Analysis of Receiver Covered by Heterogeneous Receptors in Molecular Communications

TL;DR

This paper provides an analytical framework for understanding how heterogeneous receptor configurations on an absorbing receiver affect molecule absorption in molecular communication, validated by simulations.

Contribution

It introduces a novel analytical model for the channel impulse response considering heterogeneous receptor sizes and locations, applicable to various receptor configurations.

Findings

Absorbed molecules increase with more receptors when total receptor area is fixed.

Evenly distributed receptors maximize molecule absorption.

Model validated through particle-based simulations.

Abstract

This paper analyzes the channel impulse response of an absorbing receiver (RX) covered by multiple non-overlapping heterogeneous receptors with different sizes and arbitrary locations in a molecular communication system. In this system, a point transmitter (TX) is assumed to be uniformly located on a virtual sphere at a fixed distance from the RX. Considering molecule degradation during the propagation from the TX to the RX, the expected molecule hitting rate at the RX over varying locations of the TX is analyzed as a function of the size and location of each receptor. Notably, this analytical result is applicable for different numbers, sizes, and locations of receptors, and its accuracy is demonstrated via particle-based simulations. Numerical results show that (i) the expected number of absorbed molecules at the RX increases with an increasing number of receptors, when the total area of receptors on the RX surface is fixed, and (ii) evenly distributed receptors lead to the largest expected number of absorbed molecules.