Interference Alignment with Asymmetric Complex Signaling - Settling the Host-Madsen-Nosratinia Conjecture

TL;DR

This paper proves that for almost all complex Gaussian interference channels with constant coefficients, more than 1 degree-of-freedom is achievable, introducing asymmetric complex signaling as a novel method to enhance interference alignment.

Contribution

It settles the Host-Madsen-Nosratinia conjecture by showing at least 1.2 degrees-of-freedom are achievable and introduces asymmetric complex signaling as a new approach.

Findings

Achieves at least 1.2 degrees-of-freedom for almost all channel coefficients.

Introduces asymmetric complex signaling as a novel technique for interference alignment.

Shows 2-user Gaussian X channel reaches 4/3 degrees-of-freedom without time-variations.

Abstract

It has been conjectured by Host-Madsen and Nosratinia that complex Gaussian interference channels with constant channel coefficients have only one degree-of-freedom regardless of the number of users. While several examples are known of constant channels that achieve more than 1 degree of freedom, these special cases only span a subset of measure zero. In other words, for almost all channel coefficient values, it is not known if more than 1 degree-of-freedom is achievable. In this paper, we settle the Host-Madsen-Nosratinia conjecture in the negative. We show that at least 1.2 degrees-of-freedom are achievable for all values of complex channel coefficients except for a subset of measure zero. For the class of linear beamforming and interference alignment schemes considered in this paper, it is also shown that 1.2 is the maximum number of degrees of freedom achievable on the complex Gaussian 3 user interference channel with constant channel coefficients, for almost all values of channel coefficients. To establish the achievability of 1.2 degrees of freedom we introduce the novel idea of asymmetric complex signaling - i.e., the inputs are chosen to be complex but not circularly symmetric. It is shown that unlike Gaussian point-to-point, multiple-access and broadcast channels where circularly symmetric complex Gaussian inputs are optimal, for interference channels optimal inputs are in general asymmetric. With asymmetric complex signaling, we also show that the 2 user complex Gaussian X channel with constant channel coefficients achieves the outer bound of 4/3 degrees-of-freedom, i.e., the assumption of time-variations/frequency-selectivity used in prior work to establish the same result, is not needed.