Add to ORKGWhile analyzing mobile systems we often approximate the actual coverage surface and assume an ideal cell shape. In a multi-cellular network, because of its tessellating nature, a hexagon is more preferred than a circular geometry. Despite this reality, perhaps due to the inherent simplicity, only a model for circular based random spreading is available. However, if used, this results an unfair terminal distribution for non-circular contours. Therefore, in this paper we specifically derived an unbiased node density model for a hexagon. We then extended the principle and established stochastic ways to handle sectored cells. Next, based on these mathematical findings, we created a generic modeling tool that can support a complex network with v...
In literature, a stochastic model for spreading nodes in a cellular cell is available. Despite its e...
Abstract—The cellular uplink has typically been studied using simple Wyner-type analytical models wh...
In this article, we prove that under stocastic geometry modeling, the coverage probability of cellul...
The growing demand for network capacity due to mobile devices and data-hungry applications has promp...
Recently, tools from stochastic geometry have gained much attention for modeling and analysis of den...
textThe increasing complexity of heterogeneous cellular networks (HetNets) due to the irregular depl...
Multi-cell cooperation is a promising approach for mitigating inter-cell interference in dense cellu...
A random walk model of mobile cellular network is essential for analysis of roaming and handover of ...
Abstract—In industry, cellular tower locations have primarily been modeled by a deterministic hexago...
Different types of random walk models are prevalent in mobile cellular network for analysis of roami...
International audienceModeling and simulation of a cellular network typically assumes that the targe...
Abstract—A recent way to model and analyze downlink cellular networks is by using random spatial mod...
Abstract—Random spatial models are attractive for modeling heterogeneous cellular networks (HCNs) du...
Abstract—Random spatial models are attractive for modeling heterogeneous cellular networks (HCNs) du...
User mobility in cellular networks deployed in finite areas, results in the non-uniform spatial dist...
In literature, a stochastic model for spreading nodes in a cellular cell is available. Despite its e...
Abstract—The cellular uplink has typically been studied using simple Wyner-type analytical models wh...
In this article, we prove that under stocastic geometry modeling, the coverage probability of cellul...
The growing demand for network capacity due to mobile devices and data-hungry applications has promp...
Recently, tools from stochastic geometry have gained much attention for modeling and analysis of den...
textThe increasing complexity of heterogeneous cellular networks (HetNets) due to the irregular depl...
Multi-cell cooperation is a promising approach for mitigating inter-cell interference in dense cellu...
A random walk model of mobile cellular network is essential for analysis of roaming and handover of ...
Abstract—In industry, cellular tower locations have primarily been modeled by a deterministic hexago...
Different types of random walk models are prevalent in mobile cellular network for analysis of roami...
International audienceModeling and simulation of a cellular network typically assumes that the targe...
Abstract—A recent way to model and analyze downlink cellular networks is by using random spatial mod...
Abstract—Random spatial models are attractive for modeling heterogeneous cellular networks (HCNs) du...
Abstract—Random spatial models are attractive for modeling heterogeneous cellular networks (HCNs) du...
User mobility in cellular networks deployed in finite areas, results in the non-uniform spatial dist...
In literature, a stochastic model for spreading nodes in a cellular cell is available. Despite its e...
Abstract—The cellular uplink has typically been studied using simple Wyner-type analytical models wh...
In this article, we prove that under stocastic geometry modeling, the coverage probability of cellul...