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Dynamic Hybrid Topology Design
for Integrated Traffic Support
in WDM Mesh Networks
(Invited Paper)
Mina Youssef, Baek-Young Choiz, Caterina Scoglio, Eun Kyo Park
Pages - 115 - 131 | Revised - 30-4-2010 | Published - 10-06-2010
Published in International Journal of Computer Networks (IJCN)
MORE INFORMATION
KEYWORDS
WDM networks, Multicast, Hybrid topology
ABSTRACT
The future Internet will require the transport of a wide range of services including high bandwidth one-to-many applications, with a dynamic
interconnection of devices. WDM layer support realizes such services in a transparent, reliable and efficient way. Most of the recent studies
have been focused on efficiently building and configuring light-paths for unicast or light-trees for multicast in isolation, and do not take
existing traffic demands and configuration into consideration. In this paper we consider a dynamic design problem of integrated traffic in a
realistic WDM mesh network. In such a network, new traffic demands of either multicast and/or unicast are supported dynamically in the presence
of an existing mixture of traffic. The amount of bandwidth per wavelength is abundant, while the wavelengths and light splitting capabilities
on WDM switches are limited. Using subwavelength sharing among traffic demands of unicast and multicast, we build a hybrid virtual topology that
exploits both existing light-trees and light-paths. By optimizing WDM resources in addition to resource sharing with existing unicast and
multicast demands, we truly maximize the WDM layer capability and efficiently support more traffic demands. We validate the efficiency of our
approach with extensive simulations on various network topologies.
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A. E. Gencata and B. Mukherjee, “Virtual-topology adaptation for WDM mesh networks under | |
B. Mukherjee, “Optical Communication Networks: WDM, Broadcast/Multicast and | |
B. Ramamurthy and A. Ramakrishnan, “Virtual topology reconfiguration of wavelength-routed | |
C. Qiao, “Labeled optical burst switching for IP-over-WDM integration”. IEEE Communications | |
D. Banerjee and B. Mukherjee, “Wavelength-Routed Optical Networks: Linear Formulation, | |
D. Cavendish and B. Sengupta, “Routing and wavelength assignment in WDM rings with heterogeneous wavelength conversion capabilities”. In IEEE Infocom, 2002. | |
D.-N. Yang and W. Liao, “Design of Light-Tree Based Logical Topologies for Multicast Streams in Wavelength Routed Optical Networks”. In IEEE INFOCOM, 2003. | |
E. L. V. et. al., “Architecturing the services in an optical network”. IEEE Communications Magazine, vol. 39, no. 9, pp. 80–89, Sep. 2001. | |
F. K. Hwang, D. S. Richards, and P. Winter, “The Steiner Tree Problem”. New York: Elsevier, 1992. | |
F. Zhou, M. Molnar, and B. Cousin, “Is light-tree structure optimal for multicast routing in | |
G. Agrawal and D. Medhi, “Single Shortest Path-based Logical Topologies for Grooming IP Traffic over Wavelength-Routed Networks”. In Proceedings of 2nd IEEE/Create-Net International Workshop on Traffic Grooming, 2005. | |
K. Hastings and N. Nechita, “Challenges and opportunities of delivering IP-based residential television service”. IEEE Communications Magazine, vol. 38, no. 11, pp. 86–92, November 2000 | |
L. Sahasrabuddhe and B. Mukherjee, “Light-trees: Optical multicasting for improved performance in wavelength-routed networks.” IEEE Communications Magazine, vol. 37, no. 2, pp. 67–73, February 1999. | |
M. Jeong, C. Qiao, and Y. Xiong, “Reliable WDM Multicast in Optical Burst-Switched | |
M. Jeong, Y. Xiong, H. C. Cankaya, M. Vandenhoute, and C. Qiao, “Efficient Multicast Schemes for Optical Burst-Switched WDM Networks”. In IEEE ICC, pp. 1289–1294, 2000. | |
M. Mellia, A. Nucci, A. Grosso, E. Leonardi, and M. A. Marsan, “Optimal Design of Logical Topologies in Wavelength-Routed Optical Networks with Multicast Traffic”. in IEEE Globecomm, vol. 3, 2001, pp. 1520–1525. | |
N. K. Singhal and B. Mukherjee, “Protecting Multicast Sessions in WDM Optical Mesh Networks”. Journal of Lightwave Technology, vol. 21, no. 4, April 2003. | |
Pusateri, “DVMRP version 3. draft-ietf-idmr-dvmrp-v3-07”. IETF, August 1998. | |
R. K. Pankaj, “Wavelength requirements for multicasting in all-optical networks”. IEEE/ACM Transactions on Networking, vol. 7, pp. 414–424,1999. | |
R. Karp, “Reducibility among combinatorial problems”. Complexity of Computer | |
R. Malli, X. Zhang, and C. Qiao, “Benefit of Multicasting in All-Optical Networks”. In SPIE | |
S. Bhandari, B.-Y. Choi, and E. K. Park, “Hybrid topology for multicast support in constrained WDM networks”. In Proceedings of 20th International Teletraffic Congress, Ottawa Canada, Jun. 2007. | |
T. Ballardie, P. Francis, and J. Crowcroft, “Core Based Trees (CBT): An Architecture for | |
T. Stern and K. Bala, “Multiwavelength Optical Networks”. Addison Wesley, 1999. | |
X. Zhang, J. Wei, and C. Qao, “Constrained multicast routing in WDM networks with sparse | |
X. Zhang, J. Wei, and C. Qiao, “On Fundamental Issues in IP over WDM Multicast”. In IEEE | |
Dr. Mina Youssef
- United States of America
caterinag@ksu.edu
Mr. Baek-Young Choiz
- United States of America
Dr. Caterina Scoglio
- United States of America
Mr. Eun Kyo Park
- United States of America
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