A Simulation Framework for Evaluating Interference Mitigation Techniques in Heterogeneous Cellular Environments
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Abstract
Femtocells present an attractive solution for the improvement of a mobile network’s services providing better data rates and coverage. Since their deployment results to a heterogeneous network where two layers must utilize the available spectrum, issues of interference arise. A method to address this challenge, is investigating the locations of the newly installed FBS, and enforcing a power controlled transmission of all FBSs that achieves optimal and fair overall performance. Another option that becomes available in inter-cell interference cancellation (ICIC) macrocell environments, is utilizing the available spectrum to complete or partly avoid co-channel operation. In this work, we provide a simulation framework that allows the creation of custom, high configurable, user defined topologies of femtocells with power control and frequency allocation capabilities. It allows the investigation of the margin of improvement in interference when these methods are applied and may work as a decision tool for planning and evaluating heterogeneous networks. To showcase the framework’s capabilities, we evaluate and study the behaviour of custom deployed femtocells/macrocells networks and examine the cross-tier interference issues. Facilitated by the framework, we enforce and evaluate each interference mitigation technique for different femtocells’ deployment densities. Finally, we compare the results of each method in terms of total throughput, spectral efficiency and cell-edge users’ performance.
Keywords
Femtocells Cellular networks Interference mitigation Heterogeneous network LTE-A Power control ICICAbbreviations
- ABS
Almost blank subframes
- BS
Base station
- CSG
Closed subscriber group
- FBSs
Femto base stations
- 4G
Fourth generation
- FFR
Fractional frequency reuse
- HNBs
Home node-B
- IFR3
IFR of factor 3
- IFR
Integer frequency reuse
- ICIC
Inter-cell interference cancellation ICIC
- LTE-A
Long term evolution-advanced
- MBS
Macro base station
- OFDMA
Orthogonal frequency-division multiple access
- SINR
Signal to interference plus noise ratio
- SFR
Soft frequency reuse
- PL
Path loss
- RSRP
Reference signal received power
- UE
User equipment
- UBPC
Utility-based power control
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