English

Analysis and Optimization of Sparse Random Linear Network Coding for Reliable Multicast Services

Information Theory 2016-11-17 v2 Multimedia Networking and Internet Architecture Performance math.IT

Abstract

Point-to-multipoint communications are expected to play a pivotal role in next-generation networks. This paper refers to a cellular system transmitting layered multicast services to a multicast group of users. Reliability of communications is ensured via different Random Linear Network Coding (RLNC) techniques. We deal with a fundamental problem: the computational complexity of the RLNC decoder. The higher the number of decoding operations is, the more the user's computational overhead grows and, consequently, the faster the battery of mobile devices drains. By referring to several sparse RLNC techniques, and without any assumption on the implementation of the RLNC decoder in use, we provide an efficient way to characterize the performance of users targeted by ultra-reliable layered multicast services. The proposed modeling allows to efficiently derive the average number of coded packet transmissions needed to recover one or more service layers. We design a convex resource allocation framework that allows to minimize the complexity of the RLNC decoder by jointly optimizing the transmission parameters and the sparsity of the code. The designed optimization framework also ensures service guarantees to predetermined fractions of users. The performance of the proposed optimization framework is then investigated in a LTE-A eMBMS network multicasting H.264/SVC video services.

Keywords

Cite

@article{arxiv.1511.05892,
  title  = {Analysis and Optimization of Sparse Random Linear Network Coding for Reliable Multicast Services},
  author = {Andrea Tassi and Ioannis Chatzigeorgiou and Daniel E. Lucani},
  journal= {arXiv preprint arXiv:1511.05892},
  year   = {2016}
}

Comments

To appear on IEEE Transactions on Communications

R2 v1 2026-06-22T11:48:40.574Z