Can Electromagnetic Information Theory Improve Wireless Systems? A Channel Estimation Example

Electromagnetic information theory (EIT) is an emerging interdisciplinary subject that integrates classical Maxwell electromagnetics and Shannon information theory. The goal of EIT is to uncover the information transmission mechanisms from an electromagnetic (EM) perspective in wireless systems. Existing works on EIT are mainly focused on the analysis of EM channel characteristics, degrees-of-freedom, and system capacity. However, these works do not clarify whether EIT can improve wireless communication systems. To fill in this gap, in this paper, we provide a novel example that EIT can improve the performance of classical minimum mean squared error (MMSE) channel estimators by replacing the channel covariance matrix with an EM correlation function (EMCF). Specifically, by averaging the solutions of Maxwell's equations over a tunable angular distribution, we obtain a spatio-temporal correlation function (STCF) of the EM channel, which we name as the EMCF. Since classical MMSE estimators can exploit prior information contained in the channel covariance matrix, the substitution of EMCF for the covariance matrix introduces EM side information into MMSE estimators. Furthermore, we dynamically tune the EMCF parameters to better fit the channel observations. Simulation results show that the proposed EIT-MMSE channel estimator outperforms traditional MMSE estimators, thus proving that EIT is beneficial to wireless communication systems.