Abstract
For broadband cellular access based on orthogonal frequency division multiple access (OFDMA), fractional frequency reuse (FFR) is one of the key concepts for mitigating inter-cell interference and optimizing cell-edge performance. In standard FFR, the number of OFDMA sub-bands and the reuse factor are fixed. Whereas this works well for an idealized cell pattern, it is neither directly applicable nor adequate for real-life networks with irregular cell layouts. In this article, we consider a generalized FFR (GFFR) scheme to allow for flexibility in the total number of sub-bands as well as the number of sub-bands in each cell-edge zone, to enable network-adaptive FFR. In addition, the GFFR scheme takes power assignment in consideration. We formalize the complexity of the optimization problem, and develop an optimization algorithm based on local search to maximize the cell-edge throughput. Numerical results using networks with realistic radio propagation conditions demonstrate the applicability of the GFFR scheme in performance engineering of OFDMA networks.
Highlights
Orthogonal frequency division multiple access (OFDMA) is a current technology for broadband radio access
A generalized fractional frequency reuse (FFR) scheme In this article we present and evaluate a generalized FFR (GFFR) scheme, in order to overcome the limitations of standard FFR in dealing with real-life networks with irregular cell layout
The observation motivates the application of the GFFR scheme
Summary
Orthogonal frequency division multiple access (OFDMA) is a current technology for broadband radio access. The performance metric that we use to assess sub-band allocation and power assignment targets throughput guarantee in the cell-edge zones. The optimized allocation significantly goes beyond the performance of FFR with three sub-bands, which, in its turn, delivers better throughput than reuse1 in cell-edge zones.
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