Achievable DoF Bounds for Cache-Aided Asymmetric MIMO Communications

Abstract

Integrating coded caching (CC) into multiple-input multiple-output (MIMO) communications can significantly enhance the achievable degrees of freedom (DoF) in wireless networks. This paper investigates a practical cache-aided asymmetric MIMO configuration with cache ratio γ, where a server equipped with L transmit antennas communicates with K users, each having Gk receive antennas. We propose three content-aware MIMO-CC strategies: the min-G scheme, which treats the system as symmetric by assuming all users have the same number of antennas, equal to the smallest among them; the Grouping scheme, which maximizes spatial multiplexing gain separately within each user subset at the cost of some global caching gain; and the Phantom scheme, which dynamically redistributes spatial resources using virtual or ``phantom'' antennas at the users, bridging the performance gains of the min-G and Grouping schemes. These strategies jointly optimize the number of users, , and the parallel streams decoded by each user, βk, ensuring linear decodability for all target users. Analytical and numerical results confirm that the proposed schemes achieve significant DoF improvements across various system configurations.