强震动观测和应用及山西数字强震动台网

对强震动观测的意义,强震仪的发展历史,强震动观测与通常地震观测(测震)的区别,国内外强震动观测的现状以及强震动观测的应用情况进行了论述.此外,对"十五"期间建成的山西数字强震动台网进行了简要介绍.     

宁夏数字强震动台网观测系统

宁夏数字强震动台网观测系统是国家重点建设的防震减灾基础设施项目,由48个数字观测台站和1个强震动台网中心组成.台站采用无人值守方式,利用电话拨号、CDMA和扩频微波以及卫星传输的方式,在台网中心与各强震台之间建立连接,实施远程监控.台网全部采用先进的数字技术,使宁夏强震动观测技术发生了质的变化, 填补了宁夏境内没有固定数字强震台站的空白,大幅度增强了获取近场强震动数据的能力.当宁夏发生4级以上地震时,可以获得多台强震动记录;同时,在监视区范围内发生3级以上地震时,亦可获得多台近场加速度记录,从而为震害快速评估和制定震后应急决策提供可靠依据.     

强震动观测无人值守信息管理自动化

随着中国“数字地震观测网络”项目的启动,中国强震动观测网络将新增大量先进的数字化、网络地震动记录仪,该类型仪器具备大存储容量、自动震动触发、自动报警,本地串口通讯、远程Modem通讯、远程TCP/IP网络通讯等功能,这些先进功能为强震动数据记录、存储、强震动记录以及相关地震信息自动传输创建了硬件基础.新增的大量强震动观测设备,使得强震台网的密度进一步加大,因此可利用的强震动观测数据大大增加,但目前中国的强震观测网络无法及时的收集、分析、处理这些海量数据.而随着国家级、区域级台网中心的进一步扩建、新建,监控中心网络硬件设备、软件齐全,通讯网络大大加强,也使得大数据分析、处理、传输成为可能,在此基础上建立强震动观测无人值守信息管理自动化成为一种可能.并且随着该自动化系统的运行,积累的强震观测记录也可建立强震观测数据仓库,并在数据仓库的基础进一步建立强震分析数据挖掘方法.     

"十五"辽宁数字强震台网的建设

从2002年到2007年期间,根据国家“十五”重点项目—中国数字地震观测台网的部署,辽宁省地震局建设了辽宁省数字强震动台网,共建设了37个固定台站。从而结束了辽宁省内无数字化强震台观测的历史。2个台已获取了2008年11月14日辽宁海城M4.3级。数字强震台网是我省震灾预防工作体系的重要的组成部分。     

2007年宁洱6.4级地震强震动观测记录

"十五"期间建设并投入试运行的中国数字强震动台网云南区域台网有20多个强震动台站记录到宁洱6.4级地震产生的地面运动。记录的最大峰值加速度为431.2cm/s2,这是我国大陆自开展强震动观测以来在一次强震中同时获取记录最多的一次,初步展现了"十五"强震动台站建设的成效。     

辽宁海城M4.3地震强震记录分析

2008年辽宁海城M 4.3地震,辽宁省强震动台网12个强震台站记录到地面运动,是辽宁省自开展强震动观测以来同时获取强震记录最多的一次,记录的最大加速度为167.5 cm·s-2,初步展现了辽宁省强震动台网建设的成效.     

辽宁省数字强震台网建设与运行

辽宁省在“十五”、“十一五”期间,已建成一个具有72个强震台站组成的数字强震动台网。本文从台网布局、技术系统、设备运行等几个方面介绍了辽宁强震台网的情况。     

跟踪短临预报,强化流动观测

在我国大陆地区目前固定强震观测台网尚十分薄弱的这一客观现实下,提出了中国地震局系统建立“短临预报－强震流动观测机制”的设想,将强震同地震预报科研成果紧密相结合,大力加强强震动观测,并就强震观测的原则、执行方式、组织管理模式和装备建设提出了设想和建议。     

新疆地震观测台网建设

介绍新疆地震观测台网发展过程,包括台站建设以及观测设备的更新和发展。观测设备在历经模拟和数字化阶段发展后更加智能化,能够实时、准实时进行数据传输,有效提高了地震监测台网和强震动台网的监测能力。地震监测台网和强震动台网的服务对象不同,地震观测设备和仪器参数、选址条件等也不同,但随着观测技术的发展,地震观测设备不断完善更新,测震宽频带仪器包含强震仪器频带范围,2类台网记录互为补充成为可能。     

强震观测中的关键技术研究

强震动台网的建设规模正在迅猛发展,近期在中国、智利、海地、新西兰、日本和墨西哥等地发生了多次破坏性地震,获得的强震记录数量迅速增加,为地震工程的深入研究提供了契机。然而,强震观测中除获得一批高质量的强震动波形外,也获得了一些异常波形数据,     

Seismic risk assessment of interdependent critical infrastructure systems: The case of European gas and electricity networks

We study the seismic vulnerability of the interdependent European gas and electricity transmission networks from a topological point of view, whereby the electricity network depends on the gas network through gas‐fired power plants. First, we assessed the seismic response for each independent network; then we analyzed the increased vulnerability due to their interdependency. We implemented a probabilistic reliability model that encompasses the spatial distribution of both network structures and their seismic hazard exposure using a Geographic Information System. We characterized the network interdependency using the strength of coupling of the interconnections, together with the seismic response of the independent—gas—network. We calculated the network fragility curves of the independent and dependent networks in terms of various performance measures (connectivity loss, power loss, and impact on the population) and found that the gas network is more seismically vulnerable than the electricity network. The interdependency introduces an extra vulnerability to the electricity network response that decreases with the extensiveness of the networks' damage states. Damage was also evaluated at a local level in order to identify the most vulnerable parts of the network, where it was found that the potential for the highest power loss is located in southeast Europe. Copyright © 2011 John Wiley & Sons, Ltd.     

Seismic reliability assessment of urban water networks

We present a framework for the seismic risk assessment of water supply networks, operating in either normal or abnormal conditions. We propose a methodology for assessing the reliability of water pipe networks combining data of past non‐seismic damage and the vulnerability of the network components against seismic loading. Historical data are obtained using records of damages that occur on a daily basis throughout the network and are processed to produce‘survival curves’, depicting their estimated survival rate over time. The fragility of the network components is assessed using the approach suggested in the American Lifelines Alliance guidelines. The network reliability is assessed using graph theory, whereas the system network reliability is calculated using Monte Carlo simulation. The methodology proposed is demonstrated both on a simple, small‐scale, network and also on a real‐scale district metered area from the water network of the city of Limassol, Cyprus. The proposed approach allows the estimation of the probability that the network fails to provide the desired level of service and allows the prioritization of retrofit interventions and of capacity‐upgrade actions pertaining to existing water pipe networks. Copyright © 2013 John Wiley & Sons, Ltd.     

基于震后低压变化的供水管网功能可靠度分析

供水管网的抗震功能是指供水管网在地震作用下能够满足震后城市特定用水需要（需水量和水压）的能力。地震发生后,供水管网一般处于低压供水状态,使得管网中部分用户的水压和水量不能得到全部满足,导致管网部分节点的实际配水量小于需水量。为此,在传统的管网水力分析基础上考虑节点流量随节点水压的动态变化,通过求解非线性水力方程组,得到管网节点实际流量和水压;同时,借鉴结构可靠度分析方法,引入供水管网系统随机水力模型,给出了震后供水管网功能可靠度分析的一次二阶矩方法。以一实际管网为例,演示了震后低压供水时管网功能可靠度分析的应用方法。     

Watershed structural influences on the distributions of stream network water and solute travel times under baseflow conditions

Watershed structure influences the timing, magnitude, and spatial location of water and solute entry to stream networks. In turn, stream reach transport velocities and stream network geometry (travel distances) further influence the timing of export from watersheds. Here, we examine how watershed and stream network organization can affect travel times of water from delivery to the stream network to arrival at the watershed outlet. We analysed watershed structure and network geometry and quantified the relationship between stream discharge and solute velocity across six study watersheds (11.4 to 62.8 km²) located in the Sawtooth Mountains of central Idaho, USA. Based on these analyses, we developed stream network travel time functions for each watershed. We found that watershed structure, stream network geometry, and the variable magnitude of inputs across the network can have a pronounced affect on water travel distances and velocities within a stream network. Accordingly, a sample taken at the watershed outlet is composed of water and solutes sourced from across the watershed that experienced a range of travel times in the stream network. We suggest that understanding and quantifying stream network travel time distributions are valuable for deconvolving signals observed at watershed outlets into their spatial and temporal sources, and separating terrestrial and in‐channel hydrological, biogeochemical, and ecological influences on in‐stream observations. Copyright © 2016 John Wiley & Sons, Ltd.     

基于改进的风险矩阵法的生命线网络地震脆弱性分析

生命线网络的脆弱性不单单只表示地震发生后对网络作用而产生的后果,还应该包括网络的连通情况。本文在重新确定生命线网络脆弱性定义的基础上,运用风险评估理论中的风险矩阵方法综合考虑生命线网络的连通性能和失效后果两个方面来评价生命线网络的脆弱性,并以一个供气管网为例说明改进的风险矩阵法评价生命线网络脆弱性的有效性和合理性,找出供气管网中脆弱性等级最高的节点,分析其脆弱性等级最高的原因,以便于重点保护,并降低网络的脆弱性。     

An experimental study of sapped drainage network development

In a basin developed on a stream table, effluent subsurface flow supported a channel network that evolved by a combination of headward growth, lateral widening and divide decay. The area occupied by the developing network increased with time. Circularity was used to characterize network evolution which occurred in three phases (initiation, extension and abstraction). Basin sediment discharge declined exponentially with time. Pronounced quasi-cyclic variability was superimposed upon this general trend. Some of the variability was directly linked to changes in the amount of sediment supplied to the channel. The variation of mean network sediment yield (mean sediment discharge scaled by network area) with time adequately described the general decline in sediment discharge as the network evolved.     

云南测震台有线信道与无线信道互为备份传输方案设计

针对云南省测震台网对连续率提升的需求,结合现行网络框架以及已有网络接入条件,通过路由器及服务器配置,设计并实现以有线信道为主,无线信道为辅的传输方案,为提升云南测震台网运行率提供一种选择。     

福建地震前兆台网集成设计与应用

结合”十五”期间福建台网建设的经验,介绍了区域前兆台网集成功能,包括台网结构、数据通信和软件部署设计等方面的集成,通过实践展示了数字地震前兆台网建设的应用效果。     

城市供水管网抗震能力评价研究

供水管网是城市重要的基础设施,为了高效合理地评估现有供水管网的抗震能力,本文从结构安全性角度出发,构建了供水管网综合抗震能力评价指标体系和供水管网综合抗震能力评价模型。综合分析管道各项指标,运用主成分分析法得到指标权重并建立供水管道抗震能力模型,基于图论理论构建了供水管网基础抗震能力评价模型。从物理、社会和时间效应三个维度出发,将管网基础抗震能力通过环境评价修正系数进行修正,构建了精细化的供水管网综合抗震能力评价模型,以此表征管网的易损性,为地震灾害风险评估工作提供支持。通过对深圳市供水管网进行抗震能力评价,将结果与传统震害预测结果对比,说明了评价模型的合理性。