English

Graph Codes for Distributed Instant Message Collection in an Arbitrary Noisy Broadcast Network

Information Theory 2017-02-01 v3 math.IT

Abstract

We consider the problem of minimizing the number of broadcasts for collecting all sensor measurements at a sink node in a noisy broadcast sensor network. Focusing first on arbitrary network topologies, we provide (i) fundamental limits on the required number of broadcasts of data gathering, and (ii) a general in-network computing strategy to achieve an upper bound within factor logN\log N of the fundamental limits, where NN is the number of agents in the network. Next, focusing on two example networks, namely, \textcolor{black}{arbitrary geometric networks and random Erdo¨\ddot{o}s-Reˊ\acute{e}nyi networks}, we provide improved in-network computing schemes that are optimal in that they attain the fundamental limits, i.e., the lower and upper bounds are tight \textcolor{black}{in order sense}. Our main techniques are three distributed encoding techniques, called graph codes, which are designed respectively for the above-mentioned three scenarios. Our work thus extends and unifies previous works such as those of Gallager [1] and Karamchandani~\emph{et. al.} [2] on number of broadcasts for distributed function computation in special network topologies, while bringing in novel techniques, e.g., from error-control coding and noisy circuits, for both upper and lower bounds.

Keywords

Cite

@article{arxiv.1508.01553,
  title  = {Graph Codes for Distributed Instant Message Collection in an Arbitrary Noisy Broadcast Network},
  author = {Yaoqing Yang and Soummya Kar and Pulkit Grover},
  journal= {arXiv preprint arXiv:1508.01553},
  year   = {2017}
}

Comments

60 pages. Submitted for publication

R2 v1 2026-06-22T10:28:14.949Z