Communication via Holomorphic Green Functions

TL;DR

This paper introduces a complex spacetime Green function model for extended emitters and receivers, representing antenna dishes with directional and temporal characteristics, ensuring causality and analyzing communication efficiency.

Contribution

It extends the classical Green function to complex spacetime to model realistic antenna dishes with directionality and duration, preserving causality and analyzing communication efficiency.

Findings

Holomorphic Green function models antenna dishes with directionality.

Causality is preserved through future cone constraints.

Communication efficiency is bounded by emission and reception components.

Abstract

Let G(x_r-x_e) be the causal Green function for the wave equation in four spacetime dimensions, representing the signal received at the spacetime point x_r due to an impulse emitted at the spacetime point x_e. Such emission and reception processes are highly idealized, since no signal can be emitted or received at a single (mathematical) point in space and time. We present a simple model for \sl extended \rm emitters and receivers by extending G analytically to a function \tilde G(z_r- z_e), where z_e=x_e+iy_e is a complex spacetime point representing a circular \sl pulsed-beam emitting antenna dish \rm centered at x_e and emitting in the direction of y_e, and z_r=x_r-iy_r represents a circular \sl pulsed-beam receiving antenna dish \rm centered at x_r and receiving from the direction of y_r. The holomorphic Green function \tilde G(z_r-z_e) represents the \sl coupling \rm between the emission from z_e and the reception at z_r. To preserve causality and give nonsingular coupling, the orientation vectors y_e and y_r must belong to the \sl future cone \rm V_+ in spacetime. Equivalently, z_e and z_r belong to the \sl future and past tubes \rm in complex spacetime, respectively. The space coordinates of y_e and y_r give the spatial orientations and radii of the dishes, while their time coordinates determine the \sl duration and focus \rm of the emission and reception processes. The \sl directivity \rm D(y) of the communication process is a convex function on V_+, i.e., D(y_r+y_e)\le D(y_r)+D(y_r). This shows that the efficiency of the communication can be no better than the sum of its emission and reception components.