• 제목/요약/키워드: TCP-Westwood Algorithm

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The Study on New Wireless TCP-Westwood Algorithm having Available Bandwidth Estimation within Allowable Range (허용범위내 가용대역측정값을 가지는 새로운 무선 TCP-Westwood 알고리즘에 대한 연구)

  • Yoo, Chang-Yeol;Kim, Dong-Hoi
    • Journal of Digital Contents Society
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    • v.15 no.2
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    • pp.147-154
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    • 2014
  • There have been company researches for TCP-Westwood algorithms in wireless TCP environment with high packet loss rate. Because the TCP-Westwood algorithm adjusts the congestion window according to the ABE(Available Bandwidth Estimation), the algorithm has a problem which the accuracy of ABE decreases as the error rate increases. To solve such a problem, the proposed scheme in this paper adopts the existing packet pattern based algorithm that the ABE is ignored when the arriving interval time of ACK is longer than a given interval time and uses new algorithm that the ABE is reallocated to a given allowable ABE when the ABE is over the allowable range. The proposed scheme shows the simulation result that the ABE is closest to the setting bandwidth for simulation compared to the existing algorithms.

Performance Improvement of WTCP by Differentiated Handling of Congestion and Random Loss (혼잡 및 무선 구간 손실의 차별적 처리를 통한 WTCP 성능 개선)

  • Cho, Nam-Jin;Lee, Sung-Chang
    • Journal of the Institute of Electronics Engineers of Korea TC
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    • v.45 no.9
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    • pp.30-38
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    • 2008
  • The traditional TCP was designed assuming wired networks. Thus, if it is used networks consisting of both wired and wireless networks, all packet losses including random losses in wireless links are regarded as network congestion losses. Misclassification of packet losses causes unnecessary reduction of transmission rate, and results in waste of bandwidth. In this paper, we present WTCP(wireless TCP) congestion control algorithm that differentiates the random losses more accurately, and adopts improved congestion control which results in better network throughput. To evaluate the performance of proposed scheme, we compared the proposed algorithm with TCP Westwood and TCP Veno via simulations.

TCP NJ+: Packet Loss Differentiated Transmission Mechanism Robust to High BER Environments (TCP NJ+ : 높은 BER에 강인한 패킷 손실 원인별 처리기반 전송방식)

  • Kim, Jung-Rae;Lee, You-Ho;Choo, Hyun-Seung
    • Journal of Internet Computing and Services
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    • v.8 no.5
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    • pp.125-132
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    • 2007
  • Transmission mechanisms that include an available bandwidth estimation algorithm and a packet loss differentiation scheme, in general, exhibit higher TCP performance in wireless networks. TCP New Jersey, known as the best existing scheme in terms of goodput, improves wireless TCP performance using the available bandwidth estimation at the sender and the congestion warning at intermediate routers. Although TCP New Jersey achieves 17% and 85% improvements in goodput over TCP Westwood and TCP Reno, respectively, we further improve TCP New Jersey by exploring improved available bandwidth estimation, retransmission timeout, and recovery mechanisms. Hence, we propose TCP New Jersey PLUS (shortly TCP NJ+), showing that under 1% packet loss rate, it outperforms 3% by TCP New Jersey and 5% by TCP Wes1wood. In 5% packet loss rate, a characteristic of high bit-error-rate wireless network, it outperforms other TCP variants by 19% to 104% in terms of goodput even when the network is in bi-directional congestion.

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NJ+: An Efficient Congestion Control Mechanism for Wireless Networks

  • Lee, Jae-Hyung;Kim, Jung-Rae;Park, Min-U;Koo, Ja-Hwan;Choo, Hyun-Seung
    • KSII Transactions on Internet and Information Systems (TIIS)
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    • v.2 no.6
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    • pp.333-351
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    • 2008
  • Transmission control protocols have to overcome common problems in wireless networks. TCP employing both packet loss discrimination mechanism and available bandwidth estimation algorithm, known as the good existing solution, shows significant performance enhancement in wireless networks. For instance, TCP New Jersey which exhibits high throughput in wireless networks intends to improve TCP performance by using available bandwidth estimation and congestion warning. Even though it achieves 17% and 85% improvements in terms of goodput over TCP Westwood and TCP Reno, respectively, we further improve it by exploring maximized available bandwidth estimation, handling bit-error-rate error recovery, and effective adjustment of sending rate for retransmission timeout. Hence, we propose TCP NJ+, showing that for up to 5% packet loss rate, it outperforms other TCP variants by 19% to 104% in terms of goodput when the network is in bi-directional background traffic.