一种基于太赫兹成像的复杂地形自适应定高方法

针对现有近感探测器难以适应复杂地形情况下的精确定高问题,提出一种基于成像的图像域自适应对地高度估计方法。该方法将多普勒锐化成像原理应用到前下视场景,利用太赫兹频段分辨力高、孔径合成长度短的优势,采用太赫兹前下视成像实现地形感知,将传统近感探测器的一维距离测量扩展为二维成像测量,实现对运动轨迹前下方地形地貌的精确感知。在获得地面目标图像后,利用地面图像特征,采用图像域特征拟合方法实现对地高度估计。对前下视多普勒锐化成像的参数设计和成像算法进行了理论分析和仿真验证,开发了一套工作于220 GHz频段的太赫兹近感探测系统,并开展了无人机挂载试验。试验表明,该方法能有效感知地表目标环境,排除角反、树木等其他目标对地面高度测量的干扰,测高精确度达0.5 m,证明了该基于太赫兹成像的对地高度估计方法的可行性,为基于图像域特征提升近感探测器对复杂地形适应能力和感知能力奠定了工作基础。     

城市对流层气溶胶观测分析与研究

利用激光雷达测量数据反演出了北京测站和西藏那曲测站上空对流层大气气溶胶散射比和消光系数的垂直分布,利用消光系数和风速数据,进行了相关分析。结果表明,北京测站上空气溶胶的组分、浓度、粒径和分布较那曲呈现更大的不均匀性;西藏那曲地区的空气质量较北京城区要高;那曲测站上空的贴地层高度较北京城区低;北京测站近地面气溶胶消光系数和风速的负相关特性较为明显。     

北京航天计量测试技术研究所EI北大核心CSCD

激光雷达扫描仪激光雷达扫描仪是一种非接触、高精度、自动化、便携式测量设备,数字成像,3D激光扫描及模型比对与处理功能都集成到了本设备中。激光雷达扫描仪可以解决大型零部件的轮廓扫描、目标匹配、姿态测量等检测、逆向工程问题,以及空地扫描成像测量,也可广泛应用于地面大型项目工程的扫描测量,如地面资源环境专题制图、考古建模、地形勘察、道路规划、及城市建筑物三维地形建模等方面。     

红外望远镜站址大气传输和环境背景特性的测量分析研究

大口径的地基红外望远镜必须安装在具有良好大气条件的观测台站才能充分发挥其性能,天空背景辐射和大气传输特性是地基红外望远镜站址选择所需考虑的重要内容。采用消光-小角度散射法在西藏羊八井实测了太阳直接红外辐射和大气背景红外辐射,并根据备选站点的大气参数,采用CART软件计算了当地8~14 m波段整层垂直大气的光谱透过率、太阳直接光谱辐射和地面大气垂直向下的背景光谱辐射,以及相关量的波段积分值,这些结果有助于地基红外太阳望远镜的站址选择。     

实时地形渲染的细节增强算法研究

浏览多分辨率细节层次地形,当视点距离地面非常近,达到最高分辨率时,地形无法继续细化,影响浏览的连续性和视觉效果。针对这一问题,文中在应用Chunked LOD算法构建地形的基础上,以规则格网为处理单元,结合并改进了Kobbelt细分算法和分形技术,提出了实时细节增强的改进方案。该方案可以实时地添加富有真实感的高分辨率网格,避免了因过多细节增强引起的计算负荷。根据这一改进所做的实验结果表明,该方法在保持帧速连续的基础上,能实时有效地增加细节,满足逼真视效的需求。     

垂直入射大地回波特性测量方法与实验

针对垂直入射区雷达大地回波的特性,利用S波段和8 mm波段线性调频连续波雷达散射计,开展了农田和沙地2种地形的回波测量实验,获取了2种地形在S波段和8mm波段的垂直入射区回波数据,给出了地面反射系数和散射系数的计算方法,并利用该方法由测量回波数据得出了2种地形在S波段和8 mm波段的反射和散射系数.该结果为雷达高度表和微波遥感等系统提供了设计依据.     

激光雷达的透过率迭代法定标研究

通过激光雷达对近地面层大气进行水平探测，结合近地面层气溶胶粒子谱分布及折射率测量，本文导出了激光雷达的透过率迭代定标新方法，此方法简便，易行，结果令人满意。     

汶川地震前羊八井中子-μ子望远镜计数率异常

利用在西藏羊八井新建中子-μ子望远镜的观测数据,研究分析了在2008年5月12日四川汶川8.0地震期间宇宙线高能粒子偏离正常背景的异常变化。中子-μ子望远镜的中子监测器经过消除背景场和气压修正后震前5天特别是5月9日出现计数率降低异常。在地震发生前5天左右,μ子望远镜各方向计数率出现日变化异常。这些宇宙线异常现象,与其它观测资料,例如地磁低点位移、电离层总电子含量TEC、电离层测高仪得到的foF2和电磁卫星监测的离子密度和温度等,在时空分布上有较好的一致性。这是继羊八井中子监测器观测到震前宇宙线异常现象后,利用另一种宇宙线观测手段观测到的震前宇宙线异常现象。     

直接地理编码与星载干涉SAR测高不确定度的等效性分析

现有的考虑地球曲率影响的INSAR测高模型主要有星载干涉SAR测高模型和直接地理编码两种。星载干涉SAR测高模型首先利用SAR干涉获取非模糊干涉相位,然后根据考虑地球曲率的空间几何关系直接计算地形高度。而直接地理编码模型则是在SAR干涉获取非模糊干涉相位的基础上,利用两个斜距方程和一个多普勒方程给出地面点的3维坐标值。由于两种模型得到地形高程的途径不同,因此很难直接比较这两种模型的地形测高不确定度。该文在采用矩阵形式推导出直接地理编码模型地形高程不确定度显示表达式的基础上,通过引入斜距平面坐标系,定量化地证明了直接地理编码模型的高程测量不确定度公式与考虑地球曲率的SAR干涉测高模型的测高不确定度公式是相同的,从而说明了这两种模型在用于地形高程测量时具有相同的精度。最后采用计算机仿真验证了理论分析的正确性。     

雷达测高计完成样机试验

GEC传感器有限公司为隐蔽作战研制出一种雷达测高计,除测量地面的高度外,还能测量距离最近的障碍物上方的高度。在隐蔽作战中,雷达测高计对安全飞行十分重要,那时,飞机可能不用其更有探测能力的地形防撞和地形跟随雷达进行工作。然而,即使是标准雷达测高计的低功率透射率,也能增大飞机的可探测性。     

Alternative Schemes for Dynamic Secure VPN Deployment in UMTS

Three alternative schemes for secure Virtual Private Network (VPN) deployment over the Universal Mobile Telecommunication System (UMTS) are proposed and analyzed. The proposed schemes enable a mobile node to voluntarily establish an IPsec-based secure channel to a private network. The alternative schemes differ in the location where the IPsec functionality is placed within the UMTS network architecture (mobile node, access network, and UMTS network border), depending on the employed security model, and whether data in transit are ever in clear-text, or available to be tapped by outsiders. The provided levels of privacy in the deployed VPN schemes, as well as the employed authentication models are examined. An analysis in terms of cost, complexity, and performance overhead that each method imposes to the underlying network architecture, as well as to the mobile devices is presented. The level of system reliability and scalability in granting security services is presented. The VPN management, usability, and trusted relations, as well as their behavior when a mobile user moves are analyzed. The use of special applications that require access to encapsulated data traffic is explored. Finally, an overall comparison of the proposed schemes from the security and operation point of view summarizes their relative performance. Christos Xenakis received his B.Sc. degree in computer science in 1993 and his M.Sc. degree in telecommunication and computer networks in 1996, both from the Department of Informatics and Telecommunications, University of Athens, Greece. In 2004 he received his Ph.D. from the University of Athens (Department of Informatics and Telecommunications). From 1998–2000 was with the Greek telecoms system development firm Teletel S.A., where was involved in the design and development of advanced telecommunications subsystems for ISDN, ATM, GSM, and GPRS. Since 1996 he has been a member of the Communication Networks Laboratory of the University of Athens. He has participated in numerous projects realized in the context of EU Programs (ACTS, ESPRIT, IST). His research interests are in the field of mobile/wireless networks, security and distributed network management. He is the author of over 15 papers in the above areas. Lazaros Merakos received the Diploma in electrical and mechanical engineering from the National Technical University of Athens, Greece, in 1978, and the M.S. and Ph.D. degrees in electrical engineering from the State University of New York, Buffalo, in 1981 and 1984, respectively. From 1983 to 1986, he was on the faculty of Electrical Engineering and Computer Science at the University of Connecticut, Storrs. From 1986 to 1994 he was on the faculty of the Electrical and Computer Engineering Department at Northeastern University, Boston, MA. During the period 1993–1994 he served as Director of the Communications and Digital Processing Research Center at Northeastern University. During the summers of 1990 and 1991, he was a Visiting Scientist at the IBM T. J. Watson Research Center, Yorktown Heights, NY. In 1994, he joined the faculty of the University of Athens, Athens, Greece, where he is presently a Professor in the Department of Informatics and Telecommunications, and Director of the Communication Networks Laboratory (UoA-CNL) and the Networks Operations and Management Center. His research interests are in the design and performance analysis of broadband networks, and wireless/mobile communication systems and services. He has authored more than 150 papers in the above areas. Since 1995, he is leading the research activities of UoA-CNL in the area of mobile communications, in the framework of the Advanced Communication Technologies & Services (ACTS) and Information Society Technologies (IST) programmes funded by the European Union (projects RAINBOW, Magic WAND, WINE, MOBIVAS, POLOS, ANWIRE). He is chairman of the board of the Greek Universities Network, the Greek Schools Network, and member of the board of the Greek Research Network. In 1994, he received the Guanella Award for the Best Paper presented at the International Zurich Seminar on Mobile Communications.     

SOI Technologies Overview for Low-Power Low-Voltage Radio-Frequency Applications

Thanks to their structure, the SOI technologies present several intrinsic advantages for analog and RF applications. Indeed, as it is well established now, these technologies allow the reduction of the power consumption at a given operating frequency. Moreover, the high-insulating properties of SOI substrates, in particular when high resistivity substrate is used, make that these technologies are perfect candidates for mixed-signal applications. In the present paper, we will discuss the performances of the SOI technologies in radio-frequency range. First of all, the high-frequency behavior of SOI substrates, thanks to the characterization of transmission lines, will be shown. The impact of the SOI substrate resistivity on the performances of passive components will also be analyzed. Then, an overview of RF performances of SOI MOSFETs for two different architectures, fully- and partially-depleted, will be achieved and compared to the bulk ones. Finally, the influence of some specific parasitic effects, such as the kink effect, the self-heating effect and the kink-related excess noise, on the RF performances of SOI devices will be studied, thanks to a specific high-frequency characterization.     

HiBRID-SoC: A Multi-Core SoC Architecture for Multimedia Signal Processing

The HiBRID-SoC multi-core system-on-chip architecture targets a wide range of multimedia applications with particularly high processing demands, including general signal processing applications, video de-/encoding, image processing, or a combination of these tasks. For this purpose, the HiBRID-SoC integrates three fully programmable processors cores and various interfaces onto a single chip, all tied to a 64-Bit AMBA AHB bus. The processor cores are individually optimized to the particular computational characteristics of different application fields, complementing each other to deliver high performance levels with high flexibility at reduced system cost. The HiBRID-SoC is fabricated in a 0.18 μm 6LM standard-cell CMOS technology, occupies about 81 mm², and operates at 145 MHz. An MPEG-4 Advanced Simple Profile decoder in full D1 resolution requires about 120 MHz for real-time operation on the HiBRID-SoC, utilizing only two of the three cores. Together with the third core, a custom region-of-interest (ROI) based surveillance application can be built.Hans-Joachim Stolberg received the Dipl.-Ing. degree in electrical engineering from the University of Hannover, Germany, in 1995.From 1995 to 1996, he was with the NEC Information Technology Research Laboratories, Kawasaki, Japan, working on efficient implementations of video compression algorithms. Since 1996, he has been with the Institute of Microelectronic Systems at the University of Hannover as a Research Assistant. During summer 2001, he was a Monbukagakusho Research Fellow at the Tokyo Institute of Technology, Japan. His current research interests include VLSI architectures for video signal processing, performance estimation of multimedia schemes, and profile-guided memory organization for signal processing and multimedia applications.Mladen Bereković received the Dipl.-Ing. degree in electrical engineering from the University of Hannover, Germany, in 1995.Since then he has been a Research Assistant with the Institute of Microelectronic Systems of the University of Hannover. His current research interests include VLSI architectures for video signal processing, MPEG-4, System-on-Chip (SOC) designs, and simultaneously multi-threaded (SMT) processor architectures.Sören Moch received the Dipl.-Ing. degree in electrical engineering from the University of Hannover, Germany, in 1997.Since then he has been Research Assistant with the Laboratory for Information Technology, University of Hannover. His current research interests are in the area of processor architectures for image, video and multimedia signal processing applications.Lars Friebe studied electrical engineering at the Universities Ulm and Hannover, Germany. In 1999, he worked at the NEC System ULSI Research Laboratory in Kanagawa, Japan. He received the Dipl.-Ing. degree in electrical engineering from the University of Hannover, Germany, in 1999.Since then he has been a Research Assistant with the Laboratory for Information Technology, University of Hannover. His current research interests are in the area of parallel programmable VLSI architectures for real-time image processing.Mark B. Kulaczewski started his studies in electrical engineering at the University of Hannover, Germany. In 1994, he transferred to Purdue University, West Lafayette, USA, and received the M.S. degree in electrical engineering in 1996.Since 1997 he has been a Research Assistant at the Laboratory for Information Technology and the Institute of Microelectronic Systems, University of Hannover. His current research interests include programmable real-time architectures for video coding and image segmentation, and instruction-set extensions for cryptographic applications.Sebastian Flügel was born in Crivitz, Germany, in 1975. He received his Dipl.-Ing. degree from the Department of Electrical Engineering of the University of Rostock in 2001.Since then he has been a Ph.D. candidate at the Institute of Microelectronic Systems at the University of Hannover. He works in the field of architectures and systems for video processing systems. His focus is on algorithms for video encoding and the development of optimized hardware architectures.Heiko Klußmann received the Dipl.-Ing. degree in computer engineering from the University of Hannover, Germany, in 2002.Since then he has been a Research Assistant with the Institute of Microelectronic Systems of the University of Hannover. His current research interests are in the area of programmable architectures for real-time video signal processing.Andreas Dehnhardt was born in Frankfurt am Main, Germany, in 1976. He received his Dipl.-Ing. degree in electrical engineering from the University of Hannover, Germany, in 2002.Since then, he has been a Research Assistant with the Institute of Microelectronic Systems, University of Hannover. His current research interests include programmable architectures for multimedia applications and implementation of real-time MPEG-4 encoding schemes.Peter Pirsch received the Ing. grad. degree from the engineering college in Hannover, Hannover, Germany, in 1966, and the Dipl.-Ing. and Dr.-Ing. degrees from the University of Hannover, in 1973 and 1979, respectively, all in electrical engineering.From 1966 to 1973 he was employed by Telefunken, Hannover, working in the Television Department. He became a Research Assistant at the Department of Electrical Engineering, University of Hannover, in 1973, a Senior Engineer in 1978. During 1979 to 1980 and in Summer 1981 he was on leave, working in the Visual Communications Research Department, Bell Laboratories, Holmdel, NJ. During 1983 to 1986 he was Department Head for Digital Signal Processing at the SEL research center, Stuttgart. Since 1987 he is Professor in the Department of Electrical Engineering, since 2002 in the Department of Computer Science at the University of Hannover. He served as Vice President Research of the University of Hannover from 1998 to 2002. His present research includes architectures and VLSI implementations for image processing applications, rapid prototyping and design automation for DSP applications. He is the author or coauthor of more than 200 technical papers. He has edited a book on VLSI Implementations for Image Communications (Elsevier 1993) and is author of the book Architectures for Digital Signal Processing (John Wiley 1998).Pirsch is a member of the IEEE, the German Institute of Information Technology Engineers (ITG) and the German Association of Engineers (VDI). He was recipient of several awards: the NTG paper price award (1982), IEEE Fellow (1997), IEEE Circuits and Systems Golden Jubilee Medal (1999). He was member or chair of several technical program committees of international conferences and organizer of special sessions and preconference courses. He has held several administrative and technical positions with the IEEE Circuits and Systems Society and other professional organizations. Dr. Pirsch currently serves as Vice President Publications of the IEEE Circuits and Systems Society. Since 2000 he is chairman of the Accreditation Commission for Engineering and Informatics of the Accreditation Agency for Study Programs in Engineering, Informatics, Natural Science and Mathematics (ASIIN). Dr. Pirsch is chair of the VDI committee on Engineering Education.     

自动测试系统中的总线技术

自动测试系统满足现代科研生产中对测试高速度和高精度的要求,其发展方向是标准化、模块化和系列化,而标准的总线技术是满足这三化的关键技术,总线技术作为自动测试系统的核心,其发展推动了自动测试系统的更新换代.按照自动测试系统中出现的总线技术的顺序,依次对GPIB,VXI,PXI,LXI的基本特性、优缺点及应用进行概括,重点是结合在实际中组建自动测试系统对总线的选型,从宏观上比较了选取传统的卡式仪器总线或基于以太网的新型总线的因素.从而使用户在选取总线时更有针对性和目的性.     

企业VPN技术应用实施浅析

随着企业规模逐渐扩大,远程用户、分支机构、合作伙伴也在不断增多,关键业务的需求增加,出现了一种通过公共网络（如Internet）来建立自己的专用网络的技术,这种技术就是虚拟专用网（简称VPN）。本文首先介绍了VPN的概念,对VPN的实现技术进行了分类和适用性分析,然后分析了各种类型的企业在信息安全方面的需求和限制,根据不同企业的特点提出了不同的VPN解决方案,最后,对VPN在集成电路企业中的应用做了简单的拓朴展示。     

A Fault-Tolerant Scheme for Mobility Management in PCS Networks

One of the most important and challenging issues in the design of personal communication service (PCS) systems is the management of location information. In this paper, we propose a new fault-tolerant location management scheme, which is based on the cellular quorum system. Due to quorum's salient set property, our scheme can tolerate the failures of one or more location server(s) without adding or changing the hardware of the systems in the two-tier networks. Meanwhile, with a region-based approach, our scheme stores/retrieves the MH location information in the location servers of a quorum set of the local region as much as possible to avoid long delays caused by the possible long-distance of VLR and HLR. Thus, it yields better connection establishment and update delay. Ming-Jeng Yang received the M.S. degree in computer science from the Syracuse University, New York, in 1991, and the Ph.D. degree in computer science from National Taiwan Normal University, Taiwan, in 2004. He is an associate professor in the Department of Information Technology, Takming College, Taiwan. His research interests include wireless networks, mobile computing, fault-tolerant computing, and distributed computing. He is a member of the IEEE Computer Society and the ACM. Yao-Ming Yeh received the B.S. degree in computer engineering from National Chiao-Tung University, Taiwan, in 1981, and the M.S. degree in computer science and information engineering from National Taiwan University, Taiwan, in 1983. In August 1991, he received the Ph.D. degree in the Department of Electrical and Computer Engineering, The Pennsylvania State University, Pa., U.S.A. He is a professor in the Department of Information and Computer Education, National Taiwan Normal University, Taiwan. His research interests include fault-tolerant computing, web and XML computing, and distributed computing.     

Optimization of lithographic masks using genetic algorithms

Due to its cost effectiveness and reliability, wet-chemical etching of silicon is still one of the key technologies for producing bulk-silicon microstructures. In this paper we present an approach for the design of advanced mask sets for anisotropic, wet-chemical etching of silicon. The optimization method of genetic algorithms is used to derive suitable masks for cases where geometrically calculated compensation structures fail. The underlying etch simulation is described as well as the optimization algorithm itself. Design tasks of current research projects are used as examples to illustrate the advantage of using the presented tool. Udo Triltsch was born in Bergisch Gladbach, Germany, in 1976. He received the Dipl.-Ing. degree for Mechanical Engineering from the Technical University of Braunschweig, Germany, in 2002. He is currently working towards his Ph.D. at the Institute for Microtechnology, Braunschweig, Germany. His research interests include: design methodology for MEMS, process simulation and knowledge management. Anurak Phataralaoha was born in Bangkok, Thailand, in 1973. He received the B. Eng. degree for Production Engineering from KMUTT, Thailand in 1995 and Dipl.-Ing. degree for Mechanical Engineering from Technical University of Clausthal, Germany in 2002. He is currently working towards his Ph.D. at the Institute for Microtechnology, Braunschweig, Germany. His research interests include: 3D-tactile sensors, micro machining for silicon, Tribological micro guide. Stephanus Büttgenbach obtained the Diploma and Ph.D. degrees in physics from the University of Bonn, Germany, in 1970 and 1973, respectively. From 1974 to 1985, he was with the Institute of Applied Physics of the University of Bonn, working on atomic and laser spectroscopy. In 1983, he was promoted to Professor of Physics. From 1977 to 1985, he was also a Scientific Associate at CERN in Geneva, Switzerland. In 1985, Dr. Büttgenbach joined the Hahn-Schickard-Society of Applied Research at Stuttgart as Head of the Department of Microtechnology, where he worked on micromechanics, laser microfabrication, and resonant sensors. From 1988 to 1991, he was the Founding Director of the Institute of Micro and Information Technology of the Hahn-Schickard-Society. In 1991, Dr. Büttgenbach became Professor of Microtechnology at the Technical University of Braunschweig. His current research centers on the development and application of micro sensors, micro actuators, and micro systems. Currently, he is Vice President of the Technical University of Braunschweig, where his areas of responsibility are research and technology transfer. Dima Straube was born in Berlin, Germany, in 1977. He received the Dipl.-Ing. degree for Civil Engineering from Technical University of Berlin, Germany, in 2002. He is currently working towards his Ph.D. at the Institute for Engineering Design, Braunschweig. His research interests include: design methodology for MEMS, computer aided design and tolerance management. Hans-Joachim Franke was born in Helmstedt, Germany, on February 14, 1944. He received his diploma in mechanical engineering (Dipl.-Ing.) from the Technical University of Braunschweig, Germany, in 1969. From 1969 to 1976 he was research assistant of Prof. Roth at the Institute for Engineering Design. In 1976 he received his Ph.D. degree in mechanical engineering. From 1976 to 1988 he had diverse executive positions at the KSB-AG in Frankenthal, Germany, a company, which produces pumps and valves. Since 1988 he has been the director of the Institute for Engineering Design of the Technical University of Braunschweig. His research interests are in the areas of design methodology, computer aided design and machine elements.     

接入控制器安全网络管理系统的设计与实现

在讨论了接入控制器(AC)网络管理系统安全重要性的基础上,分析了SNMP协议的应用,包括对其3个版本SNMPv1、SNMPv2及SNMPv3的优缺点的对比,并解释了该设备网络管理系统采用SNMPv3版本的原因.详细介绍了AC所实现的管理信息库的内容,包括RFC1213协议、IEEE 802.1x协议、RMON协议、Web DHCP、EAP_OTP、EAP_MD5、EAP_TLS、EAP_SIM等多种认证协议以及网络管理系统的五大功能.最后阐述了AC安全网络管理系统结构的设计与实现.