Towards a Bufferless Optical Internet

Towards a Bufferless Optical Internet

This paper investigates the relationship between buffer size and long-term average TCP performance in dense wavelength division multiplexing (DWDM) networks. By investigating TCP NewReno, we demonstrate that buffer requirements are related to the number of wavelength channels at a bottleneck. With s...

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Veröffentlicht in:Journal of lightwave technology 2009-07, Vol.27 (14), p.2817-2833
Hauptverfasser: Wong, E., Andrew, L., Cui, T., Moran, B., Zalesky, A., Tucker, R.S., Zukerman, M.
Format: Artikel
Sprache:eng
Schlagworte:
Analytical models
Approximation
Bit rate
Bufferless optical packet switching (OPS)
Buffers
Channels
dense wavelength division multiplexing (DWDM) network
Extrapolation
Internet
Mathematical analysis
Optical buffering
Optical packet switching
Optical switches
Packet switching
Switching theory
TCP
TCP (protocol)
Throughput
Wavelength division multiplexing
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container_end_page 2833
container_issue 14
container_start_page 2817
container_title Journal of lightwave technology
container_volume 27
creator Wong, E.
Andrew, L.
Cui, T.
Moran, B.
Zalesky, A.
Tucker, R.S.
Zukerman, M.
description This paper investigates the relationship between buffer size and long-term average TCP performance in dense wavelength division multiplexing (DWDM) networks. By investigating TCP NewReno, we demonstrate that buffer requirements are related to the number of wavelength channels at a bottleneck. With sufficient wavelengths, high throughput can be obtained with a buffer of one packet per channel; furthermore, there may be situations where an entirely bufferless optical packet switching (OPS) will become feasible. For this study, we develop new evaluation tools. First, we propose a method based on a two-part analytical model, with a new ¿open loop¿ component which approximates packet discarding in a bottleneck DWDM switch, and a ¿closed loop¿ fixed-point which reflects the impact of TCP. This analytical method provides accurate and scalable approximations of throughput and packet loss rate that can be used as part of a tool for DWDM network and switch design. Second, we propose an extrapolation technique to allow simulation of TCP over long ultra-high bit rate links, avoiding the intractable processing and memory requirements of direct simulation. This extrapolation technique enables us to validate the analytical model for arbitrarily high bit rate scenarios.
doi_str_mv 10.1109/JLT.2009.2017211
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By investigating TCP NewReno, we demonstrate that buffer requirements are related to the number of wavelength channels at a bottleneck. With sufficient wavelengths, high throughput can be obtained with a buffer of one packet per channel; furthermore, there may be situations where an entirely bufferless optical packet switching (OPS) will become feasible. For this study, we develop new evaluation tools. First, we propose a method based on a two-part analytical model, with a new ¿open loop¿ component which approximates packet discarding in a bottleneck DWDM switch, and a ¿closed loop¿ fixed-point which reflects the impact of TCP. This analytical method provides accurate and scalable approximations of throughput and packet loss rate that can be used as part of a tool for DWDM network and switch design. 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source IEEE Electronic Library (IEL)
subjects Analytical models
Approximation
Bit rate
Bufferless optical packet switching (OPS)
Buffers
Channels
dense wavelength division multiplexing (DWDM) network
Extrapolation
Internet
Mathematical analysis
Optical buffering
Optical packet switching
Optical switches
Packet switching
Switching theory
TCP
TCP (protocol)
Throughput
Wavelength division multiplexing
title Towards a Bufferless Optical Internet
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