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Transient characterization of concentration-encoded molecular communication with sinusoidal stimulation

Published: 26 October 2011 Publication History

Abstract

In this paper we present an analysis of transient loss and detection noise margin of a molecular communication system based on sinusoidal stimulation. The molecular propagation channel is based on ideal diffusion of molecules. A set of possible performance metrics has been proposed and their characteristics have been analyzed for various operating frequencies of the stimulation. Transient loss and detection noise margin have shown a significant dependence on communication range and operating frequency in a noiseless channel. Finally, the effectiveness of the metrics in a frequency-shift keying (FSK) modulated scheme has been explained.

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M. U. Mahfuz, D. Makrakis, H. Mouftah, "Spatiotemporal Distribution and Modulation Schemes for Concentration-Encoded Medium-To-Long Range Molecular Communication," in Proc. IEEE QBSC, Canada, 12--14 May, 2010.
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Lánsky, P., V. Krivan, J. Rospars, "Ligand-receptor interaction under periodic stimulation: a modeling study of concentration chemoreceptors," European Biophysics Journal, 30: 110--120, 2001.
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Cited By

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  • (2017)Concentration-Encoded Molecular Communication in Nanonetworks. Part 2: Performance EvaluationModeling, Methodologies and Tools for Molecular and Nano-scale Communications10.1007/978-3-319-50688-3_2(35-56)Online publication date: 16-Mar-2017
  • (2017)Concentration-Encoded Molecular Communication in Nanonetworks. Part 1: Fundamentals, Issues, and ChallengesModeling, Methodologies and Tools for Molecular and Nano-scale Communications10.1007/978-3-319-50688-3_1(3-34)Online publication date: 16-Mar-2017
  • (2015)A Comprehensive Analysis of Strength-Based Optimum Signal Detection in Concentration-Encoded Molecular Communication With Spike TransmissionIEEE Transactions on NanoBioscience10.1109/TNB.2014.236859314:1(67-83)Online publication date: Jan-2015
  • Show More Cited By

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    ISABEL '11: Proceedings of the 4th International Symposium on Applied Sciences in Biomedical and Communication Technologies
    October 2011
    949 pages
    ISBN:9781450309134
    DOI:10.1145/2093698
    Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

    Sponsors

    • Universitat Pompeu Fabra
    • IEEE
    • Technical University of Catalonia Spain: Technical University of Catalonia (UPC), Spain
    • River Publishers: River Publishers
    • CTTC: Technological Center for Telecommunications of Catalonia
    • CTIF: Kyranova Ltd, Center for TeleInFrastruktur

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    Association for Computing Machinery

    New York, NY, United States

    Publication History

    Published: 26 October 2011

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    Author Tags

    1. concentration encoding
    2. molecular communication
    3. sinusoidal transmission rate
    4. transient response

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    ISABEL '11
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    • Technical University of Catalonia Spain
    • River Publishers
    • CTTC
    • CTIF

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    View all
    • (2017)Concentration-Encoded Molecular Communication in Nanonetworks. Part 2: Performance EvaluationModeling, Methodologies and Tools for Molecular and Nano-scale Communications10.1007/978-3-319-50688-3_2(35-56)Online publication date: 16-Mar-2017
    • (2017)Concentration-Encoded Molecular Communication in Nanonetworks. Part 1: Fundamentals, Issues, and ChallengesModeling, Methodologies and Tools for Molecular and Nano-scale Communications10.1007/978-3-319-50688-3_1(3-34)Online publication date: 16-Mar-2017
    • (2015)A Comprehensive Analysis of Strength-Based Optimum Signal Detection in Concentration-Encoded Molecular Communication With Spike TransmissionIEEE Transactions on NanoBioscience10.1109/TNB.2014.236859314:1(67-83)Online publication date: Jan-2015
    • (2014)A Comprehensive Study of Sampling-Based Optimum Signal Detection in Concentration-Encoded Molecular CommunicationIEEE Transactions on NanoBioscience10.1109/TNB.2014.234169313:3(208-222)Online publication date: Sep-2014
    • (2014)Strength-based optimum signal detection in concentration-encoded pulse-transmitted OOK molecular communication with stochastic ligand-receptor bindingSimulation Modelling Practice and Theory10.1016/j.simpat.2013.11.00542(189-209)Online publication date: Mar-2014
    • (2013)A generalized strength-based signal detection model for concentration-encoded molecular communicationProceedings of the 8th International Conference on Body Area Networks10.4108/icst.bodynets.2013.253560(461-467)Online publication date: 30-Sep-2013
    • (2013)Performance Analysis of Convolutional Coding Techniques in Diffusion-Based Concentration-Encoded PAM Molecular Communication SystemsBioNanoScience10.1007/s12668-013-0086-53:3(270-284)Online publication date: 17-May-2013

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