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Conference Papers Year : 2018

Accurate Characterization of Dynamic Cell Load in Noise-Limited Random Cellular Networks

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Abstract

The analyses of cellular network performance based on stochastic geometry generally ignore the traffic dynamics in the network. This restricts the proper evaluation and di- mensioning of the network from the perspective of a mobile operator. To address the effect of dynamic traffic, recently, the mean cell approach has been introduced, which approximates the average network load by the zero cell load. However, this is not a realistic characterization of the network load, since a zero cell is statistically larger than a random cell drawn from the population of cells, i.e., a typical cell. In this paper, we analyze the load of a noise-limited network characterized by high signal to noise ratio (SNR). The noise-limited assumption can be applied to a variety of scenarios, e.g., millimeter wave networks with efficient interference management mechanisms. First, we provide an analytical framework to obtain the cumulative density function of the load of the typical cell. Then, we obtain two approximations of the average load of the typical cell. We show that our study provides a more realistic characterization of the average load of the network as compared to the mean cell approach. Moreover, the prescribed closed form approximation is more tractable than the mean cell approach.

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Dates and versions

hal-01826682 , version 1 (29-06-2018)

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  • HAL Id : hal-01826682 , version 1

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Gourab Ghatak, Antonio de Domenico, Marceau Coupechoux. Accurate Characterization of Dynamic Cell Load in Noise-Limited Random Cellular Networks. IEEE 88th Vehicular Technology Conference (VTC Fall), Aug 2018, Chicago, United States. pp.1-5. ⟨hal-01826682⟩
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