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Reseach Article

Interaction Studies of Some Recent AQMs with High Speed TCPs through Experimental Evaluation

Published on September 2016 by Vandana Kushwaha, Ratneshwer
National Conference on Advances in Computing Applications
Foundation of Computer Science USA
NCACA2016 - Number 1
September 2016
Authors: Vandana Kushwaha, Ratneshwer
130b4b53-fa7d-4f68-8254-b09023ce2d4e

Vandana Kushwaha, Ratneshwer . Interaction Studies of Some Recent AQMs with High Speed TCPs through Experimental Evaluation. National Conference on Advances in Computing Applications. NCACA2016, 1 (September 2016), 30-37.

@article{
author = { Vandana Kushwaha, Ratneshwer },
title = { Interaction Studies of Some Recent AQMs with High Speed TCPs through Experimental Evaluation },
journal = { National Conference on Advances in Computing Applications },
issue_date = { September 2016 },
volume = { NCACA2016 },
number = { 1 },
month = { September },
year = { 2016 },
issn = 0975-8887,
pages = { 30-37 },
numpages = 8,
url = { /proceedings/ncaca2016/number1/26171-1032/ },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Proceeding Article
%1 National Conference on Advances in Computing Applications
%A Vandana Kushwaha
%A Ratneshwer
%T Interaction Studies of Some Recent AQMs with High Speed TCPs through Experimental Evaluation
%J National Conference on Advances in Computing Applications
%@ 0975-8887
%V NCACA2016
%N 1
%P 30-37
%D 2016
%I International Journal of Computer Applications
Abstract

The two approaches of congestion control i. e. source based approach and router based approach have their own limitations. In source based approach, It is difficult to get correct location of congestion and without proper admission control; it would be difficult to effectively manage the congestion problem. So both approaches have to work in coordination for effectively control the congestion problem. In this context, an interaction study plays an important role to verify how an AQM implemented at router end works with TCP at source end. In this paper, the performance of some recent AQM approaches: CoDel and sfqCoDel have been analyzed, in presence of different high speed TCP variants at the source end. The main objective of this work is to obtain the interaction patterns of recently proposed AQMs with different high speed TCP variants like: HTCP, Compound and Cubic. Simulation results show that that if the objective is to achieve a better throughput and improved fairness simultaneously, sfqCoDel may be a good choice of AQM.

References
  1. Kushwaha V, Gupta R. Congestion control for high-speed wired network: a systematic literaturereview. Journal of Network and Computer Applications, Vol. 45, pp:62–78, 2014.
  2. Nichols, K. , Jacobson, V. (2012). Controlling queue delay. Communications of the ACM, Vol. 55(7), pp:42-50.
  3. Hoeiland-Joergensen, T. , McKenney, P. et al. (2014). Flowqueue-Codel (draft-hoeilandjoergensen-aqm-fq-codel-00). Retrieved from: https://tools. ietf. org/html/draft-hoeiland-joergensen-aqm-fq-codel-00.
  4. Leith, D. , Shorten, R. (2004). H-TCP: TCP for high-speed and long distance networks. In: Proceedings of the PFLDnet. 2004.
  5. Tan, K. , Song, J. (2006). Compound TCP: a scalable and TCP-friendly congestion control for high-speed networks. In Proc. 4th International Workshop on Protocols for FAST Long-Distance Networks, March 2006.
  6. Rhee, I. , Xu, L. (2008). CUBIC: a new TCP-friendly high-speed TCP variant. SIGOPS Operating System Review, Vol. 42(5), pp:64–74.
  7. Chydzinski, A. , Brachman, A. (2010). Performance of AQM routers in the presence of new TCP variants. In: Proceedings of the second international conference on advances in future internet. pp. 88–93.
  8. Floyd, S. , Jacobson, V. (1993). Random early detection gateways for congestion avoidance. IEEE/ACM Transactions on Networking, Vol. 1(4), pp: 397–413.
  9. Kunniyur, S. , Srikant, R. (2001). Analysis and design of an adaptive virtual queue (AVQ) algorithm for active queue management. Computer Communication Review, Vol. 31(4), pp:123–134.
  10. Hollot, C. , Misra, V. , Towsley, D. , Gong, W. (2002). Analysis and design of controllers for AQM routers supporting TCP flows. IEEE Transactions of Automatic Control, Vol. 47, pp: 945–959.
  11. Lapsley, D. , Low, S. (1999). Random early marking: an optimization approach to internet congestion control. In: Proceedings of the IEEE ICON.
  12. Eshete, A. , Jiang, Y. ,Landmark, L. (2012). Fairness among high speed and traditional TCP under different queue management mechanisms. In: Proceedings of the ACM asian internet engineering conference. pp. 39–46.
  13. Xue, L. , Cui, C. et al. (2012). Experimental evaluation of the effect of queue management schemes on the performance of high speed tcps in 10gbps network environment. In proceeding of International Conference on Computing, Networking and Communications (ICNC), pp: 315-319, IEEE.
  14. CRON, (2011). CRON Project: Cyberinfrastructure for Reconfigurable Optical Networking Environment. Retrieved from: http://www. cron. loni. org/.
  15. Kuhn, N. , Lochin, E. et al. (2014). Revisiting old friends: Is codel really achieving what red cannot? In: ACM SIGCOMM Capacity Sharing Workshop. ACM, Chicago, IL, USA.
  16. Gettys, J. , Nichols, K. (2012). Bufferbloat: dark buffers in the internet. Communications of the ACM, Vol. 55(1), pp:57-65.
  17. Rao, V. P. , Tahiliani, M. P. et al. (2014). Analysis of sfqCoDel for Active Queue Management, Applications of Digital Information and Web Technologies (ICADIWT).
  18. Ns-2 Network Simulator. (n. d. ). Retrieved from: ?http://www. isi. edu/nsnam/ns/?.
Index Terms

Computer Science
Information Sciences

Keywords

High Speed Networks Congestion Control Active Queue Management Buffer-bloat