1 research outputs found
A Number Theoretic Approach for Fast Discovery of Single-Hop Wireless Networks
Interference management has become a key factor in regulating transmissions
in wireless communication networks. To support effective interference
management schemes, it can be essential to have prior knowledge about the
network topology. In this paper, we build on existing results in the literature
on the simulation of the message passing model, and present an efficient
strategy for fast discovery of the network topology during a pilot
communication phase. More precisely, we investigate the minimum number of
communication rounds that is needed to discover an arbitrary network topology
with a maximum number of links per receiver, while assuming a single-hop
network that is restricted to interference-avoidance based schemes in its pilot
phase. We first ignore any interference cancellation strategy such that no
receiver can recognize, and cancel transmissions of, previously discovered
transmitters, and then capture the gains obtained through interference
cancellation during the pilot phase. Our results evince how the required number
of rounds scale in an approximately logarithmic fashion with practical values
of the total number of users in the network, having a slope proportional to the
number of interfering transmitters per receiver.Comment: 4 pages, 6 figure