Abstract

Joint network-channel codes (JNCC) can improve the performance of communication in wireless networks, by combining, at the physical layer, the channel codes and the network code as an overall error-correcting code. JNCC is increasingly proposed as an alternative to a standard layered construction, such as the OSI-model. The main performance metrics for JNCCs are scalability to larger networks and error rate. The diversity order is one of the most important parameters determining the error rate. The literature on JNCC is growing, but a rigorous diversity analysis is lacking, mainly because of the many degrees of freedom in wireless networks, which makes it very hard to prove general statements on the diversity order. In this article, we consider a network with slowly varying fading point-to-point links, where all sources also act as relay and additional non-source relays may be present. We propose a general structure for JNCCs to be applied in such network. In the relay phase, each relay transmits a linear transform of a set of source codewords. Our main contributions are the proposition of an upper and lower bound on the diversity order, a scalable code design and a new lower bound on the word error rate to assess the performance of the network code. The lower bound on the diversity order is only valid for JNCCs where the relays transform only two source codewords. We then validate this analysis with an example which compares the JNCC performance to that of a standard layered construction. Our numerical results suggest that as networks grow, it is difficult to perform significantly better than a standard layered construction, both on a fundamental level, expressed by the outage probability, as on a practical level, expressed by the word error rate.

Highlights

  • Point-to-point communication has revealed many of its secrets

  • In Section ‘Diversity analysis of Joint network-channel codes (JNCC)’, we perform a diversity analysis, leading to an upper bound on the diversity order of any linear binary JNCC following our system model, and to a lower bound on the diversity order for a particular subset of linear binary JNCCs

  • We propose an upper and lower bound on the diversity order, a scalable code design and a new lower bound on the word error rate that is tighter than the outage probability and better suited to assess the performance of the overall error-correcting code

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Summary

Introduction

Point-to-point communication has revealed many of its secrets. Driven by new applications, research in wireless communication is focusing more on the optimization of communication in wireless networks. The main contributions are summarized in the lemmas, propositions and corollaries These can be a guide for any coding theorist designing JNCCs. Further, our numerical results suggest that as networks grow, it is difficult to perform significantly better than a standard layered construction, both on a fundamental level, expressed by the outage probability, as on a practical level, expressed by the word error rate. This article extends the study, published in [18], by considering non-perfect source-relay channels, by considerably extending the diversity analysis, by providing an achievability proof for the diversity order of the proposed JNCC, by clearly indicating the set of wireless networks where the proposed JNCC is diversity-optimal, by providing a tighter lower bound on the word error rate, and by providing more numerical results

H11 H21 H1
System model
Diversity as a function of the network coding rate
Space diversity by cooperation
Diversity order with interuser failures
Diversity order in a layered construction
Second step
Calculation of the outage probability
Perfect source-relay links
Findings
Conclusion

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