G.652光纤长途传输系统的色散补偿

针对当前国内长途传输光缆系统在扩容过程中，因光信号色散而影响传输质量的现象，结合实际工程建设，分析了光信号色散的危害及其成因，并提出了相应的解决办法及建议。     

适用于高速长途DWDM系统的色散管理线路

对于高速长途密集波分复用（DWDM）传输，必需采用各种各样的色散补偿、色散管理技术，其中，交替使用正负色散光纤构成色散管理线路（DML）是可行的解决方案之一，在国际上已经取得显著进展，正成为人们关注的焦点，国内在这方面的研究报道还少见.文章以高速长途DWDM系统对传输线路的性能要求为基础，综述了有代表性的3种不同类型的DML的特点和最新进展。     

Analysis and Optimization of the Energy Efficiency in the 802.11 DCF

This paper introduces an analytical model to investigate the energy efficiency of the IEEE 802.11 distributed coordinated function (DCF). This model not only accounts for the number of contending nodes, the contention window, but also the packet size, and the channel condition. Based on this model, we identify the tradeoff in choosing optimum parameters to optimize the energy efficiency of DCF in the error-prone environment. The effects of contention window and packet size on the energy efficiency are examined and compared for both DCF basic scheme and DCF with four-way handshaking. The maximum energy efficiency can be obtained by combining both the optimal packet size and optimal contention window. To validate our analysis, we have done extensive simulations in ns-2, and simulation results seem to match well with the presented analytical results. The Ohio Board of Regents Doctoral Enhancements Funds and the National Science Foundation under Grant CCR 0113361 have supported this work. Xiaodong Wang received his B.S. degree in communication engineering from Beijing Information Technical Institute of China in 1995, and his M.S. degree in electric engineering from Beijing University of Aeronautics and Astronautics of China in 1998. He joined China Telecom in 1998 where he worked on communication protocols for telecommunication. From June 2000 to July 2002, he worked on GSM base station software development at Bell-labs China, Beijing, China. Currently he is a Ph.D. student in Computer Engineering at University of Cincinnati. His research activities include wireless MAC protocols, energy saving for wireless sensor networks. He is a student member of the IEEE. Jun Yin received the BS degree in automatic control from Dalian Railway Institute of China in 1997, and the MS degree in flight control from Beijing University of Aeronautics and Astronautics of China in 2001. Since 2001 she has been a Ph.D. student in the OBR Research Center for Distributed and Mobile Computing at the University of Cincinnati. Her research interests include performance evaluation of 802.11 MAC protocol, wireless ad hoc networks and sensor networks. She is a student member of the IEEE. Dharma P.Agrawal IEEE Fellow, 1987; ACM Fellow, 1998; AAAS Fellow, 2003 Dr. Agrawal is the Ohio Board of Regents Distinguished Professor of Computer Science and Computer Engineering in the department of Electrical and Computer Engineering and Computer Science, University of Cincinnati, OH. He has been a faculty member at Wayne State University, (1977–1982) and North Carolina State University (1982–1998). He has been a consultant to the General Dynamics Land Systems Division, Battelle, Inc., and the U. S. Army. He has held visiting appointment at AIRMICS, Atlanta, GA, and the AT&T Advanced Communications Laboratory, Whippany, NJ. He has published a number of papers in the areas of Parallel System Architecture, Multi computer Networks, Routing Techniques, Parallelism Detection and Scheduling Techniques, Reliability of Real-Time Distributed Systems, Modeling of C-MOS Circuits, and Computer Arithmetic. His recent research interest includes energy efficient routing, information retrieval, and secured communication in ad hoc and sensor networks, effective handoff handling and multicasting in integrated wireless networks, interference analysis in piconets and routing in scatternet, use of smart directional antennas (multibeam) for enhanced QoS, Scheduling of periodic real-time applications and automatic load balancing in heterogeneous workstation environment. He has four approved patents and three patent filings in the area of wireless cellular networks.     

基于最佳竞争窗口的IEEE802.11DCF接入协议改进及性能分析

针对DCF协议的初始竞争窗口不能随着节点数变化选择其最佳值的不足,提出一个具有两级退避的接入协议(OCW-DCF),并用Markov模型分析了协议性能,确定其最佳竞争窗口值。仿真结果表明,OCW-DCF协议能有效减小信道接入延时,且采用基本接入模式的总体性能比RTS/CTS接入模式的好。     

802.11 DCF协议引入信道预约机制的必要性分析

论文对802.11 DCF协议引入信道预约机制的必要性问题进行了探讨.通过分析信道预约机制与隐藏/暴露终端问题之间的关系,提出一种比较隐藏终端和暴露终端出现概率大小的等效方法,并给出了相应的数值估算结果.理论分析结果验证了802.11 DCF协议引入信道预约机制的有效性.     

DCF法在石化项目估值中的应用

阐述了石化项目价值评估的方法和步骤。     

基于竞争窗口递减因子自适应调整退避算法

包括IEEE802.11、802.15.4标准在内的许多无线网络协议都采用二进制指数退避机制管理数据的重发。在动态分布式的网络环境中,二进制指数退避算法固定的竞争窗口递减方式难以适应动态变化的网络规模。针对这一问题,提出了一种改进的回退机制,该机制通过引入竞争窗口递减因子,自适应地调整无线节点的等待时间,以实现网络吞吐量的最大化。同时,在算法实现上提出一种启发式算法以跟踪网络中竞争节点数量的改变。在IEEE 802.11DCF协议中以相同的物理层参数进行仿真,结果表明改进算法提高了网络吞吐量,降低了分组平均接入时延。     

无线自组织网络中的自适应竞争窗口退避算法

基于无线自组织网络IEEE 802.11协议原理,改进Ad Hoc网络标准DCF算法,提出一种自动调整最小竞争窗口的退避算法——ABEB算法,建立算法的二维Markov链模型,导出其稳态分布概率,分析其性能并进行了仿真。研究结果表明,与标准DCF算法相比,该算法的吞吐量平均提高了18%,时延平均降低了11%。     

一种优化WLAN上下行公平性的MAC机制

IEEE802．11DCF主要基于载波检测／碰撞退避多址接人协议和时隙制退避算法。因此,往往在基础架构模式中,AP与用户站在随机竞争信道过程中并无优势,并且DCF应用于多速率WLAN,各站点之间的竞争并不均匀（时间不均）,存在吞吐量异常和严重不公平性问题。通过建立三维Markov链模型,对非饱和状态下802．11 MAC协议上下行带宽公平性进行了分析,由此提出基于下行链路优先的DPMAC协议,其核心思想是：AP享有优先访问信道的权利,并且可以根据下行链路状态动态调整占有信道的时间,各用户站竞争信道仍然采用原有的IXZF访问方式。通过仿真证实DPMAC协议能很好地实现上下行链路公平性,达到满意的效果。     

用于无线网络中违规行为检测的退避算法

无线媒体访问控制协议通常使用分布式竞争机制来共享无线信道。通过对IEEE 802.11协议的分布式协调功能机制进行修改,提出一种改进的退避算法,可实现对网络中的违规行为节点的有效检测,并通过惩罚机制加以纠正。仿真结果表明,该方法能够更有效地检测出无线网络中的违规行为,提高整个网络的吞吐量。