Digital Signal Processing for Molecular Communication via Chemical-Reaction-Based Microfluidic Circuits

Dadi Bi; Yansha Deng

doi:10.1109/MCOM.001.2000830

Digital Signal Processing for Molecular Communication via Chemical-Reaction-Based Microfluidic Circuits

King's College London

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

Chemical-reaction-based microfluidic circuits are expected to provide new opportunities to perform signal processing functions over the molecular domain. To realize this vision, in this article, we exploit and present the digital signal processing capabilities of chemical-reaction-based microfluid-ic circuits. To facilitate microfluidic circuit design, we describe a microfluidic circuit using a five-level architecture: molecular propagation, chemical transformation, microfluidic modules, microfluidic logic gates, and microfluidic circuits. We first identify the components at Levels 1 and 2, and present how their combinations can build the basic modules for Level 3. We then assemble basic modules to construct five types of logic gates for Level 4, including AND, NAND, OR, NOR, and XOR gates, which show advantages of microfluidic circuits in versatility and modularity. Finally, we discuss challenges and potential solutions for designing, building, and testing microfluidic circuits with complex signal processing functions in Level 5 based on the digital logic gates at Level 4.

Original language	English
Article number	9446679
Pages (from-to)	26-32
Number of pages	7
Journal	IEEE COMMUNICATIONS MAGAZINE
Volume	59
Issue number	5
DOIs	https://doi.org/10.1109/MCOM.001.2000830
Publication status	Published - May 2021

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title = "Digital Signal Processing for Molecular Communication via Chemical-Reaction-Based Microfluidic Circuits",

abstract = "Chemical-reaction-based microfluidic circuits are expected to provide new opportunities to perform signal processing functions over the molecular domain. To realize this vision, in this article, we exploit and present the digital signal processing capabilities of chemical-reaction-based microfluid-ic circuits. To facilitate microfluidic circuit design, we describe a microfluidic circuit using a five-level architecture: molecular propagation, chemical transformation, microfluidic modules, microfluidic logic gates, and microfluidic circuits. We first identify the components at Levels 1 and 2, and present how their combinations can build the basic modules for Level 3. We then assemble basic modules to construct five types of logic gates for Level 4, including AND, NAND, OR, NOR, and XOR gates, which show advantages of microfluidic circuits in versatility and modularity. Finally, we discuss challenges and potential solutions for designing, building, and testing microfluidic circuits with complex signal processing functions in Level 5 based on the digital logic gates at Level 4. ",

author = "Dadi Bi and Yansha Deng",

note = "Funding Information: AcknowledGMent This work was funded by the EPSRC, U.K., under Grant EP/T000937/1. Publisher Copyright: {\textcopyright} 1979-2012 IEEE. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.",

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AB - Chemical-reaction-based microfluidic circuits are expected to provide new opportunities to perform signal processing functions over the molecular domain. To realize this vision, in this article, we exploit and present the digital signal processing capabilities of chemical-reaction-based microfluid-ic circuits. To facilitate microfluidic circuit design, we describe a microfluidic circuit using a five-level architecture: molecular propagation, chemical transformation, microfluidic modules, microfluidic logic gates, and microfluidic circuits. We first identify the components at Levels 1 and 2, and present how their combinations can build the basic modules for Level 3. We then assemble basic modules to construct five types of logic gates for Level 4, including AND, NAND, OR, NOR, and XOR gates, which show advantages of microfluidic circuits in versatility and modularity. Finally, we discuss challenges and potential solutions for designing, building, and testing microfluidic circuits with complex signal processing functions in Level 5 based on the digital logic gates at Level 4.

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Digital Signal Processing for Molecular Communication via Chemical-Reaction-Based Microfluidic Circuits

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