SIR Coverage Analysis in Multi-Cell Downlink Systems With Spatially Correlated Queues

In this article, we analyze the signal-to-interference ratio (SIR) coverage probability of a multi-cell downlink system with random traffic arrivals. Based on a theoretical model, in which the base stations (BSs) and devices are deployed as independent Poisson point processes (PPPs), we first present the sufficient and necessary conditions of the $\varepsilon $ -stable region for the queueing system. Then, by taking into account the impact of spatially queueing interactions among BSs, we focus on the steady status of the queues and introduce a two-queue-length approximated model for the system. Specifically, in the studied new model, the BSs are separated into two sets in the steady state: the long-queue BS set and the short-queue BS set. The locations of the former are modeled by a Neyman-Scott process and those of the latter are modeled as a residual hole process. By applying the first-order statistic approximation, we further approximate the hole process by a homogeneous PPP with the same density. To model the deployment of the BSs precisely, the related parameters in the approximated model are fitted. Using tools from stochastic geometry and queueing theory, we derive the SIR coverage probability in the steady state. An iterative algorithm is proposed to calculate the active probability of the BSs. To reduce the computational complexity, Beta distribution is applied to approximate the probability density function of the service rate in each iteration of the algorithm. Finally, the effect of the fitting parameters and the accuracy of our analysis are presented via Monte Carlo simulations.

[1]  Sunghyun Choi,et al.  Ultrareliable and Low-Latency Communication Techniques for Tactile Internet Services , 2019, Proceedings of the IEEE.

[2]  Jeffrey G. Andrews,et al.  A Tractable Approach to Coverage and Rate in Cellular Networks , 2010, IEEE Transactions on Communications.

[3]  J. Gil-Pelaez Note on the inversion theorem , 1951 .

[4]  P. Dixon Ripley's K Function , 2006 .

[5]  Raviraj S. Adve,et al.  Handoff Rate and Coverage Analysis in Multi-Tier Heterogeneous Networks , 2015, IEEE Transactions on Wireless Communications.

[6]  John MacLaren Walsh,et al.  Properties of an Aloha-Like Stability Region , 2014, IEEE Transactions on Information Theory.

[7]  Mohamed-Slim Alouini,et al.  Uncoordinated Massive Wireless Networks: Spatiotemporal Models and Multiaccess Strategies , 2019, IEEE/ACM Transactions on Networking.

[8]  Tony Q. S. Quek,et al.  On the Stability of Static Poisson Networks Under Random Access , 2016, IEEE Transactions on Communications.

[9]  M. Cenk Gursoy,et al.  Coverage in Heterogeneous Downlink Millimeter Wave Cellular Networks , 2016, IEEE Transactions on Communications.

[10]  Lajos Hanzo,et al.  A Universal Approach to Coverage Probability and Throughput Analysis for Cellular Networks , 2015, IEEE Transactions on Vehicular Technology.

[11]  Stefan Parkvall,et al.  Ultra-dense networks in millimeter-wave frequencies , 2015, IEEE Communications Magazine.

[12]  Ranjan K. Mallik,et al.  Coverage Probability Analysis in a Device-to-Device Network: Interference Functional and Laplace Transform Based Approach , 2019, IEEE Communications Letters.

[13]  Chun-Hung Liu,et al.  Heterogeneous Networks With Power-Domain NOMA: Coverage, Throughput, and Power Allocation Analysis , 2017, IEEE Transactions on Wireless Communications.

[14]  Sofiène Affes,et al.  Unified Analysis and Optimization of D2D Communications in Cellular Networks Over Fading Channels , 2018, IEEE Transactions on Communications.

[15]  Harpreet S. Dhillon,et al.  Joint Energy and SINR Coverage in Spatially Clustered RF-Powered IoT Network , 2018, IEEE Transactions on Green Communications and Networking.

[16]  Jeffrey G. Andrews,et al.  SINR and Throughput of Dense Cellular Networks With Stretched Exponential Path Loss , 2017, IEEE Transactions on Wireless Communications.

[17]  Tony Q. S. Quek,et al.  Spatio-Temporal Analysis for SINR Coverage in Small Cell Networks , 2019, IEEE Transactions on Communications.

[18]  Wuyang Zhou,et al.  The Ginibre Point Process as a Model for Wireless Networks With Repulsion , 2014, IEEE Transactions on Wireless Communications.

[19]  Lajos Hanzo,et al.  Performance Analysis of Device-to-Device Communication Underlaying Dense Networks (DenseNets) , 2019, IEEE Transactions on Vehicular Technology.

[20]  Walid Saad,et al.  Unmanned Aerial Vehicle With Underlaid Device-to-Device Communications: Performance and Tradeoffs , 2015, IEEE Transactions on Wireless Communications.

[21]  Mohamed-Slim Alouini,et al.  Spatiotemporal Stochastic Modeling of IoT Enabled Cellular Networks: Scalability and Stability Analysis , 2016, IEEE Transactions on Communications.

[22]  Jeffrey G. Andrews,et al.  A Unified Asymptotic Analysis of Area Spectral Efficiency in Ultradense Cellular Networks , 2017, IEEE Transactions on Information Theory.

[23]  Xiaohu Ge,et al.  Heterogeneous Cellular Networks With Spatio-Temporal Traffic: Delay Analysis and Scheduling , 2016, IEEE Journal on Selected Areas in Communications.

[24]  Weihua Zhuang,et al.  Tractable Coverage Analysis for Hexagonal Macrocell-Based Heterogeneous UDNs With Adaptive Interference-Aware CoMP , 2019, IEEE Transactions on Wireless Communications.

[25]  Naoto Miyoshi,et al.  Downlink Coverage Probability in Cellular Networks With Poisson–Poisson Cluster Deployed Base Stations , 2018, IEEE Wireless Communications Letters.

[26]  Martin Haenggi,et al.  Stochastic Geometry for Wireless Networks , 2012 .

[27]  R. M. Loynes,et al.  The stability of a queue with non-independent inter-arrival and service times , 1962, Mathematical Proceedings of the Cambridge Philosophical Society.

[28]  Ivan Atencia,et al.  A Discrete-Time Geo/G/1 Retrial Queue with General Retrial Times , 2004, Queueing Syst. Theory Appl..

[29]  Peter Han Joo Chong,et al.  Modeling and Performance Analysis of Clustered Device-to-Device Networks , 2015, IEEE Transactions on Wireless Communications.