台风“菲特”期间T639预报风场在东中国海的有效性检验

海表风场是航海、海洋工程及防灾减灾等都十分关注的海洋要素之一,本文利用来自台湾地区和韩国的风速观测资料,检验了台风"菲特"及一次冷空气过程期间T639风场预报产品在东中国海的有效性。结果表明:(1)台风"菲特"和冷空气期间,预报风速与观测风速在曲线走势上保持了较好的一致性。(2)从相关系数来看,各个观测站的预报风速与观测风速都表现出较为密切的相关性;从偏差来看,预报风速略高于观测风速;从均方根误差和平均绝对误差来看,误差也都在可控范围之内。(3)台风"菲特"期间,T639预报风场对台风眼、台风尾迹等气旋性特征刻画得较为形象,外埔气象站、东吉岛气象站和兰屿气象站受台风影响较为显著,淡水气象站、金门气象站和绿岛气象站受台风的影响则偏弱。T639预报风场对南下的冷空气过程同样有着较好的体现,对风向和风速都有很好的模拟。     

基于观测网的海底动力环境监测系统的设计与实现

海底动力环境监测系统是南海海底观测网试验系统的重要课题。在"十一五"观测网的基础上,对系统的稳定性与可靠性进行改进,设计使用CAN现场总线通信、ARM双冗余备份、Modem声学网关通道、DC/DC并联冗余与备份电池。该系统主要搭载声学多普勒流速剖面仪(ADCP)、国家海洋技术中心温盐深测量仪(CTD)、高精度压力传感器等设备,集成岸基监测与反馈子系统、控制与数据采集子系统、通信与电源管理子系统,实现了对海底边界层速度剖面场、湍流速度、温度、盐度、压力等海洋动力要素的长期实时稳定监测。经过试验测试,该系统稳定可靠,利于传感器扩展集成,为海底观测网提供了可靠的验证观测节点。     

盐湖卤水参数自动观测系统中的传感器

研制了检测盐湖和盐田卤水温度、密度和水位的传惑器,并建立了盐湖高浓度卤水中钾离子含量的直接自动测定方法。为了使传感器在青藏高原盐湖的恶劣环境中长期稳定工作,并防止探头结盐与腐蚀,采取了一系列技术措施。这些传感器用于察尔汗盐湖卤水动态自动观测系统中,取得了满意的效果。     

The Integrated Global Geodetic Observing System (IGGOS) viewed from the perspective of history

Towards the end of the 19th century, geodetic observation techniques allowed it to create geodetic networks of continental size. The insight that big networks can only be set up through international collaboration led to the establishment of an international collaboration called “Central European Arc Measurement”, the predecessor of the International Association of Geodesy (IAG), in 1864. The scope of IAG activities was extended already in the 19th century to include gravity.At the same time, astrometric observations could be made with an accuracy of a few tenths of an arcsecond. The accuracy stayed roughly on this level, till the space age opened the door for milliarcsecond (mas) astrometry. Astrometric observations allowed it at the end of the 19th century to prove the existence of polar motion. The insight that polar motion is almost unpredictable led to the establishment of the International Latitude Service (ILS) in 1899.The IAG and the ILS were the tools (a) to establish and maintain the terrestrial and the celestial reference systems, including the transformation parameters between the two systems, and (b) to determine the Earth's gravity field.Satellite-geodetic techniques and astrometric radio-interferometric techniques revolutionized geodesy in the second half of the 20th century. Satellite Laser Ranging (SLR) and methods based on the interferometric exploitation of microwave signals (stemming from Quasars and/or from satellites) allow it to realize the celestial reference frame with (sub-)mas accuracy, the global terrestrial reference frame with (sub-)cm accuracy, and to monitor the transformation between the systems with a high time resolution and (sub-)mas accuracy. This development led to the replacement of the ILS through the IERS, the International Earth Rotation Service in 1989.In the pre-space era, the Earth's gravity field could “only” be established by terrestrial methods. The determination of the Earth's gravitational field was revolutionized twice in the space era, first by observing geodetic satellites with optical, Laser, and Doppler techniques, secondly by implementing a continuous tracking with spaceborne GPS receivers in connection with satellite gradiometry. The sequence of the satellite gravity missions CHAMP, GRACE, and GOCE allow it to name the first decade of the 21st century the “decade of gravity field determination”.The techniques to establish and monitor the geometric and gravimetric reference frames are about to reach a mature state and will be the prevailing geodetic tools of the following decades. It is our duty to work in the spirit of our forefathers by creating similarly stable organizations within IAG with the declared goal to produce the geometric and gravimetric reference frames (including their time evolution) with the best available techniques and to make accurate and consistent products available to wider Earth sciences community as a basis for meaningful research in global change. IGGOS, the Integrated Global Geodetic Observing System, is IAG's attempt to achieve these goals. It is based on the well-functioning and well-established network of IAG services.     

气候观测系统及其相关的关键问题

地球系统中的大气圈、水圈、冰雪圈、岩石圈和生物圈构成了气候系统, 气候系统中不同圈层之间的相互作用决定了气候的自然变化。由于人类活动的日益加剧, 对气候系统已经产生了显著影响。气候的自然变化和人类活动导致的气候变化对社会经济的发展以及人民生活的影响日益加大, 并涉及到国家安全、环境外交和可持续发展等一系列重大问题。要认识气候变化及其强迫因素、预测未来气候变化, 最基础的工作是建立针对气候目的涉及到气候系统五大圈层的综合气候观测系统, 以获取所需的高质量资料和相关产品, 提供气候系统变化的详细信息。该文回顾了气候观测系统设计在中国的发展以及中国气象科学研究院在组织设计中国气候观测系统中的作用, 并指出了在建立我国气候观测系统中存在的一些需要改进的方面。在对气候观测系统进行分析的基础上, 指出了与建立气候观测系统相关的10个方面的关键问题, 这些问题包括:气候观测系统的科学需求、气候观测系统的代表性、全面性、规范性、对气候预测和预估及模式发展的支撑性、多学科应用性、社会经济性、资料开放共享性以及气候系统资料的同化再分析和历史资料的抢救。     

成都地磁台地磁总强度数字与模拟资料对比

对成都地磁台两年多(2002~2004年)的地磁总强度数字与模拟观资料进行了对比分析,结果表明:由于数字观测资料与模拟观测资料取数的个数不同,两者的曲线变化形态不同。模拟地磁总强度的形态为近直线型,而数字化地磁总强度则有显著的日动态变化。但数字观测资料经过平均处理后产生的日均值与模拟观测日值大致相同。据现有资料,数字化地磁总强度的映震能力优于模拟地磁总强度。     

714C天气雷达冬季测雪的分析与实践

从雪对电磁波的散射和衰减入手，定性分析了714C天气雷达的测雪能力，以2000年冬季测雪实践为例，总结了乌鲜果昌机场714C天气雷达测雪的一般特点。     

自动测氡数据干扰因素浅析

本文对引起氡值变化的干扰因素进行了讨论，分析了盘一井自动测氡资料变化特征及其规律。重点研究了固体潮，气压，室温变化对观测数据的影响。针对氡值出现的夏低冬高的变化，采取了加装等温装置的措施。     

综合气象观测运行监控业务及系统升级设计

通过对综合气象观测运行监控业务及运行监控系统现状的分析,提出了运行监控业务的发展设想,并对运行监控系统升级做了科学的设计。结果指出,运行监控业务将成为装备保障工作的核心中枢,具有监控、指挥、调度、管理功能,应形成设备监控、维修保障、装备供应与评估业务关联互动的业务体系。运行监控系统需突破目前依赖观测资料质量检查为主要手段的技术,建立以设备自身状态信息为主,故障维修业务填报信息和观测资料检查等多元信息相互校验的技术,实现监控、维修保障、装备供应的信息联动。     

海洋观测方法之研究

本文讨论了海洋观测技术的定义,厘清了其与海洋探测技术和海洋监测技术的关系,并在认识海洋观测数据本质的基础上,从技术性、实时性、经济性和适用性等4个方面,来讨论海洋观测方法。本文研究表明,抓着观测数据的本质保障观测数据的质量;观测手段特别是平台技术决定观测技术的实时性;实时性反映海洋观测任务的需要及观测技术的水平;经济性决定观测技术的选用;适用性进一步决定海洋观测技术的最佳形式,甚至衍生出新的观测技术。