基于激光散射的高速微粒测速系统

高速微粒速度测量技术是空间高速粒子地基模拟系统中的一项关键技术。设计并实现了一种利用激光光幕对高速运动微粒的非接触式速度测量系统,分析了测量误差以及进一步提高测量精度的方法。该系统以高功率半导体激光器作为光源,同时采用PIN光电二极管作为光电探测器,利用接收侧向散射光脉冲作为起始和结束信号以测量微粒的平均速度。实验结果表明,该系统可对速度范围为1~10 km/s,直径大于100μm的高速微粒进行测速,精度优于1.8%。     

基于BLF时钟的RFID低功耗数字基带设计

提出了一种符合ISO/IEC 18000-6C协议中关于时序规定的射频识别(RFID)无源标签芯片低功耗数字基带处理器的设计.基于采用模拟前端反向散射链路频率(BLF)时钟的方案,将BLF的二倍频设置为基带中的全局时钟,构建BLF和基带数据处理速率之间的联系;同时在设计中采用门控时钟和行波计数器代替传统计数器等低功耗策略.芯片经TSMC 0.18 μmCMOS混合信号工艺流片,实测结果表明,采用该设计的标签最远识别距离为7 m,数字基带动态功耗明显降低,且更加符合RFID协议的要求.     

VDL4:一种新型航空VHF数据链

甚高频(VHF)数据链在当今航空通信中具有十分重要的作用。目前航空数据链各异,并各具优势。文中主要论述VDL4,首先介绍了其基本设备结构,说明了协议的层次模型,然后分析了VDL4的时隙选择、网络接入、信道管理等关键技术,最后将它和其余VDL模式数据链进行了比较,从而说明VDL4是一种能满足新航行系统需求、极具竞争力的航空数据链。     

Dreamweaver UltraDev环境下实现数据库的动态链接

简要论述了如何在Dreamweaver UltraDev环境下实现对已有的Access或Excel数据库的动态链接的操作。在Dreamweaver UltraDev环境下，实现对企业、事业单位原有Access或Excel数据库的动态链接，可以在很短的时间内开发出符合单位实际情况的信息管理系统，并且可以使这类已经创建好的数据信息，不加任何修改地与外部进行交流，实现资源共享。将此系统以主页的形式链入Internet，可以实现开放式管理体系。     

cdma2000标准中链路接入控制层的研究与实现

首先介绍了cdma2000标准的协议分层结构;然后针对链路接入控制层,研究了数据单元处理流程和基于IS-95A标准的改进;最后结合协议规定给出了cdma2000移动台信令实验系统中链路接入控制层的软件实现方法和结果。     

WPAN/WLAN应用环境下基于PER的链路自适应算法

本文重点研究基于包错误率测量的链路自适应算法，分析了包错误率与信道参数的关系，提出了一种有别于固定门限值方案的优化门限值方案。仿真结果表明，优化门限值方案的网络吞吐量要大于固定门限值方案和基于信干比估计的链路自适应算法，最大增幅可达12Mbit/s。在系统引入重传机制后，网络吞吐量将有所损失，但最大不超过1Mbit/s，相比较服务质量的提高是值得的。需指出的是，虽然分析和仿真均以HIPERLAN／2为例，但不失一般性，它们同样适合于WPAN/WLAN等类似系统。     

星间激光通信技术进展与趋势

较详细地评述了目前国外卫星间光通信技术研究的现状．根据关键单元技术的进展情况，总结了未来星间光通信系统的发展趋势。     

一种VDSL上行链路自适应功率回馈方案

上行链路功率回馈技术(UPBO：upstream power back-off)是VDSL(very high-speed digital subscriber lines)系统中的关键技术，它用于抵消同一电缆中短线对长线引起的严重的远端串扰(FEXT:far-end crosstalk)。文中从功率控制的角度分析了基于迭代注水的自适应UPBO方案，并进行了性能仿真分析。     

卫星系统新技术--应用机遇及发展策略考虑(上)

结合市场导向下的技术驱动重要性，重点论述现代卫星系统新技术及其在中国的应用机遇和发展策略。     

Uplink Scheduling in CDMA Packet-Data Systems

Uplink scheduling in wireless systems is gaining importance due to arising uplink intensive data services (ftp, image uploads etc.), which could be hampered by the currently in-built asymmetry in favor of the downlink. In this work, we propose and study algorithms for efficient uplink packet-data scheduling in a CDMA cell. The algorithms attempt to maximize system throughput under transmit power limitations on the mobiles assuming instantaneous knowledge of user queues and channels. However no channel statistics or traffic characterization is necessary. Apart from increasing throughput, the algorithms also improve fairness of service among users, hence reducing chances of buffer overflows for poorly located users. The major observation arising from our analysis is that it is advantageous on the uplink to schedule “strong” users one-at-a-time, and “weak” users in larger groups. This contrasts with the downlink where one-at-a-time transmission for all users has shown to be the preferred mode in much previous work. Based on the optimal schedules, we propose less complex and more practical approximate methods, both of which offer significant performance improvement compared to one-at-a-time transmission, and the widely acclaimed Proportional Fair (PF) algorithm, in simulations. When queue content cannot be fed back, we propose a simple modification of PF, Uplink PF (UPF), that offers similar improvement. Hereafter, we refer to users with low recieved power at the base even when transmitting at peak transmit power as “weak” users, and the strongly recieved users at the base as “strong” users. Krishnan Kumaran is currently a member of the Complex Systems Modeling section in the Corporate Strategic Research of ExxonMobil Corp., Clinton, NJ. Formerly, he was a Member of Technical Staff in the Mathematics of Networks and Systems Research Department at Bell Labs in Murray Hill, NJ, where his research interests were in modeling, analysis and simulation of design, resource management and scheduling issues in telecommunication networks. Lijun Qian is an assistant professor in the Department of Electrical Engineering at Prairie View A&M University. He received his B.S. from Tsinghua University in Beijing, M.S. from Technion-Israel Institute of Technology, and Ph.D. from WINLAB, Rutgers University, all in electrical engineering. Before joining PVAMU, he was a researcher at Networks and Systems Research Department of Bell Labs in Murray Hill, NJ. His major research interests are in wireless communications and networking technologies, especially in radio resource management, protocol design, TCP/RLP optimization and MPLS traffic engineering.