PHASE-PLANE ANALYSIS OF SWITCHING DYNAMICS OF TCP FLOW CONTROL ALGORITHMS

H.-T. Lee,∗ F.-L. Lian,∗∗ and T.-C. Fong∗∗

References

  1. [1] S.H. Low, F. Paganini, & J.C. Doyle, Internet congestion control, IEEE Control Systems Magazine, 22(1), 2002, 28–43.
  2. [2] V. Jacobson, Congestion avoidance and control, Proc. ACM SIGCOMM, Stanford, CA, USA, August 1988, 314–329.
  3. [3] V. Jacobson, Berkeley TCP evolution from 4.3-Tahoe to 4.3TCP-Reno, Proc. 18th Internet Eng. Task Force, Vancouver, BC, Canada, August 1990.
  4. [4] L.S. Brakmo & L.L. Peterson, TCP Vegas: End to end congestion avoidance on a global Internet, IEEE Journal on Selected Areas in Communications, 13(8), 1995, 1465–1480.
  5. [5] S. Floyd & V. Jacobson, Random early detection gateways for congestion avoidance, IEEE/ACM Transactions on Networking, 1(4), 1993, 397–413.
  6. [6] T. Ikegawa, Comparative Performance Analysis of Basic Window Size Adjustment Algorithms for Dynamic Windows Flow Controlled Internet Environment: Markov Renewal Reward Process Modeling, Proceeding (368) Networks, Parallel and Distributed Processing, and Applications, 2002.
  7. [7] V. Misra, W. Gong, & D. Towsley, A fluid-based analysis of a network of AQM routers supporting TCP flows with an application to RED, Proc. ACM SIGCOMM, 30(4), Stockholm, Sweden, September 2000, 151–160.
  8. [8] H. Ohsaki, M. Murata, T. Ushio, & H. Miyahara, Stability analysis of window-based flow control mechanism in TCP/IP networks, Proc. 1999 IEEE International Conference on Control Application, Hawaii, USA, Vol. 2, August 1999, 1603–1606.
  9. [9] C.V. Hollot & Y. Chait, Nonlinear stability analysis for a class of TCP/AQM networks, IEEE Conference on Decision and Control, Vol. 3, Orlando, FL, USA, December 2001, 2309–2314.
  10. [10] Y. Fan, Z.P. Jiang, & S.S. Panwar, An adaptive control scheme for stabilizing TCP, Proc. 5th World Congress on Intelligent Control and Automation, Vol. 2, Hangzhou, P. R. China, June 2004, 1410–1414.
  11. [11] G. Hasegawa, K. Kurata, & M. Murata, Analysis and improvement of fairness between TCP TCP-Reno and vegas for deployment of TCP vegas to the internet, Proc. 2000 IEEE International Conference on Network Protocols, Osaka, Japan, November 2000, 177–186.
  12. [12] J.R. Chen, Y.C. Chen, & C.L. Lee, An end-to-end flow control approach based on round trip time, Computer Communications, 23(16), 2000, 1537–1547.
  13. [13] A. Maor & Y. Mansour, AdaVegas: Adaptive control for TCP Vegas, Proc. IEEE GLOBECOM’03, Vol. 7, San Francisco, CA, USA, December 2003, 3647–3651.
  14. [14] K.N. Srijith, L. Jacob, & A.L. Ananda, TCP Vegas-A: Improving the performance of TCP vegas, Computer Communications, 28(4), 2005, 429–440.
  15. [15] J. Chen, F. Paganini, M.Y. Sanadidi, & R. Wang, Fluid-flow analysis of TCP Westwood with RED, Computer Networks, 50(9), 2006, 1302–1326.
  16. [16] J.-J.E. Slotine & W. Li, Applied nonlinear control (Englewood Cliffs: Prentice-Hall, Inc., 1991).
  17. [17] The Network Simulator – ns-2, http://www.isi.edu/nsnam/ns/

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