Abstract
We develop a unified framework for the performance analysis of arbitrary-loaded downlink heterogeneous networks (HetNets) in which interfering sources are inherently spatially-correlated. Considering a randomly-deployed multi-tier cellular network comprised of a diverse set of large- and small-cells, we incorporate the notion of load-awareness and spatial correlations in characterizing the activities of base stations (BSs) using binary decision variables. A stochastic geometry-based approach is accordingly employed to systematically develop a bounded expression of ergodic rate with different cellular association and load-balancing strategies. Employing the proposed unified framework hence allows for relaxation of several major limitations in the existing state-of-the-art models, in particular the always-transmitting-BSs, uncorrelated interferers, and Rayleigh fading assumptions. We elaborate on the usefulness of adopting this methodology by providing detailed analysis of the aggregate network interference generated by interdependent load-proportional sources over Nakagami-m fading interfering channels. The analytical formulations are validated through Monte-Carlo (MC) simulations for various scenarios and system settings of interest. We observe that the heavily-adopted fully-loaded model as well as the more recent interference-thinning-based approximations are significantly limited in capturing the actual performance curve. The proposed bounded load-aware model and MC trials reveal several important trends and design guidelines for the practical deployment of HetNets.
Original language | English |
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Pages (from-to) | 4110-4125 |
Number of pages | 15 |
Journal | I E E E Transactions on Communications |
Volume | 62 |
Issue number | 11 |
DOIs | |
Publication status | Published - Nov 2014 |
Keywords
- Downlink heterogeneous networks, stochastic geometry, point processes, spatial correlations, loadawareness, cell selection strategies, aggregate network interference, Monte-Carlo simulations