Author(s)

Lijun Li¹, Huanlai Xing², Zhenni Wang¹, Hui Shi¹

¹School of Electronics and Information Engineering, Taiyuan University of Science and Technology, Taiyuan, China.
²School of Information Science and Technology, Southwest Jiaotong University, Chengdu, China.

With the increasing requirements of the multicast services in the whole data traffic service, the optical multicast technology becomes a key technology supporting wide bandwidth and high speed multicasting communication. The transmission efficiency, capacity and robustness of optical multicast network can be further improved by introducing network coding technology into optical multicast networks. Meanwhile, facing to demand of emerging rate-variable multi-granularity multicast service, a multi-path transmission scheme based on network coding for routing and spectrum allocation (RSA) is proposed. It can not only allocate spectrum resources effectively and flexibly for various-rate multicast traffic, but also balance the network load, improve network throughput and reduce transmission blocking rate. In this paper, RSA problem is decomposed into two subproblems, namely routing allocation based on network coding and spectrum allocation based on maximum spectrum first (MSF) strategy, which are solved sequentially. Simulation experiments are carried out to analyze transmission performance with proposed RSA scheme. The simulation results show that the proposed RSA mechanism can allocate spectrum resources efficiently and flexibly for multi-granularity multicast traffic. Compared with RSA schemes based on shortest path tree (SPT) and minimal spanning tree (MST), the proposed RSA scheme is more efficient for spectrum resource utilization and load balancing, and spectrum resource is saved more than 20%.

Optical Multicasting, Elastic Optical Networks, Routing and Spectrum Allocation, Network Coding, Orthogonal Frequency Division Multiplexing

Li, L. , Xing, H. , Wang, Z. and Shi, H. (2018) Elastic Resource Allocation for Multi-Granularity Multicasting Traffic in OFDM-Based Optical Networks. Optics and Photonics Journal, 8, 323-336. doi: 10.4236/opj.2018.811028.