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Chemical Reactions-Based Microfluidic Transmitter and Receiver Design for Molecular Communication

Research output: Contribution to journalArticlepeer-review

Dadi Bi, Yansha Deng, Massimiliano Pierobon, Arumugam Nallanathan

Original languageEnglish
Article number9090868
Pages (from-to)5590-5605
Number of pages16
JournalIEEE Transactions on Communications
Volume68
Issue number9
Early online date11 May 2020
DOIs
Accepted/In press2 May 2020
E-pub ahead of print11 May 2020
Published30 Sep 2020

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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. This paper designs chemical reactions-based microfluidic devices to realize binary concentration shift keying (BCSK) modulation and demodulation functionalities. Considering existing MC literature on information transmission via molecular pulse modulation, we propose a microfluidic MC transmitter design, which is capable of generating continuously predefined pulse-shaped molecular concentrations upon rectangular triggering signals to achieve the modulation function. 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 its parameters can be optimized. 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.

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