我国通用航空应急管理体系构建

低空空域开放是助力我国通用航空迅速发展的重大战略性举措,同时将对通用航空在作业过程中的应急管理带来挑战。文章给出通用航空突发事件的定义,对引起通用航空突发事件的致灾因素从通用航空器、通用航空作业环境、通用航空服务保障情况做一分析。阐述了通用航空应急管理的定义。最后提出了基于应急管理平台的通用航空应急管理体系。     

卫星测控应用中心远程容灾系统方案设计

随着航天技术的发展,各种卫星如综合侦察卫星、气象与海洋监视卫星、数据与中继卫星等,其数据的信息速率存储、处理的数据量越来越大,对卫星测控应用中心大容量、高速率数据的安全性、可靠性要求也越来越高。在自然灾害,如地震、洪水;人为破坏,如恐怖活动、战争等条件下,确保卫星测控应用中心的安全与快速恢复能力,将非常重要。本文从原理上设计了一套远程数据容灾系统方案,以保证卫星测控应用中心在自然灾害或人为破坏后能够快速恢复其基本功能。分析表明,该方案具有很好的可靠性、安全性。     

造成去年关中洪灾的原因及法律索赔探析

2003年关中渭河洪灾,不是纯天灾,而是“人祸与天灾混合体”。“人祸”即三门峡某水电企业拒绝各方长期劝告,坚持高水位发电,酿成陕西56万灾民和20多亿元损失。在酝酿处理善后的思路上,并没有涉及该企业对陕西公私受灾者依法进行部分赔偿的问题,本文从法律角度进行了深入剖析,提出了应给灾民以合理合法的赔偿。     

Economic effect of satellite communications based on the Great East Japan Earthquake

On 11 March 2011, an undersea earthquake of magnitude 9.0, the largest ever recorded in Japan, occurred off the Oshika Peninsula on the Pacific coast of the Tohoku region. The hypocentral region extended for 500 km in the north–south direction from Iwate Prefecture to Ibaraki Prefecture, and for 200 km in east–west direction. The earthquake generated a tsunami with a height of more than 10 m and a run-up height of up to 40.0 m in certain places, which inflicted devastating damage on the coastal areas of the Tohoku and Kanto regions. In addition to the tsunami, the earthquake caused shaking, liquefaction, subsidence, and the collapse of dams, causing major damage to vast areas in the Tohoku and Kanto regions and disrupting various types of infrastructure, including communication. In light of this unprecedented damage, satellite communications were important from various perspectives while terrestrial communications systems were damaged, and an objective evaluation of the role played by satellite communications is relevant to its future installation, adoption and use as a standalone or backup system. Furthermore, satellite communications can help reduce the extent of damage, particularly damage to communications systems, inflicted by strong earthquakes in the future. Accordingly, we report a preliminary quantitative evaluation of the role of satellite communications in the Great East Japan Earthquake, of the role of satellite communications if it becomes widespread, and of its expected role in future large-scale earthquakes in terms of the economic effect converted into cost.     

航天任务控制中心容灾模式研究

航天任务是一项高投入、高风险的活动,作为管理所有在轨飞行航天器及资源的航天任务控制中心,要求具备很高的可靠性与较强的容灾能力。国际航天大国对地面系统,特别是任务中心级的备份均非常重视,也开展了相关建设和系统运行。在对我国航天任务控制中心容灾模式进行探讨的基础上,提出容灾中心的技术要素、需求分析以及运行机制。     

Capacity building in emerging space nations: Experiences,challenges and benefits

This paper focuses on ways in which space is being used to build capacity in science and technology in order to:     

The mitigation, management, and survivability of asteroid/comet impact with Earth

The chances that Earth will collide with a significant near earth object (NEO) within the next century are very small, but such a collision is possible, would be catastrophic, and could happen at any time. Much discussion has been devoted to methods of diverting these objects away from Earth through the use of space technology. However, if these efforts are unsuccessful, we would need to implement effective strategies to survive the event, no matter how cataclysmic. To date, disaster management for various impact scenarios has not been addressed (except in novels and Hollywood films). An impact disaster may be many orders of magnitude greater than any disaster the human species has ever experienced. Initially, technology and experience gained in other large-scale disasters will most likely form the foundation of how these impact events will be managed and classified. Given the size and energy of the projectile, the estimated area of damage, and whether impact effects might be localized or global in nature, we can begin to build basic disaster response scenarios, anticipate public health concerns, and formulate questions in need of answers. Questions we must deal with include: what will be required technologically, sociologically, and medically to survive? What types of evacuation plans and warning systems might be required? Capabilities in need of further investigation include: technological protection strategies related to ‘impact winter’, expanded chemical hazard control methodologies, food storage and production, roles of national governments, and international cooperation. Whatever the magnitude and severity of the event, we must reflect on what we know, what capabilities we can apply, develop or adapt, and seriously investigate what might be done to manage it and survive.     

FY-2C星用户利用站分系统

介绍了风云二号(FY-2)气象卫星地面应用系统中用户利用站(USS)的构成和特点.给出了其中规模用户利用站(MDUS)、低速率用户利用站(LRUS)和数据收集平台(DCP)的配置、特点、主要功能及部分硬件的技术指标.     

Operation and Application of A, B Satellites for Environment and Disaster Monitoring and Forecasting

Environment and disaster monitoring and forecasting small satellite constellation A and B satellites (HJ-1-A, B) are called "environment and disaster reduction satellites A and B' for short. The constellation adopts a 10:30 LT sun-synchronous circular orbit, with orbit altitude of 649 km. HJ-1-A and HJ-1-B are distributed with a phase difference of 180o in the same orbital plane, so as to enhance the time resolution of earth observation. The satellites have orbit maintenance capability, the lifetime is 3 years. Both satellites adopt CAST968 platforms. Two wide-coverage multispectral CCD cameras with resolution 30 m and width 700 km, a super-spectral imager with resolution 100 m and width 50 km as well as a data transmission subsystem of 120 Mbit/s are deployed on HJ-1-A, which also carries Ka communication testing equipment of Thailand. HJ-1-B has two wide-coverage multispectral CCD cameras (the same as satellite A), one infrared camera with resolution 150 m and width 720 km and a data transmission subsystem of 60 Mbit/s. The coverage period of the wide-coverage multispectral CCD camera is 48 hours. The revisit period of super-spectral imager is 96 hours and the coverage period of infrared camera is 96 hours.      

探测地球自然灾害的一种方法

通过探测地球整体的辐射温度变化,即在空间把地球作为一个辐射点源对待,同时又将地球分成几百个局部,视为一个面源,进行实时的比较;又分别对太阳和宇宙背景的辐射温度变化进行测量,来了解地球表面和地气的热温度状况和太阳对地球、对宇宙背景能量传输的情况。从而研究地球上大规模灾害性事件(包括火山的爆发、地震、大气环流、气候变异等…)在整个地球上所能反映的热温度效应。探测地球在宇宙空间非平衡热状况下(太阳温度6000K;地球温度300K;空间背景3K)的耗散结构,研究在这种状况下物理力学的一些自会聚和自组织现象(即地球上灾害性事件形成过程),形成一门非平衡宇宙热力学,并使之成为一门实验科学。文章着重介绍为此目的实施的探测方法和其应用前景。