Author/Authors :
Ullah, Rahat Universiti Teknologi Malaysia - Faculty of Electrical Engineering, Ceneter of Excellence for Telecommunication Technology, Malaysia , Ullah, Rahat Federal Urdu University of Arts Science and Technology - Department of Electrical Engineering, Pakistan , Fisal, Norsheila Universiti Teknologi Malaysia - Faculty of Electrical Engineering, Ceneter of Excellence for Telecommunication Technology, Malaysia , Safdar, Hashim Universiti Teknologi Malaysia - Faculty of Electrical Engineering, Ceneter of Excellence for Telecommunication Technology, Malaysia , Safdar, Hashim Federal Urdu University of Arts Science and Technology - Department of Electrical Engineering, Pakistan , Khalid, Zubair Universiti Teknologi Malaysia - Faculty of Electrical Engineering, Ceneter of Excellence for Telecommunication Technology, Malaysia , Khalid, Zubair Federal Urdu University of Arts Science and Technology - Department of Electrical Engineering, Pakistan , Maqbool, Wajahat Universiti Teknologi Malaysia - Faculty of Electrical Engineering, Ceneter of Excellence for Telecommunication Technology, Malaysia , Ullah, Hanif Federal Urdu University of Arts Science and Technology - Department of Electrical Engineering, Pakistan
Abstract :
Fractional Frequency Reuse (FFR) has been acknowledged as an efficient Interference Management (IM) technique, which offers significant capacity enhancement and improves cell edge coverage with low complexity of implementation. The performance of cellular system greatly depends on the spatial configuration of base stations (BSs). In literature, FFR has been analyzed mostly with cellular networks described by Hexagon Grid Model (HGM). HGM is neither tractable nor scalable to the dense deployment of next generation wireless networks. Moreover, the perfect geometry based HGM tends to overestimate the system s performance and not able to reflect the reality. In this paper, we use the stochastic geometry approach; FFR is analyzed with cellular network modeled by homogeneous Poisson Point Process (PPP). PPP model provides complete randomness in terms of BS deployment, which captures the real network scenario. A dynamic FFR scheme is proposed in this article, which take into account the randomness of the cell coverage area described by Voronoi tessellation. It is shown that the proposed scheme outperforms the traditional fixed frequency allocation schemes in terms of capacity and capacity density.
Keywords :
Interference management , fractional frequency reuse , Long Term Evolution (LTE) , Poisson Point Process
