Chemical Reactions-Based Microfluidic Transmitter and Receiver for Molecular Communication

TL;DR

This paper presents a novel microfluidic molecular communication system with chemical reaction-based transmitter and receiver, capable of generating and demodulating pulse-shaped molecular signals for reliable, scalable communication.

Contribution

It introduces a practical microfluidic MC transmitter and receiver design based on chemical reactions, addressing biological process limitations and providing theoretical analysis and validation.

Findings

Successfully generates predefined pulse-shaped molecular signals

Demonstrates reliable demodulation of received signals

Validates system performance through simulations

Abstract

The design of communication systems capable of processing and exchanging information through molecules and chemical processes is a rapidly growing interdisciplinary field, which holds the promise to revolutionize how we realize computing and communication devices. While molecular communication (MC) theory has had major developments in recent years, more practical aspects in designing components capable of MC functionalities remain less explored. Motivated by this, we design a microfluidic MC system with a microfluidic MC transmitter and a microfluidic MC receiver based on chemical reactions. Considering existing MC literature on information transmission via molecular pulse modulation, the proposed microfluidic MC transmitter is capable of generating continuously predefined pulse-shaped molecular concentrations upon rectangular triggering signals using chemical reactions inspired by how cells generate pulse-shaped molecular signals in biology. We further design a microfluidic MC receiver capable of demodulating a received signal to a rectangular output signal using a thresholding reaction and an amplifying reaction. Our chemical reactions-based microfluidic molecular communication system is reproducible and well-designed, and more importantly, it overcomes the slow-speed, unreliability, and non-scalability of biological processes in cells. To reveal design insights, we also derive the theoretical signal responses for our designed microfluidic transmitter and receiver, which further facilitate the transmitter design optimization. Our theoretical results are validated via simulations performed through the COMSOL Multiphysics finite element solver. We demonstrate the predefined nature of the generated pulse and the demodulated rectangular signal together with their dependence on design parameters.