共查询到18条相似文献,搜索用时 265 毫秒
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基于天地图和ArcGIS API建立一套地震应急地图服务模型平台,初步实现地震应急基础数据展示、地震损失预估范围发布、地震空间信息查询与定位、现场灾情反馈与标注和专题地图打印等功能。该平台以天地图为基础,利用ArcGIS API的多种模块为接口,搭建一套交互式、分布式、动态的系统构架,实现基本地震应急地图数据服务;并力求探索地震应急地图服务的初步方案,解决地震专题地图的效率和传播问题,为震时指挥决策提供辅助支撑手段,为今后多灾种信息平台融合提供了参考。 相似文献
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江苏省地震局云计算管理平台设计与实现 总被引:1,自引:0,他引:1
自主可控的虚拟化技术是基于网络且根据用户需求可立即交付使用,空闲时可立即释放软硬件资源的一种共享应用服务。地震行业信息网络为地震行业各个业务提供基础支撑服务,这些服务都可做为SaaS服务部署在地震云平台之上。从而解决了地震信息网络中应急指挥、地震数据存储、地震数据处理,可视化等问题。通过建立基于自主虚拟化的地震云平台,可以将各地震监测机构、管理机构的应用部署在地震云平台上。这对于地震应急时,加强各部门之间协作、提高地震应急救援效率,都具有积极作用。 相似文献
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针对震前灾情难以预估,震后灾情获取缓慢且碎片化,灾情评估误差较大,决策支持不到位,灾情服务缺位等科学问题,综合考虑震前应急准备和灾后应急处置场景,重点研究全时程灾情与决策信息获取和分析手段,震后灾情信息实时汇聚与融合技术,震后基于致死性和易损性相结合的损失综合分析技术,不同区域辅助决策支持要点,面向多用户灾情信息服务产品可视化生成技术,建立灾情推送与信息准实时服务平台及终端,构建基于云架构的智能化、可视化地震应急信息全流程服务平台,开展应急协同服务示范,实现7级以上大地震灾情信息全时程服务。该项目将丰富地震灾情信息获取手段,形成涵盖灾情收集、信息速报、监测预警、分析评估、智能协同和动态发布等地震应急全过程技术平台,提升地震应急信息服务能力,对快速、科学施救具有重要意义。 相似文献
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为了提升地震应急能力,结合地震应急救援工作对地震专题图的需求,利用VB6.0开发出一套适用于地震应急救援的专题地图快速产出系统。该系统建立了相关地区的独立数据库,完全摆脱了对ArcGis、MapSis等专业制图软件的依赖,建立了独立的地震应急图件产出平台。通过输入地震参数,系统可以快速生成震中位置分布图、地震影响场分布图、震中人口分布图、历史地震分布图等专业图件并批量输出。 相似文献
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本文设计的地震信息服务系统,通过对地震信息、多监测台网分布、城镇空间分布和人口热力数据进行充分整合,基于可视化技术Echarts实现了国家、省、市三级地震信息活动大屏可视化、地震震情信息和历史地震统计等功能,并通过Kafka分布式数据处理技术,优化整合现有地震信息数据资源,提升信息服务实效性和可靠性;系统部署在公有云计算平台,用户无需部署系统就可获取相关数据,提供了更便捷的地震信息服务,为政府和应急管理部门提供高效、标准的地震信息服务,提升面向地震灾害的公共服务能力。 相似文献
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利用京津冀基础地理数据、本地化地震灾害快速评估模型、本地化辅助决策模版和离线快速评估与应急制图等技术,实现了支持Web页面与移动端的北京市本地化地震应急工作平台。面向远程应急和移动办公需求,实现了基于Android移动终端的地震快速触发、灾害快速评估、辅助决策、信息自动推送、应急指挥调度、日常运维管理和综合信息查询等功能,在地震应急响应中,打破场所和时间限制,第一时间产出快速评估报告、辅助决策报告和应急专题图件,为北京市地震应急指挥决策提供科学高效的信息服务。平台自运行以来在多次地震应急处置中发挥了重要应用实效。 相似文献
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破坏性地震发生后,地震灾情快速评估作为地震应急指挥技术系统中的核心模块能够为各级政府和应急管理部门地震应急指挥决策提供重要的信息服务,是地震应急救援与指挥决策重要的支撑平台。随着学者对地震应急领域几十年的研究,已经具备了开发新一代地震灾害快速评估系统的条件。本文基于甘肃省分震级地震烈度衰减模型、分区域的地震灾害人员伤亡评估模型、地震应急专题图设计等研究基础,研发了新一代甘肃省地震灾害快速评估原型系统,实现了软件自动触发、分震级地震影响范围估计、分区地震灾害人员伤亡计算,自动生成地震灾情评估报告,提高了系统的自动化水平和计算结果的精度。该软件能够提升甘肃省地震灾害快速响应能力,能够为甘肃省地震灾害应急救援和指挥决策提供更为科学可靠信息服务。 相似文献
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基于ArcGIS Server的地震应急数据与服务共享研究 总被引:1,自引:0,他引:1
ArcGIS Server是基于Web Service用来发布企业级GIS应用程序的综合平台。 本文以地震应急数据与服务共享为研究目标, 分析了ArcGIS Server的体系架构和几种常用共享模式的特点, 提出了基于Web Service和ArcGIS Server的共享模式, 详细阐述了地震应急数据与服务共享的理论方法和系统架构, 实现了基于ArcGIS Server开发地震应急信息共享的原型系统。 相似文献
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After an earthquake, earthquake emergency response and rescue are important ways to mitigate earthquake-induced losses. Various earthquake emergency maps can provide effective references and guidance to those actions. Currently, related studies include the investigation on symbols of emergency maps, remote sensing emergency mapping and GIS-based mapping methods. However, the existing studies overlook the characteristics of rapidity, dynamicity and variety of presentation methods in making earthquake emergency maps. In this paper, a map template matching method is used to quickly make earthquake emergency maps considering their characteristics. We take investigations on the service objects(users)of the earthquake emergency maps to understand the needs of making earthquake emergency maps. The audience theory in mass media field and map information transmission theory are adopted to classify the users of the earthquake emergency maps into four categories: earthquake emergency commanders, technical staffs for decision-making, earthquake emergency rescuers, and the public. The components of different types of users are described and then their diverse demands in earthquake emergency maps are analyzed, such as the needs of on-field disaster information maps, earthquake information maps, physical geography and social economic maps. Following those needs, we introduce the representation methods of the earthquake emergency maps according to their formats(vector or raster)and contents, such as point symbolization method, kilometer grid method, line symbolization method and range method. Then, we study the rapid plotting method of earthquake emergency map based on map template matching method. The core steps of the method include: 1)before earthquake, the templates of different earthquake emergency maps are designed, prepared and connect the earthquake emergency features with their related spatial database. The map layout and map elements are stored in the templates. 2)After earthquake, the earthquake emergency features will be generated from seismic models(such as attenuation model of earthquake magnitude and seismic intensity)or the information obtained from field investigation. 3)Corresponding earthquake emergency map template is selected in accordance with the generated seismic features. And the features are used to update related features inside the selected template. 4)Minor adjustments are made such as to the map scale and some map annotations to finally generate the formal earthquake emergency map. Architecture of template system of the earthquake emergency maps is designed, including map user level, map template level, template layer level and map element level. Regrading to the architecture, the general map template of earthquake emergency is presented which includes four main regions: title region, main picture region, auxiliary region and annotation region. The main picture region is the essential, which lays geographic background maps and earthquake emergency features. Finally, an earthquake emergency mapping system is developed. Based on the system, a case study is presented, which demonstrates making a simulated seismic intensity influence map. From three aspects, the case presents the application of the template-matching method including: generating earthquake emergency features, substituting the features inside the template with the generated features, and revising map annotations. Therefore, the map template matching method is verified so that it can be used to quickly generate various earthquake emergency maps. 相似文献