Scaling Laws of Dense Multi-Antenna Cellular Networks

Abstract

We study the scaling laws of the signal-to-interference-plus-noise ratio (SINR) and the area spectral efficiency (ASE) in multi-antenna cellular networks, where the number of antennas scales with the base station (BS) spatial density λ, under the assumption of independent and identically distributed (i.i.d.) channels. We start with the MISO case with Nt(λ) transmit antennas and a single receive antenna and prove that the average SINR scales as Nt(λ)λ and the average ASE scales as λ(1+Nt(λ)λ). For the MIMO case with single-stream eigenbeamforming and Nr(λ) ≤ Nt(λ) receive antennas, we prove that the scaling laws of the conditional SINR and ASE are agnostic to Nr(λ) and scale exactly the same as the MISO case. Hence, deploying multi-antenna BSs can help maintain non-zero per-user throughput and a corresponding linear increase in the ASE in dense cellular networks.