research-article

Accurate and Efficient Per-Flow Latency Measurement Without Probing and Time Stamping

Authors:

Muhammad Shahzad,

Alex X. LiuAuthors Info & Claims

IEEE/ACM Transactions on Networking (TON), Volume 24, Issue 6

Pages 3477 - 3492

https://doi.org/10.1109/TNET.2016.2533544

Published: 01 December 2016 Publication History

Abstract

With the growth in number and significance of the emerging applications that require extremely low latencies, network operators are facing increasing need to perform latency measurement on per-flow basis for network monitoring and troubleshooting. In this paper, we propose COLATE, the first per-flow latency measurement scheme that requires no probe packets and time stamping. Given a set of observation points, COLATE records packet timing information at each point so that later, for any two points, it can accurately estimate the average and the standard deviation of the latencies experienced by the packets of any flow in passing the two points. The key idea is that when recording packet timing information, COLATE purposely allows noise to be introduced for minimizing storage space, and when querying the latency of a target flow, COLATE uses statistical techniques to denoise and obtain an accurate latency estimate. COLATE is designed to be efficiently implementable on network middleboxes. In terms of processing overhead, COLATE performs only one hash and one memory update per packet. In terms of storage space, COLATE uses less than 0.1-b/packet, which means that, on a backbone link with half a million packets per second, using a 256-GB drive, COLATE can accumulate time stamps of packets traversing the link for over 1.5 years. We evaluated COLATE using three real traffic traces, namely, a backbone traffic trace, an enterprise network traffic trace, and a data center traffic trace. Results show that COLATE always achieves the required reliability for any given confidence interval.

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Cited By

Guo JHong YWu YLiu YYang TCui BSingh ASun YAkoglu LGunopulos DYan XKumar ROzcan FYe J(2023)SketchPolymer: Estimate Per-item Tail Quantile Using One SketchProceedings of the 29th ACM SIGKDD Conference on Knowledge Discovery and Data Mining10.1145/3580305.3599505(590-601)Online publication date: 6-Aug-2023
https://dl.acm.org/doi/10.1145/3580305.3599505

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cover image IEEE/ACM Transactions on Networking

IEEE/ACM Transactions on Networking Volume 24, Issue 6

December 2016

635 pages

ISSN:1063-6692

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Copyright © 2016.

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IEEE Press

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Published: 01 December 2016

Published in TON Volume 24, Issue 6

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Cited By

Guo JHong YWu YLiu YYang TCui BSingh ASun YAkoglu LGunopulos DYan XKumar ROzcan FYe J(2023)SketchPolymer: Estimate Per-item Tail Quantile Using One SketchProceedings of the 29th ACM SIGKDD Conference on Knowledge Discovery and Data Mining10.1145/3580305.3599505(590-601)Online publication date: 6-Aug-2023
https://dl.acm.org/doi/10.1145/3580305.3599505

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