网运行水平和地震观测资料的分析程度对台站的实际的地震检测能力影响显著,新疆等部分台站稀疏地区地震检测能力较高,而中等台站密度的贵州等部分区域相对较低;国家台的地震检测能力评分D_score系统优于区域台,新疆等西部边疆地区,以及福建等东南沿海地区的D_score明显高于台站密集的东部地区;模拟结果显示,在现有台站布局条件下,通过台站优化改造和提升运维管理水平,可显著提升对内蒙古西部、四川西部、甘肃-青海的北部交界地区、鄂尔多斯地块内部、贵州大部分地区,以及我国近海海域、朝鲜半岛北部和中南半岛北部地区的地震监测能力.     

利用PMC方法评估地震台阵的地震检测能力——以西昌流动地震台阵为例

为实现对高密度、宽频带流动地震台阵地震检测能力的实时、不同深度评估,本研究采用"基于概率的完整性震级"(PMC)方法,以西昌流动地震台阵为例,对2013-01-13—2014-05-14期间平均的地震检测能力、不同震源深度检测能力,以及某一时刻的实时地震检测能力进行了评估.结果表明,PMC方法可识别地震观测资料处理中人为因素对地震检测能力的影响,不同震源深度下地震的检测能力存在差异,其中H=7.5km时,"网内"的完整性震级MP可达ML0.8,而在H=15.0km和25.0km时,"网内"的MP分别为ML1.0和ML1.4.在示例的2014-01-14时刻,非正常运行的台站造成地震检测能力的变化可被清晰识别出.此外,与MAXC和EMR等其它常用方法的对比表明,这些方法可能过高估计了地震台阵的检测能力.     

Local seismic network for monitoring of a potential nuclear power plant area

This study presents a plan for seismic monitoring of a region around a potential nuclear power plant. Seismic monitoring is needed to evaluate seismic risk. The International Atomic Energy Agency has set guidelines on seismic hazard evaluation and monitoring of such areas. According to these guidelines, we have made a plan for a local network of seismic stations to collect data for seismic source characterization and seismotectonic interpretations, as well as to monitor seismic activity and natural hazards. The detection and location capability of the network were simulated using different station configurations by computing spatial azimuthal coverages and detection threshold magnitudes. Background noise conditions around Pyhäjoki were analyzed by comparing data from different stations. The annual number of microearthquakes that should be detected with a dense local network centered around Pyhäjoki was estimated. The network should be dense enough to fulfill the requirements of azimuthal coverage better than 180° and automatic event location capability down to ML?～?0 within a distance of 25 km from the site. A network of 10 stations should be enough to reach these goals. With this setup, the detection threshold magnitudes are estimated to be ML?=??0.1 and ML?=?0.1 within a radius of 25 and 50 km from Pyhäjoki, respectively. The annual number of earthquakes detected by the network is estimated to be 2 (ML?≥?～ ?0.1) within 25 km radius and 5 (ML?≥?～?0.1 to ～0.1) within 50 km radius. The location accuracy within 25 km radius is estimated to be 1–2 and 4 km for horizontal coordinates and depth, respectively. Thus, the network is dense enough to map out capable faults with horizontal accuracy of 1–2 km within 25 km radius of the site. The estimation is based on the location accuracies of five existing networks in northern Europe. Local factors, such as seismic noise sources, geology and infrastructure might limit the station configuration and detection and location capability of the network.     

Detection capabilities of the BURAR seismic array—contributions to the monitoring of regional and distant seismicity

Data recorded with the Bucovina Romanian Seismic Array (BURAR) seismic array between January 2005 and December 2008 were analyzed to verify the monitoring capabilities of regional and distant seismicity. For this time interval, nearly 35,000 events detected by BURAR and identified in seismic bulletins (Preliminary Determination of Epicenters and Romanian Earthquake Catalogue) were investigated using parameters as backazimuth, epicentral distance and magnitude. A remarkably detection capability is emphasized for teleseismic observations (Δ > 20°). BURAR onsets could be associated to almost 60% of all events in the teleseismic distance, with a magnitude detection threshold of 4.5 (mb). When no threshold magnitude is applied, the full detection capability of BURAR is in the same order as the performance of GERES array, which is one of the most sensitive stations in Central Europe. For regional events, detection capability decreases to about 16% of all events within regional distance range. The site conditions (crustal structure and high frequency cultural noise) as well as array dimension, affect the signal coherency and reduce the array detection capability for regional events. For both teleseismic and regional distances, a monthly variation of BURAR detection capabilities has been found; the number of events detected during the summer time is diminished by the specific seasonal human activity and atmospheric conditions (thunderstorms). To prove the good detection capability of the BURAR for teleseismic distances, a comparison with the observations of the Romanian Real Time Network in terms of magnitude and epicentral distance was carried out. The higher signal detection capability of BURAR is due to the array techniques applied in data processing, which enhance the signal-to-noise ratio. The monitoring performed by the BURAR seismic array provides a good azimuthal coverage of the regional and distant seismicity, in a large range of epicentral distances.     

Seismological services of the Australian Bureau of Mineral Resources,Geology and Geophysics

The Bureau of Mineral Resources, Geology and Geophysics provides seismological services which complement those provided by several other agencies.The services comprise the operation of 20 seismograph stations in continental Australia, and the operation of regional data centres for earthquakes and strong earth-motion data. The ambit of the data centres includes BMR stations in Antarctica and Papua New Guinea, and foreign stations in Papua New Guinea and the Solomon Islands. Most of the data are lodged at World Data Centres, and the remainder are available from the BMR national centre.The combined Australian network has provided data at a regional level only for about the last twenty years. These have however, been sufficient to show that although seismicity is low it is not insignificant, and that there are several areas where damaging earthquakes can be expected to recur at 50-year intervals; about 500 Australian earthquakes are located annually.Complete national location capability does not extend below Richter magnitude 4, and it is unlikely that significant improvements can be expected in the near future. In most of the areas where earthquake risk is important from a civil standpoint the detection capability is about magnitude 3. For the other more remote areas advanced techniques based on unattended seismometers and satellite telemetry will probably be needed to attain the same capability.     

气枪信号触发台站的自动快速识别

气枪震源是高度可重复的人工震源,在深部探测工作中应用广泛。以福建省地震局组织开展的水库气枪实验为研究对象,面向未来技术的发展,提出基于气枪激发波形的相关性计算,自动获取气枪信号触发台站情况,并绘制触发台站的分布图。对处理结果分析认为:该方法能快速准确识别触发台站,可迅速作出分布图,直观地反应气枪激发效果,较好地为实验现场实验条件的调整提供依据。     

青海省新增地震台波形数据质量评价

为了进一步提升青藏高原地震监测能力,中国地震局在青海、西藏和新疆3个地区建设地震台站。为确保高质量产出地震数据,以青海地区新增16个地震台站为例,围绕观测数据的完整性和可靠性,基于数据连续率、台基噪声水平和事件波形记录质量,对地震观测数据质量进行评价,结果发现：青海地区新增地震台站观测环境较好,总体运行稳定,数据连续率较高,适合进行宽频带数字地震观测;地震台站空间分布更加均匀,青海省中西部地区理论地震监测能力从约M_S 4.5提升到M_S 2.0,地震监测能力提升。本项工作的开展,为我国青藏高原地震监测能力提升提供了业务化支撑。     

The collection and analysis of seismological data to detect possible violations of a nuclear test ban treaty

In an experimental study of requirements for the operational monitoring of nuclear tests, seismological data collected by a small but globally distributed network of array stations are transmitted to Blacknest Data Analysis Centre.Important features of the experiment have been the improvement of data communications links with the cooperating agencies which operate the overseas arrays and with other national data centres, together with the creation of a data-base on computer files linked to the ARPANETWORK and accessible to collaborating organisations.A brief summary is given of some results of event analyses using data mainly from single recording points at the array stations. These are preliminary results from the network, preceding an eventual improvement in detection capability of the array stations which will ensue when the installation of on-line processing systems is completed.     

基于Java的地震应急流动测震及强震动自动化产出系统

采用Java和MySQL设计一套地震应急流动测震及强震动自动化产出系统,系统主要产出震中位置图、监测能力图、故障台站分布图、流动台站分布图、加速度峰值分布图、速度峰值分布图、仪器烈度分布图等以及各类表格文字。基于该系统,可以有效提高震后应急流动测震台站、故障台站、监测能力、强震动加速度峰值、速度峰值以及仪器烈度等图件的产出速度。     

安徽测震台网监测能力评估

安徽测震台网接收邻省19个测震台站数据,评估该数据对地震监测能力效益的改进,并对今后提高测震台网监测能力进行探讨.     

地震台站噪声水平定量评估及其在气枪源探测中的应用

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。     

镜泊湖火山测震台网监测效能评估

2019年镜泊湖火山测震台网新增2个测震台后,共有5个测震观测子台对火山区进行地震监测.利用其观测数据,进行噪声功率谱和监测能力计算,绘制地震监测能力图,并与原测震台网监测能力进行对比分析.研究表明,镜泊湖火山测震台网监测能力得到很大提升,可满足火山地震监测需要.     

重点地震监视区敏感台站的识别研究

识别显著影响重点监视区地震检测能力的“敏感台站”, 对有针对性地开展地震台网运行维护和加强相关区域天然地震与非天然地震的监视跟踪工作有重要意义。 利用基于概率的最小完整性震级(PMC)方法, 通过对研究区地震台站进行“检测能力评分”(Dscore)和“缺失评分”(Missing Score)方式进行识别研究, 以龙门山断裂南段强震危险区为例的重点监视区“敏感台站”识别结果表明, 研究区内51个台站的“检测能力评分”及“缺失评分”, 可识别对重点监视区地震检测能力影响最大的台站, 给出台站停止运行引起的最小完整性震级的变化, 并探讨了多台站停止运行等造成影响的极限情况。 上述“敏感台站”的识别方式, 可为地震台网运行维护、 针对特定目标区的地震监视跟踪和进一步的台网优化改造提供参考。     

区域台网地震监测能力评估算法的Matlab实现

采用近震震级公式方法,在已知台站噪声水平和震中距的情况下,计算出该台能记录到的最小地震震级,在震中距最近的6个台中,通过组合排序法选取布局最优的4个台进行定位,并取这4个台站中震级最大值作为最小监测能力震级,从而得到局域台网的地震监测能力。运用Matlab软件来实现该算法,并对其中的核心处理技巧进行说明。     

Optimum station distribution to monitor seismic activity of Teide Volcano,Tenerife, Canary Islands

Optimization and location capability methods have been applied to the design of a seismic monitoring network composed of five stations to be installed around Teide-Pico Viejo stratovolcano in Tenerife, Canary Islands.In terms of location errors coming from the relative spatial distribution of seismic stations and hypocenters, the optimum network provides an improvement in epicentral location capability of 60% compared with a preliminary choice of five stations, while its improvement in focal depth determination is between 30% and 60%, depending on the average focal depth of seismic activity. Network enlargement to six stations, adding station CTFE from the Spanish National Geographic Institute (IGN), gives an improvement of 20% with respect to the optimum configuration.The interest and importance of previous planning on optimum distribution of seismic stations have become evident, as well as the need to enlarge the network in the near future, to attain more accurate focal depths.     

CTBT国际监测系统水声监测网络概况

介绍全面禁止核试验条约（CTBT）国际监测系统（IMS）水声监测网络的组成、类型、分布及其监测能力,从台站的地理位置选择、勘址条件及台站构成、性能指标等方面,详细阐述H-相和T-相水声台站的建设和发展,并分析新一代水听器台站的设计理念及研发测试进展,以期为相关技术研究和我国水声台站建设提供参考。     

河南省区域数字测震台网监测能力分析

收集河南省区域数字测震台网建台堪选资料及纳入该台网的外省地震台地震仪噪声背景资料,利用测震学模拟观测仪放大倍数与数字化地震仪噪声背景之间的关系,初步分析该省"十二五"建成台网的地震监测能力,预估"十三五"规划新增预警台后地震的监测能力。     

Event detectability of seismograph stations in Fennoscandia

The event detection probability as a function of ISC magnitude shows significant variations between seismic stations in Fennoscandia. In the teleseismic range, the 50% incremental detection thresholds extend from m_b = 4.5 to 5.5 among those stations that reported to the ISC during 1964–1969; the best stations being located in Finland. Most of this variation, though not all, can be explained from noise level fluctuation and regional signal attenuation effects. A common feature for all stations studied is a significantly better detectatbility for signals from eastern Asia than from western North America at a similar distance range. This is interpreted as resulting from higher attenuation in the mantle of high-frequency signals from the latter region.