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

Volume

18

Issue

9

fYear

2014

fDate

Sept. 2014

Firstpage

1575

Lastpage

1578

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;

fLanguage

English

Journal_Title

Communications Letters, IEEE

Publisher

ieee

ISSN

1089-7798

Type

jour

DOI

10.1109/LCOMM.2014.2341251

Filename

6862011