Abstract
Hierarchical femtocellular architectures have become popular recently because of their potential to provide increased coverage and capacity in cellular systems. However, introduction of femtocells might reduce the overlay macrocellular system performance due to increased interference caused to macrocellular users. In this article, two MIMO precoding techniques are considered at the femtocellular base stations (FBSs) to control the interference to the macrocellular users: precoding matrix index (PMI), and least interference (LI). With MIMO precoding, the limited CSI at the transmitter is the index of the precoder chosen from the codebook fed back by the receiver. The LI technique can be employed at the FBSs to maximize the macrocellular throughput, but it also results in significant reduction in femtocellular throughput. The PMI approach can maximize the signal power at a desired receiver, with minimal feedback. In this article, we develop algorithms that adapt at the FBSs between the LI and PMI schemes to increase both the macrocellular and femtocellular throughputs. We show that allowing for mode adaptation at each FBS improves the system performance when compared with using the same mode across the system, and a simple binary choice at each FBS can nearly achieve the optimum mode-adaptation performance. Analysis and simulation results in a multicell environment are presented to illustrate the improvement in system performance with the proposed techniques.
Highlights
A femtocell is a low-power, user-deployed base station designed for indoor use
The L-bit index of this codeword could be fed back to each femtocellular base stations (FBSs) through a local connection. This method can maximize the signal power with a given codebook and, maximize the femtocellular throughput; on the other hand, the macrocellular throughput might be reduced significantly because the interference generated to the MUE is not considered in the optimization in (6)
Performance with ZF applied at the FBSs is fairly good, because here we assume each FBS is equipped with four transmit antennas and it is only necessary to eliminate the interference generated to the MUE in the same macrocell; the rest of the degrees of freedom can be utilized to increase the signal power at the FUE
Summary
A femtocell is a low-power, user-deployed base station designed for indoor use. Because of their potential to provide improvement in coverage and capacity [1,2,3], femtocells have attracted much attention recently. This method can maximize the signal power with a given codebook and, maximize the femtocellular throughput; on the other hand, the macrocellular throughput might be reduced significantly because the interference generated to the MUE is not considered in the optimization in (6).
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