GRD Journals | Global Research and Development Journal for Engineering | International Conference on Innovations in Engineering and Technology (ICIET) - 2016 | July 2016
e-ISSN: 2455-5703
Dynamic Grouping and Frequency Reuse Scheme for Dense Small Cell Network 1B.Sridevi 2R.Shakanapriya 3R.Jeyalakshmi 4P.Saranya 1
Assistant Professor 2,3,4Student Department of Electronics and Communication Engineering 1,2,3,4 Velammal college of engineering and technology, Madurai
1,2,3,4
Abstract Small cell networks have emerged as a key technology in residential, office building or hotspot deployments that can significantly fulfil high data demands in order to offload indoor traffic from outdoor macro cells. However, as one of the major challenges, inter-small cell interference gets worse in some building scenarios because of the presence of numerous interfering sources and then needs to be considered in early network planning phase. Though, penetration loss and complex indoor environment make that it is difficult for existing cellular network to sufficiently follow the demand in indoor mobile traffic. The deployment of small cells is envisioned to be a key solution for providing high wireless data-rates, offloading the macro cell traffic and enhancing the coverage of existing networks. Based on the edge nodes all interfering nodes in the small cells are grouped into number of groups, and then the frequency reuse factor is applied according to the dominance interference strength. Hence the power gets transmitted for different groups according to the interference strength. Simulation results shows, the proposed scheme yields great performance gain in terms of the efficiency relative to the universal frequency reuse. Keyword- In-building small cell networks; frequency reuse __________________________________________________________________________________________________
I. INTRODUCTION Recently, it has been reported that about 80% of wireless communication traffic comes from indoors[1]. The deployment of femtocells is envisioned to be a key solution for providing high wireless data-rates, offloading the macro cell traffic and enhancing the coverage of existing networking [2].Small cells can be densely deployed in a small area such as an office building, hotspot area, or residential area. Nevertheless, an unplanned or random user-installed deployment faces several problems and challenges in terms of interference management and backhaul constraints [3]. In co-channel deployments, all small cells reuse the spectrum resources, and interference from other small cells might significantly deteriorate the overall system performance by multiple dominant interferences, which are from small cells not only on the same floor due to adjacent deployment, but also on the upper and lower floors due to cross-floor signal penetration. Hence, interference modelling used in traditional cellular scenario is not proper in a building environment. Currently, several interference mitigation schemes in macro base station scenario have been widely studied mainly by means of interference randomization, interference control, interference suppress, and interference coordination. In the first class the interference is averaged across the whole spectrum via spreading sequences (e.g. scrambling and interleaving),and therefore is not actually cancelled out. The second class uses the power control and static beam forming to reduce the interference level. But by contrast, in the third class, the interference is successfully suppressed by using advanced signal processing techniques [4]. Although these techniques are becoming popular, however, the complexity at the receiver side and backhaul constraint are still the challenging issues particularly in the presences of multiple dominant interferences. Inter-Cell Interference Coordination (ICIC) techniques [5], on the other hand, present pragmatically a more feasible solution. Unlike the macro base station, small base stations can be installed by users in a random manner, making it difficult to handle the interference problem. The traditional methods can be applied to the mitigation of inter-small cell interference when femtocells are deployed in a systematic way with low density[6]. However, when multiple small cells are densely deployed in a building environment, the interference source will be greatly increased, and the interference scenario will drastically vary due to a large number of dominant random interfering nodes. In order to mitigate the inter-femtocell interference in the dense environment, several methods have been proposed, e.g. Fractional Frequency Reuse(FFR) [7-8], which uses the flexible Frequency Reuse Factors (FRF) in the celledge in the cell- edge area and cell-centre area. But in Ref. [7], dense inter-small cell interference is not specially considered. While in Ref. [8], a small cell can be granted admission into a group only when it interferes with all the small cells already admitted by that group. However, it should be noted that it has high computational complexity and the graph based method is very flexible. Therefore, different admission control criterions can be developed to tune the size of each group, and spectrum resource can be fully used for each group to improve the spectrum efficiency. In this paper, a new soft frequency reuse Scheme is proposed for interference management in dense small cell networks, which was partly presented in Ref. [9]. Based on the Reference Signal Received Power (RSRP) from the serving users, the multiple interfering small cells can be determined to form several groups, and then the minimum sub channels with different soft frequency reuse factors for these groups
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