Asymptotics and Approximation of the SIR Distribution in General Cellular Networks

May 09, 2015 Β· Declared Dead Β· πŸ› IEEE Transactions on Wireless Communications

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Authors Radha K. Ganti, Martin Haenggi arXiv ID 1505.02310 Category cs.IT: Information Theory Cross-listed cs.NI, cs.SI, math.PR Citations 95 Venue IEEE Transactions on Wireless Communications Last Checked 4 months ago
Abstract
It has recently been observed that the SIR distributions of a variety of cellular network models and transmission techniques look very similar in shape. As a result, they are well approximated by a simple horizontal shift (or gain) of the distribution of the most tractable model, the Poisson point process (PPP). To study and explain this behavior, this paper focuses on general single-tier network models with nearest-base station association and studies the asymptotic gain both at 0 and at infinity. We show that the gain at 0 is determined by the so-called mean interference-to-signal ratio (MISR) between the PPP and the network model under consideration, while the gain at infinity is determined by the expected fading-to-interference ratio (EFIR). The analysis of the MISR is based on a novel type of point process, the so-called relative distance process, which is a one-dimensional point process on the unit interval [0,1] that fully determines the SIR. A comparison of the gains at 0 and infinity shows that the gain at 0 indeed provides an excellent approximation for the entire SIR distribution. Moreover, the gain is mostly a function of the network geometry and barely depends on the path loss exponent and the fading. The results are illustrated using several examples of repulsive point processes.
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