一种高能效无线传感器网络MAC协议

介质访问控制(MAC)协议是无线传感器网络研究领域的基础协议和支撑技术.因此,一种能量高效的MAC协议是提高整个无线传感器网络能量效率的基础.针对无线网络中能量储备有限的特点,在分析了现有无线传感器网络节能协议的基础上,提出了一种能量高效的MAC协议.通过动态调整占空比和消除边界节点等方式,提高了无线传感器网络的能量效率,延长了网络的生命周期.     

分簇无线传感器网络动态时隙分配MAC协议

为降低大规模无线传感器网络的平均能耗,提出了一种基于动态分配的调度型无线传感器网络MAC协议（SDC-MAC）。该协议簇间使用FDMA方式分配无线信道,簇内通过TDMA方式给各个节点分配可变长的时隙。随着簇结构的变化,簇头通过时隙分配通知,对簇内节点的时隙分配进行动态调整,簇成员节点则根据控制信息进行休眠和唤醒。仿真结果显示,该算法有效地降低了网络的平均能耗,当网络流量高时还可降低平均数据包时延。     

基于无线传感器网络的MAC协议研究

无线传感器网络是一种应用极为广泛的新兴网络,MAC协议的研究已成为无线传感器网络中的研究热点。本文对几种典型MAC协议进行了分析,通过讨论其优缺点,指出了当前无线传感器网络面临的挑战,展望了进一步的研究方相。     

一种基于预约的无线传感器网络MAC协议

无线传感器网络要求的能量高效,低延时,使得MAC协议的设计充满挑战。近来已经提出了很多基于簇的MAC协议,为减少冲突在簇内部采用TDMA方式来协调簇内各个节点的传输。提出了一种在采用簇结构的基础上,使用预约方式来发送数据的R-MAC（Reservation-MAC）协议。当争用节点少的时候,采用随机争用方式来预约数据的发送;在争用节点多的时候,采用时隙争用方式来预约数据的发送。分析表明,R-MAC能够有效地降低能耗和减少延迟。     

无线传感器网络及其MAC层协议

无线传感器网络（WSN）是当今信息领域的一大研究热点，在军事、环境、医疗护理和智能家居等方面有着广阔的应用前景，引起了世界各国的广泛关注。首先介绍了无线传感器网络的相关理论知识，然后对无线传感器网络目前所采用的典型的MAC协议按类型进行了介绍。     

无线传感器网络MAC协议研究

本文首先从应用需求和业务特性两方面分析了无线传感器网络MAC协议设计面临的挑战.然后,结合现有典型协议,对无线传感器网络MAC协议的研究现状和趋势、节能策略及协议其他特点进行了分析与总结.最后,探讨了无线传感器网络MAC协议的待研究问题.     

一种无线传感器网络MAC协议的优化方法

依据无线传感器网络生存期主要取决于节点MAC协议低能耗的特点,在S—MAC协议基础上,提出了一种MAC协议优化方法。优化后的协议侦听周期和休眠周期变化是随着网络数据流量而动态变化,这种变化并不是立即生效,而是设定侦听周期次数阈值,如果相邻侦听周期次数阈值内无激活事件,则减小侦听周期,如果相邻侦听周期次数阈值内有激活事件,则延长侦听周期。优化方法仿真显示,节能效果比原有协议有了提高。市场应用趋势,试图把握联通4G在为未来中国通信市场的发展前景,为中国联通4G市场战略决策提供理论参考。     

无线传感器网络MAC层协议浅析

文章简述了无线传感器网络中MAC层协议设计所需要考虑的要素,并详细介绍了S-MAC、T-MAC、PCSMAC、CoLaNet以及ACSEMAC等五种已经提出的MAC协议。通过介绍这些协议的细节,展示了近几年来无线传感器网络MAC层协议的部分研究成果。最后,文章还分析了这些协议的优势和缺陷。     

一种针对无线传感器网络的MAC协议:S-MAC

无线传感器网络是最新产生的一种面向特定应用的网络系统,它产生的得益于无线通信技术和电路集成技术的发展.利用大量的低成本,体积,功能的传感器对环境进行监控,改变了传统的监控方式,具有很广泛的应用前景.文中着重介绍了一种针对无线传感器网络的MAC协议:S-MAC.     

一种基于分簇的WSN时间同步算法

论文提出了一种基于分簇结构的无线传感器网络时间同步算法.在分簇网络结构中,参考DMTS,仿照TPSN采用在MAC层给控制帧标记时同戳的方式,实现了传感器节点的能量效率,进一步提高了时间同步精度.分析表明.本算法在精度和能耗上都有所改进.     

基于FPGA无线传感器网络MAC控制器的设计

给出了一种由FPGA实现的无线传感器网络MAC控制器的设计方法,采用自顶向下的方法设计各个模块,并在QuartusⅡ 8.0完成了仿真,该控制器主要支持IEEE802.15.4协议.测试结果表明,该MAC控制器支持20～250 kb·s<'-1>数据传输速率,适应IEEE802.15.4协议要求.     

认知无线电网络的MAC协议机制

针对认知无线电网络可用信道资源随时间和空间环境变化的特点,分析了认知无线电网络MAC协议面临的问题,提出了一种基于全局控制信道的MAC协议方案,在此基础上阐述了两种接入方式及相应适用场合,实现了认知无线电节点对可用信道资源变化的感知,可为认知无线电MAC协议研究及应用提供参考.     

一种新颖的无线传感器网络的MAC协议

通过对MAC协议运行原理、具有的优缺点、目前所存在的问题以及网络中信道接入机制和能效问题进行分析的基础上,给出一种侦听/睡眠和CDMA相结合的混合MAC协议,此协议采用周期性侦听/睡眠机制和CDMA技术来保证数据的流畅传输,从而实现能量的有效利用。最后,利用仿真软件NS2证明新方法的优越性和高效性。     

Cross-Layer MAC Protocol for Semantic Wireless Sensor Network

Wireless Personal Communications - Wireless sensor networks (WSN) are ad-hoc wireless networks used in many domains involving the analysis of various properties. Along with the growth in the number...     

基于无线传感器网络时间同步MAC协议研究

针对S-MAC协议中不同虚拟簇边界节点的帧的监听时隙不同,提出了在每个节点中保存一个调度表列表,设计创建生成树同步算法。根据优先级标准,在虚拟簇边界节点上进行调度取舍,实现调度的全网同步,完成虚拟簇的合并,消除边界节点,从而解决边界节点能耗过快的问题。仿真结果表明,相比于原有协议,改进后的协议减少网络能耗,降低了数据传输时延。     

Performance Analysis of the Advanced Infrared (AIr) CSMA/CA MAC Protocol for Wireless LANs

Advanced Infrared (AIr) is a proposed standard of the Infrared Data Association (IrDA) for indoor infrared LANs. AIr Medium Access Control (MAC) employs Carrier Sense Multiple Access with Collision Avoidance (CSMA/CA) techniques with Request To Send/Clear To Send (RTS/CTS) frame exchange to address the hidden station problem. A long Collision Avoidance Slot (CAS) duration, that includes the beginning of the CTS frame, is defined to cope with collisions caused from hidden stations. AIr MAC employs linear adjustment of the Contention Window (CW) size to minimize delays emerging from the long CAS duration. This paper provides a simple and accurate analytical model for the linear CW adjustment that calculates AIr throughput assuming a finite number of stations and error free channel transmissions. Validity of the model is verified by comparing analysis with simulation results. By examining the first derivative of the throughput equation, we derive the optimum CW size that maximizes throughput as a function of the network size. In the case of the AIr protocol, where a collision lasts exactly one CAS, different conclusions result for maximum throughput as compared with the corresponding conclusions for the similar IEEE 802.11 protocol. Using the proposed model, we present an extensive AIr throughput performance evaluation. The effectiveness of physical and link layer parameters on throughput performance is explored. The proposed long CAS duration combined with CW linear adjustment are proven quite effective. Linear CW adjustment combined with the long CAS duration offer an efficient collision avoidance scheme that does not suffer from collisions caused from hidden stations.     

High Performance Wireless Switch Protocol for IEEE 802.11 Wireless Networks

All mobile stations (STAs) in IEEE 802.11 infrastructure wireless local area networks (IWLAN) are coordinated by an access point (AP). Within the 2.4 GHz unlicensed industry, science, and medicine (ISM) band defined in the IEEE 802.11 2.4 GHz physical layer (PHY) specifications, three channels are available for concurrently transferring data packets at the coverage area of an AP. In most of small/medium enterprises or home environments, an AP with one selected channel is sufficient for covering whole service area, but this implies that the radio resources for the remaining two channels are wasted. In order to overcome the drawback, we propose a new and simple media access control (MAC) protocol, named wireless switch protocol (WSP), for increasing the throughput of IEEE 802.11 IWLAN network to support high quality multimedia traffic. This is achieved by allowing any pair of STAs in IWLAN to exchange data packets in one of other idle channels after their handshake with each other in the common channel controlled by AP. Simulation results show that the total network throughput of WSP depends on the time taken by channel switching, and on the ‘Intranet’ and ‘Internet’ traffic distribution, where the Intranet and Internet mean data transmission between STAs in IWLAN and between the STA and wired host, respectively. When all data packets are Intranet traffic and the traffic load is heavy, the ratio of Goodput for the proposed WSP to that of IEEE 802.11 standard approximates 400%. In the worse case of all Internet traffic, the proposed WSP still obtains the similar throughput as that of IEEE 802.11 standard.Jenhui Chen was born on October 12, 1971 in Taipei, Taiwan, Republic of China. He received the Bachelor’s and Ph.D. degree in Computer Science and Information Engineering (CSIE) from Tamkang University in 1998 and 2003, respectively. In the Spring of 2003, he joined the faculty of Computer Science and Information Engineering Department at Chang Gung University and served as the Assistant Professor. He occupies the supervisor of Network Department in the Information Center, Chang Gung University. Dr. Chen once served the reviewer of IEEE Transactions on Wireless Communications, ACM/Kluwer Mobile Networks and Applications (MONET), and Journal of Information Science and Engineering. His main research interests include design, analysis, and implementation of communication and network protocols, wireless networks, milibots, and artificial intelligence. He is a member of ACM and IEEE.Ai-Chun Pang was born in Hsinchu, Taiwan, R.O.C., in 1973. She received the B.S., M.S. and Ph.D. degrees in Computer Science and Information Engineering from National Chiao Tung University (NCTU) in 1996, 1998 and 2002, respectively. She joined the Department of Computer Science and Information Engineering, National Taiwan University (NTU), Taipei, Taiwan, as an Assistant Professor in 2002. Her research interests include design and analysis of personal communications services network, mobile computing, voice over IP, and performance modeling.Shiann-Tsong Sheu received his B.S. degree in Applied Mathematics from National Chung Hsing University in 1990, and obtained his Ph.D. degree in Computer Science from National Tsing Hua University in May of 1995. From 1995 to 2002, he was an Associate Professor at the Department of Electrical Engineering, Tamkang University. Since Feb. 2002, he has become a Professor at the Department of Electrical Engineering, Tamkang University. Dr. Sheu received the outstanding young researcher award by the IEEE Communication Society Asia Pacific Board in 2002. His research interests include next-generation wireless communication, WDM networks and intelligent control algorithms.Hsueh-Wen Tseng received his B.S. degree in electrical engineering from Tamkang University, Taipei country, Taiwan, in 2001 and M.S. degree in electrical engineering from National Taiwan University of Science and Technology, Taipei, Taiwan, in 2003. He is currently pursuing the Ph. D. degree at the Department of Computer Science and Information Engineering, National Taiwan University, Taipei, Taiwan. His research interests include design, analysis and implementation of network protocols and wireless communications.     

X-MAC:一种新型的无线传感器网络MAC协议﹡

在无线传感器网络体系结构中,MAC(Medium Access Control)协议是保证网络高效通信的重要协议.无线传感器网络有着与传统无线网络明显不同的性能特点和技术要求.对于很多的 MAC 层协议而言,吞吐量很大程度上受到了物理信道的利用率和协议开销的限制.这里设计了一种基于一对多拓扑的无线传感器Mac层网络协议.最后,还通过NS-2(Network Simulator 2)仿真并比较该协议与现存无线传感器MAC层网络协议的网络性能.     

A Cluster-Based Random Key Revocation Protocol for Wireless Sensor Networks

In recent years,several random key pre-distribution schemes have been proposed to bootstrap keys for encryption,but the problem of key and node revocation has received relatively little attention.In this paper,based on a random key pre-distribution scheme using clustering,we present a novel random key revoca-tion protocol,which is suitable for large scale networks greatly and removes compromised information efficiently.The revocation protocol can guarantee network security by using less memory consumption and communication load,and combined by centralized and distributed revoca-tion,having virtues of timeliness and veracity for revoca-tion at the same time.