Close-Form Design of Antenna-Constrained Multi-Cell Multi-User Downlink Interference Alignment

This paper investigates the downlink channels in multi-cell multi-user interfering networks. The goal is to propose close-form designs to obtain degrees of freedom (DoF) in high SNR region for the network composed of base stations (BS) as transmitters and mobile stations (MS) as receivers. Consider the realistic system, both BS and MS have finite antennas, so that the design of interference alignment is highly constrained by the feasibility conditions. The focus of design is to explore potential opportunities of alignment in the subspace both from the BS transmit side and from the MS receive side. The new IA schemes for cellular downlink channels are in the form of causal dynamic processes in contrary to conventional static IA schemes. For different implementations, system conditions are compared from all aspects, which include antenna usage, CSI overhead and computational complexity. This research scope covers a wide range of typical multi-cell multi-user network models. The first one is a $K$-cell fully connected cellular network; the second one is a Wyner cyclic cellular network with two adjacent interfering links; the third one is a Wyner cyclic cellular network with single adjacent interfering link considering cell-edge and cell-interior users respectively.