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在通信网络IP化发展趋势下,集团客户租用运营商以太网专线带宽的需求增长迅速,运营商如何解决带宽容量问题尤为重要。本文将从“FTP/TCP理论及现网带宽实测案例”两个方面对PTN MSTP混合组网承载以太网专线业务的性能问题进行分析,总结得出传送网络承载以太网业务时带宽局限的有效解决方案。 相似文献
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近年来,在运营商的专线业务里,MSTP专线业务的租用越来越普遍。在业务开通过程中,会遇到以太网表测试正常、UDP打流测试正常,但在实际使用中传输速率异常的问题,为此本文提出通过分段测试、修改参数和替换硬件等方法来解决这一问题。 相似文献
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在10 Gbit/s以太网之前,以太网的发展已经经历了3个阶段,即以太网阶段、快速以太网阶段和1 Gbit/s以太网阶段。1 Gbit/s以太网凭借其成本低廉、互通性好、升级容易、组网简单、技术支持厂商多、技术发展快等优势,已占据了整个局域网市场的大部分份额,成为设备的基本配置。目前,10 Gbit/s以太网技术也已日趋成熟。 相似文献
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本文在对Modbus/TCP工业以太网技术深入研究的基础上,设计了一种基于Modbus/TCP协议的三层体系结构的工业控制系统,重点阐述了控制系统三层结构中过程管理层的控制组态、数据管理和数据通讯等各功能模块的设计,最后,以重庆某公司的锅炉汽包水位控制系统为例搭建平台进行验证,验证结果表明,本控制系统各项功能稳定可靠,... 相似文献
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阐述了符合IEEE802.3at标准的以太网供电技术的特点,详细的介绍了基于以太网供电技术的系统结构和供电过程,在此基础上完成基于LTC4274的以太网供电设备和基于LTC4265以太网受电设备的设计。 相似文献
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FTP速率优化涵盖无线优化、传输优化及应用层参数优化等方面。传统的FTP优化主要基于无线优化和传输优化,未涉及用户应用层的优化。本文在现有FTP优化方法基础上,以TCP/IP协议为基础,针对FTP业务信令流程特征及TCP/IP重要参数研究,结合3G无线接入网络信令特征,提出具有指导意义的TCP/IP参数设置规范,对提高现网FTP下载速率及大流量业务应用(如手机流媒体等)具有一定的推广价值。 相似文献
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从ALTO ALOHA网络于1973年开始运转迄今,由于网络技术不断进步,网络设备体积日益减小,网络功能也日渐增强,以前的交换机只有5口、8口,现在单板交换机的网络接口最大端口数已经增加到48个.随着生产工艺的不断更新,网络芯片的方方面面都在发生日新月异的变化. 相似文献
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TCP/IP是Internet的主要技术,也希望能在无线连接中很好地应用,通过一种模拟系统研究了基于IEEE802.11无线介质访问控制协议的TCP/IP的性能. 相似文献
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为了保证汽车ECU的TCP/IP协议实现的准确性,开发了一种车载以太网TCP/IP协议的一致性测试系统,并设计了TCP/IP协议一致性测试集。该测试系统基于NOVUS10/1/100 m车载以太网测试板卡搭建,通过开发的一致性测试软件完成测试用例库管理、测试任务管理和测试数据管理的工作。TCP/IP协议一致性测试集可以对TCP/IP协议中的ARP,IP,TCP和UDP进行协议一致性测试。测试结果表明,该测试系统能够发现被测ECU协议实现的问题,为供应商完善产品协议提供了有效帮助。 相似文献
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随着通信网络IP化趋势发展,PTN、MSTP技术在以太网业务的传输承载上得到了广泛应用。通过理论及现网测试两个方面对PTN、MSTP技术承载以太网专线业务的效率进行分析,总结得出PTN承载以太网业务时网络吞吐率的配置建议。 相似文献
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Euiyul Ko Donghyeok An Ikjun Yeom Hyunsoo Yoon 《International Journal of Communication Systems》2012,25(12):1550-1567
In this paper, we propose a novel technique to deal with sudden bandwidth changes in transmission control protocol (TCP). In the current Internet, sudden bandwidth changes may occur because of vertical handovers between heterogeneous access networks, routing path changes, cognitive ratio, and multi‐rate wireless local area network. The current implementation of TCP is designed and optimized for stable networks and does not adapt well upon sudden bandwidth changes. Consequently, it might suffer from packet losses in burst upon sudden bandwidth decrement and under‐utilization upon sudden bandwidth increment. To resolve this problem, we propose to modify the current TCP algorithm to include a new phase, called fast adaptation (FA). The FA phase is triggered upon detecting sudden bandwidth changes, and a TCP sender in the FA phase attempts to recover lost packets quickly to avoid spurious timeouts upon sudden bandwidth decrement. Upon sudden bandwidth increment, it increases its window size drastically to realize full utilization. Through extensive simulations, experiments, and analysis, it is shown that the proposed scheme can effectively deal with sudden bandwidth changes. Copyright © 2011 John Wiley & Sons, Ltd. 相似文献
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随着网络的快速发展,网络带宽的不断增加,适用于高速长距离网络的TCP协议不断涌现.就近几年提出的几个具有代表性的高速TCP进行了性能比较,尤其对它们的链路利用率和公平性进行了分析.通过分析和比较,获得了很多有用的结论,为TCP的研究进一步指明了方向. 相似文献
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IEEE 802.11 Wireless LAN (WLAN) has become a prevailing solution for broadband wireless Internet access while the Transport
Control Protocol (TCP) is the dominant transport-layer protocol in the Internet. Therefore, it is critical to have a good
understanding of the TCP dynamics over WLANs. In this paper, we conduct rigorous and comprehensive modeling and analysis of
the TCP performance over the emerging 802.11e WLANs, or more specifically, the 802.11e Enhanced Distributed Channel Access
(EDCA) WLANs. We investigate the effects of minimum contention window sizes and transmission opportunity (TXOP) limits (of
both the AP and stations) on the aggregate TCP throughput via analytical and simulation studies. We show that the best aggregate
TCP throughput performance can be achieved via AP’s contention-free access for downlink packet transmissions and the TXOP
mechanism. We also study the effects of some simplifying assumptions used in our analytical model, and simulation results
show that our model is reasonably accurate, particularly, when the wireline delay is small and/or the packet loss rate is
low.
Jeonggyun Yu received his B.E. degree in School of Electronic Engineering from Korea University, Seoul, Korea in 2002. He is currently working toward his Ph.D. in the School of Electrical Engineering at Seoul National University (SNU), Seoul, Korea. His research interests include QoS support, algorithm development, performance evaluation for wireless networks, in particular, IEEE 802.11 wireless local-area networks (WLANs). He is a student member of IEEE. Sunghyun Choi is currently an associate professor at the School of Electrical Engineering, Seoul National University (SNU), Seoul, Korea. Before joining SNU in September 2002, he was with Philips Research USA, Briarcliff Manor, New York, USA as a Senior Member Research Staff and a project leader for three years. He received his B.S. (summa cum laude) and M.S. degrees in electrical engineering from Korea Advanced Institute of Science and Technology (KAIST) in 1992 and 1994, respectively, and received Ph.D. at the Department of Electrical Engineering and Computer Science, The University of Michigan, Ann Arbor in September, 1999. His current research interests are in the area of wireless/ mobile networks with emphasis on wireless LAN/MAN/PAN, next-generation mobile networks, mesh networks, cognitive radios, resource management, data link layer protocols, and cross-layer approaches. He authored/coauthored over 120 technical papers and book chapters in the areas of wireless/mobile networks and communications. He has co-authored (with B. G. Lee) a book “Broadband Wireless Access and Local Networks: Mobile WiMAX and WiFi,” Artech House, 2008. He holds 15 US patents, nine European patents, and seven Korea patents, and has tens of patents pending. He has served as a General Co-Chair of COMSWARE 2008, and a Technical Program Committee Co-Chair of ACM Multimedia 2007, IEEE WoWMoM 2007 and IEEE/Create-Net COMSWARE 2007. He was a Co-Chair of Cross-Layer Designs and Protocols Symposium in IWCMC 2006, 2007, and 2008, the workshop co-chair of WILLOPAN 2006, the General Chair of ACM WMASH 2005, and a Technical Program Co-Chair for ACM WMASH 2004. He has also served on program and organization committees of numerous leading wireless and networking conferences including IEEE INFOCOM, IEEE SECON, IEEE MASS, and IEEE WoWMoM. He is also serving on the editorial boards of IEEE Transactions on Mobile Computing, ACM SIGMOBILE Mobile Computing and Communications Review (MC2R), and Journal of Communications and Networks (JCN). He is serving and has served as a guest editor for IEEE Journal on Selected Areas in Communications (JSAC), IEEE Wireless Communications, Pervasive and Mobile Computing (PMC), ACM Wireless Networks (WINET), Wireless Personal Communications (WPC), and Wireless Communications and Mobile Computing (WCMC). He gave a tutorial on IEEE 802.11 in ACM MobiCom 2004 and IEEE ICC 2005. Since year 2000, he has been a voting member of IEEE 802.11 WLAN Working Group. He has received a number of awards including the Young Scientist Award (awarded by the President of Korea) in 2008; IEEK/IEEE Joint Award for Young IT Engineer of the Year 2007 in 2007; the Outstanding Research Award in 2008 and the Best Teaching Award in 2006 both from the College of Engineering, Seoul National University; the Best Paper Award from IEEE WoWMoM 2008; and Recognition of Service Award in 2005 and 2007 from ACM. Dr. Choi was a recipient of the Korea Foundation for Advanced Studies (KFAS) Scholarship and the Korean Government Overseas Scholarship during 1997–1999 and 1994–1997, respectively. He is a senior member of IEEE, and a member of ACM, KICS, IEEK, KIISE. Daji Qiao is currently an assistant professor in the Department of Electrical and Computer Engineering, Iowa State University, Ames, Iowa. He received his Ph.D. degree in Electrical Engineering-Systems from The University of Michigan, Ann Arbor, Michigan, in February 2004. His current research interests include modeling, analysis and protocol/algorithm design for various types of wireless/mobile networks, including IEEE 802.11 Wireless LANs, mesh networks, and sensor networks. He is a member of IEEE and ACM. 相似文献
| Daji QiaoEmail: |
Jeonggyun Yu received his B.E. degree in School of Electronic Engineering from Korea University, Seoul, Korea in 2002. He is currently working toward his Ph.D. in the School of Electrical Engineering at Seoul National University (SNU), Seoul, Korea. His research interests include QoS support, algorithm development, performance evaluation for wireless networks, in particular, IEEE 802.11 wireless local-area networks (WLANs). He is a student member of IEEE. Sunghyun Choi is currently an associate professor at the School of Electrical Engineering, Seoul National University (SNU), Seoul, Korea. Before joining SNU in September 2002, he was with Philips Research USA, Briarcliff Manor, New York, USA as a Senior Member Research Staff and a project leader for three years. He received his B.S. (summa cum laude) and M.S. degrees in electrical engineering from Korea Advanced Institute of Science and Technology (KAIST) in 1992 and 1994, respectively, and received Ph.D. at the Department of Electrical Engineering and Computer Science, The University of Michigan, Ann Arbor in September, 1999. His current research interests are in the area of wireless/ mobile networks with emphasis on wireless LAN/MAN/PAN, next-generation mobile networks, mesh networks, cognitive radios, resource management, data link layer protocols, and cross-layer approaches. He authored/coauthored over 120 technical papers and book chapters in the areas of wireless/mobile networks and communications. He has co-authored (with B. G. Lee) a book “Broadband Wireless Access and Local Networks: Mobile WiMAX and WiFi,” Artech House, 2008. He holds 15 US patents, nine European patents, and seven Korea patents, and has tens of patents pending. He has served as a General Co-Chair of COMSWARE 2008, and a Technical Program Committee Co-Chair of ACM Multimedia 2007, IEEE WoWMoM 2007 and IEEE/Create-Net COMSWARE 2007. He was a Co-Chair of Cross-Layer Designs and Protocols Symposium in IWCMC 2006, 2007, and 2008, the workshop co-chair of WILLOPAN 2006, the General Chair of ACM WMASH 2005, and a Technical Program Co-Chair for ACM WMASH 2004. He has also served on program and organization committees of numerous leading wireless and networking conferences including IEEE INFOCOM, IEEE SECON, IEEE MASS, and IEEE WoWMoM. He is also serving on the editorial boards of IEEE Transactions on Mobile Computing, ACM SIGMOBILE Mobile Computing and Communications Review (MC2R), and Journal of Communications and Networks (JCN). He is serving and has served as a guest editor for IEEE Journal on Selected Areas in Communications (JSAC), IEEE Wireless Communications, Pervasive and Mobile Computing (PMC), ACM Wireless Networks (WINET), Wireless Personal Communications (WPC), and Wireless Communications and Mobile Computing (WCMC). He gave a tutorial on IEEE 802.11 in ACM MobiCom 2004 and IEEE ICC 2005. Since year 2000, he has been a voting member of IEEE 802.11 WLAN Working Group. He has received a number of awards including the Young Scientist Award (awarded by the President of Korea) in 2008; IEEK/IEEE Joint Award for Young IT Engineer of the Year 2007 in 2007; the Outstanding Research Award in 2008 and the Best Teaching Award in 2006 both from the College of Engineering, Seoul National University; the Best Paper Award from IEEE WoWMoM 2008; and Recognition of Service Award in 2005 and 2007 from ACM. Dr. Choi was a recipient of the Korea Foundation for Advanced Studies (KFAS) Scholarship and the Korean Government Overseas Scholarship during 1997–1999 and 1994–1997, respectively. He is a senior member of IEEE, and a member of ACM, KICS, IEEK, KIISE. Daji Qiao is currently an assistant professor in the Department of Electrical and Computer Engineering, Iowa State University, Ames, Iowa. He received his Ph.D. degree in Electrical Engineering-Systems from The University of Michigan, Ann Arbor, Michigan, in February 2004. His current research interests include modeling, analysis and protocol/algorithm design for various types of wireless/mobile networks, including IEEE 802.11 Wireless LANs, mesh networks, and sensor networks. He is a member of IEEE and ACM. 相似文献
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基于RTT的TCP流带宽公平性保障机制 总被引:3,自引:0,他引:3
TCP端到端的拥塞控制机制使得TCP连接获得的瓶颈带宽反比于RTT(数据包往返时间)。为了缓解TCP对于RTT较小流的偏向,区分服务的流量调节机制在RTT较小的流取得目标速率且获得多余资源的情况下可以确保RTT较大流不至于饥饿。现有的基于RTT的流量调节机制在网络拥塞程度较轻时非常有效,但是当网络拥塞程度较重时,由于对RTT较大流的过分保护而导致RTT较小流饥饿。因此,通过引进自适应的思想提出了改进方法,其主要思想就是根据网络的拥塞程度自适应地调整对RTT较大流的保护程度。大量的仿真试验表明所提的机制能有效保障TCP流的带宽公平性并且比现有的方法具有更好的强壮性。 相似文献