Title :
Stochastic Geometry Modeling of Coverage and Rate of Cellular Networks Using the Gil-Pelaez Inversion Theorem
Author :
Di Renzo, Marco ; Peng Guan
Author_Institution :
Lab. des Signaux et Syst., Univ. Paris-Sud XI, Gif-sur-Yvette, France
Abstract :
In this letter, we introduce new mathematical frameworks to the computation of coverage probability and average rate of cellular networks, by relying on a stochastic geometry abstraction modeling approach. With the aid of the Gil-Pelaez inversion formula, we prove that coverage and rate can be compactly formulated as a twofold integral for arbitrary per-link power gains. In the interference-limited regime, single-integral expressions are obtained. As a case study, Gamma-distributed per-link power gains are investigated further, and approximated closed-form expressions for coverage and rate in the interference-limited regime are obtained, which shed light on the impact of channel parameters and physical-layer transmission schemes.
Keywords :
cellular radio; computational geometry; inverse problems; probability; radiofrequency interference; stochastic processes; Gamma-distributed per-link power gains; Gil-Pelaez inversion theorem; arbitrary per-link power gains; cellular networks average rate; channel parameters; closed-form expressions; coverage probability computation; coverage stochastic geometry modeling; interference-limited regime; physical-layer transmission schemes; single-integral expressions; twofold integral; Approximation methods; Fading; Geometry; Interference; Mathematical model; Monte Carlo methods; Stochastic processes; Cellular networks; Gil-Pelaez theorem; average rate; coverage probability; stochastic geometry;
Journal_Title :
Communications Letters, IEEE
DOI :
10.1109/LCOMM.2014.2341251
