Routing high-bandwidth traffic in max-min fair share networks

Subscribe (Full Service)


	Search: The ACM Digital Library The Guide

	Feedback

Routing high-bandwidth traffic in max-min fair share networks

Full text

Pdf (264 KB)

Source

Applications, Technologies, Architectures, and Protocols for Computer Communication archive
Conference proceedings on Applications, technologies, architectures, and protocols for computer communications table of contents

Palo Alto, California, United States

Pages: 206 - 217

Year of Publication: 1996

ISBN:0-89791-790-1

Also published in ...

Authors

Qingming Ma	School of Computer Science, Carnegie Mellon University, Pittsburgh, PA
Peter Steenkiste	School of Computer Science, Carnegie Mellon University, Pittsburgh, PA
Hui Zhang	School of Computer Science, Carnegie Mellon University, Pittsburgh, PA

Sponsor

SIGCOMM: ACM Special Interest Group on Data Communication

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 4, Downloads (12 Months): 30, Citation Count: 13

Additional Information:

abstract references cited by index terms collaborative colleagues peer to peer

Tools and Actions:	Request Permissions Review this Article Save this Article to a Binder Display Formats: BibTeX EndNote ACM Ref

DOI Bookmark:	Use this link to bookmark this Article: http://doi.acm.org/10.1145/248156.248175 What is a DOI?

ABSTRACT

We study how to improve the throughput of high-bandwidth traffic such as large file transfers in a network where resources are fairly shared among connections. While it is possible to devise priority or reservation-based schemes that give high-bandwidth traffic preferential treatment at the expense of other connections, we focus on the use of routing algorithms that improve resource allocation while maintaining max-min fair share semantics. In our approach, routing is closely coupled with congestion control in the sense that congestion information, such as the rates allocated to existing connections, is used by the routing algorithm. To reduce the amount of routing information that must be distributed, an abstraction of the congestion information is introduced. Using an extensive set of simulation, we identify a link-cost or cost metric for "shortest-path" routing that performs uniformly better than the minimal-hop routing and shortest-widest path routing algorithms. To further improve throughput without reducing the fair share of single-path connections, we propose a novel prioritized multi-path routing algorithm in which low priority paths share the bandwidth left unused by higher priority paths. This leads to a conservative extension of max-min fairness called prioritized multi-level max-min fairness. Simulation results confirm the advantages of our multi-path routing algorithm.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	J.M. Akinpelu. The Overload Performance of Engineered Networks with Nonhierarchical and Hierachical Routing. Bell System Technical Journal, pages 1261- 1281, September 1984.
	2	Saewoong Bahk , Magda El Zarki, Dynamic multi-path routing and how it compares with other dynamic routing algorithms for high speed wide area network, Conference proceedings on Communications architectures & protocols, p.53-64, August 17-20, 1992, Baltimore, Maryland, United States
	3	Jochen Behrens , J. J. Garcia-Luna-Aceves, Distributed, scalable routing based on link-state vectors, Proceedings of the conference on Communications architectures, protocols and applications, p.136-147, August 31-September 02, 1994, London, United Kingdom
	4	F. Bonomi and K. Fendick. The Rate-Based Flow Control Framework for the Available Bit Rate ATM Service. IEEE Network, 9(2):25-39, March/April 1995.
	5	L. Breslau, D. Estrin, and L. Zhang. A Simulation Study of Adaptive Source Routing in Integrated Service Networks. USU USD Technical Report, Sep., 1993.
	6	A. Charny, D.D. Clark, and R. Jain. Congestion Control With Explicit Rate Indication. In Proc, IUU'95, June 1995.
	7	A. Charny, K.K. Ramakrishnan, and A. Lauck. Scalability Issues for Distributed Explicit Rate Allocation in ATM. In Proc, IEEE INFOCOM'96, 1996.
	8	David D. Clark. Adding Service Discrimination to the Internet. Preprint, 1995.
	9	A. Demers , S. Keshav , S. Shenker, Analysis and simulation of a fair queueing algorithm, ACM SIGCOMM Computer Communication Review, v.19 n.4, p.1-12, Sep. 1989
	10	PNNI SWG Doug Dykeman (ed.). PNNI Draft Specification. ATM Forum 94-0471R10, October 1995.
	11	E.W. Dijkstra. A Note on Two Problems in Connexion with Graphs. Numcrischc Mathcmatik, pages 1:269- 271, 1959.
	12	A. Fraser. Towards a Universal Data Transport System. IEEE JSAU, pages 803-816, Nov 1983.
	13	R.J. Gibbens, F.P. Kelley, and P.B. Key. Dynamic Alternative Routing- Modelling and Behaviour. In Proceedings of the 12th International Teletraffic Congress, June 1988.
	14	J.M. Jaffe. Bottleneck flow control. IEEE Transactions on Communications, COM-29(7):954-962, July 1981. Correspondence.
	15	R. Jain. The Art of Computer Performance Analysis. Wiley, 1991.
	16	Kevin Lang , Satish Rao, Finding near-optimal cuts: an empirical evaluation, Proceedings of the fourth annual ACM-SIAM Symposium on Discrete algorithms, p.212-221, January 25-27, 1993, Austin, Texas, United States
	17	J. Liebeherr, I.F. Akyildiz, and A. Tai. A Multi-level Explicit Rate Control Scheme for ABR Traffic with Heterogeneous Service Requirements. Submitted for Publication, July 1995.
	18	J.M. McQuillan, I. Richer, and E. Rosen. The New Routing Algorithm for the ARPANET. IEEE Transactions on Communications, COM-28(5):711-719, May 1980.
	19	D.J. Nelson, K. Sayood, and H. Chang. An Extended Least-hop Distributed Routing Algorithm. IEEE Transactions on Communications, COM-38(4):520- 528, April 1990.
	20	M. Schwartz and T.E. Stern. Routing Techniques Used in Computer Communication Networks. IEEE Transactions on Communications, COM-28(4), April 1980.
	21	S. Shenker, D.D. Clark, and L. Zhang. A Scheduling Service Model and a Scheduling Architecture for an Integrated Service Packet Network. preprint, 1993.
	22	J. Sole-Pareta, D. Sarkar, J. Liebeherr, and I.F. Akyildiz. Adaptive Multipath Routing of Connectionless Traffic in an ATM Network. In Proc. IEEE ICC'95, May 1995.
	23	M. Steenstrup. Inter-Domain Policy Routing Protocol Specification: Version 1. Technical Report Internet Draft, May 1992.
	24	Hiroshi Suzuki , Fouad A. Tobagi, Fast bandwidth reservation scheme with multi-line & multi-path routing in ATM networks, Proceedings of the eleventh annual joint conference of the IEEE computer and communications societies on One world through communications (Vol. 3), p.2233-2240, May 1992, Florence, Italy
	25	Z. Wang , J. Crowcroft, Shortest path first with emergency exits, Proceedings of the ACM symposium on Communications architectures & protocols, p.166-176, September 26-28, 1990, Philadelphia, Pennsylvania, United States
	26	Z. Wang and J. Crowcroft. QoS Routing for Supporting Resource Reservation. IEEE JSAC, to appear 1996.

CITED BY 13

	C. Casetti , R. Lo Cigno , M. Mellia , M. Munafò , Z. Zsóka, A new class of QoS routing strategies based on network graph reduction, Computer Networks: The International Journal of Computer and Telecommunications Networking, v.41 n.4, p.475-487, 15 March 2003
	Jeffrey Semke , Jamshid Mahdavi , Matthew Mathis, Automatic TCP buffer tuning, ACM SIGCOMM Computer Communication Review, v.28 n.4, p.315-323, Oct. 1998
	Emilio Leonardi , Marco Mellia , Marco Ajmone Marsan , Fabio Neri, Optimal scheduling and routing for maximum network throughput, IEEE/ACM Transactions on Networking (TON), v.15 n.6, p.1541-1554, December 2007
	Xun Su , Gustavo de Veciana, Predictive routing to enhance QoS for stream-based flows sharing excess bandwidth, Computer Networks: The International Journal of Computer and Telecommunications Networking, v.42 n.1, p.65-80, 15 May 2003
	Csaba Kiss Kalló , Carla-Fabiana Chiasserini , Sewook Jung , Mauro Brunato , Mario Gerla, Hop count based optimization of Bluetooth scatternets, Ad Hoc Networks, v.5 n.3, p.340-359, April, 2007
	S. Sriram , T. Bheemarjuna Reddy , B. S. Manoj , C. Siva Ram Murthy, On the end-to-end call acceptance and the possibility of deterministic QoS guarantees in ad hoc wireless networks, Proceedings of the 6th ACM international symposium on Mobile ad hoc networking and computing, May 25-27, 2005, Urbana-Champaign, IL, USA
	Zhenghua Fu , Nalini Venkatasubramanian, Combined path and server selection in dynamic multimedia environments, Proceedings of the seventh ACM international conference on Multimedia (Part 1), p.469-472, October 30-November 05, 1999, Orlando, Florida, United States
	Dániel Orincsay , Balázs Szviatovszki , Géza Böhm, Prompt partial path optimization in MPLS networks, Computer Networks: The International Journal of Computer and Telecommunications Networking, v.43 n.5, p.557-572, 5 December 2003
	Jun Wang , Klara Nahrstedt, Hop-by-hop routing algorithms for premium traffic, ACM SIGCOMM Computer Communication Review, v.32 n.5, November 2002
	Daniel Bauer , John N. Daigle , Ilias Iliadis , Paolo Scotton, Topology aggregation for combined additive and restrictive metrics, Computer Networks: The International Journal of Computer and Telecommunications Networking, v.50 n.17, p.3284-3299, 5 December 2006
	Shigang Chen , Yuguang Fang , Ye Xia, Lexicographic Maxmin Fairness for Data Collection in Wireless Sensor Networks, IEEE Transactions on Mobile Computing, v.6 n.7, p.762-776, July 2007
	Garth A. Gibson , David F. Nagle , Khalil Amiri , Fay W. Chang , Eugene M. Feinberg , Howard Gobioff , Chen Lee , Berend Ozceri , Erik Riedel , David Rochberg , Jim Zelenka, File server scaling with network-attached secure disks, ACM SIGMETRICS Performance Evaluation Review, v.25 n.1, p.272-284, June 1997
	Marco Dorigo , Gianni Di Caro , Luca M. Gambardella, Ant algorithms for discrete optimization, Artificial Life, v.5 n.2, p.137-172, April 1999