Molecular Communication.
Nakano, Tadashi.
Molecular Communication. - Cambridge : Cambridge University Press, (c)2013. - 1 online resource (194 pages)
Includes bibliographies and index.
Cover; Half Title; Copyright; Title; Contents; Preface; 1 Introduction; 1.1 Molecular communication: Why, what, and how?; 1.1.1 Why molecular communication?; 1.1.2 What uses molecular communication?; 1.1.3 How does it work? A quick introduction; 1.2 A history of molecular communication; 1.2.1 Early history and theoretical research; 1.2.2 More recent theoretical research; 1.2.3 Implementational aspects; 1.2.4 Contemporary research; 1.3 Applications areas; 1.3.1 Biological engineering; 1.3.2 Medical and healthcare applications; 1.3.3 Industrial applications; 1.3.4 Environmental applications. 1.3.5 Information and communication technology applications1.4 Rationale and organization of the book; References; 2 Nature-made biological nanomachines; 2.1 Protein molecules; 2.1.1 Molecular structure; 2.1.2 Functions and roles; 2.2 DNA and RNA molecules; 2.2.1 Molecular structure; 2.2.2 Functions and roles; 2.3 Lipid membranes and vesicles; 2.3.1 Molecular structure; 2.3.2 Functions and roles; 2.4 Whole cells; 2.5 Conclusion and summary; References; 3 Molecular communication in biological systems; 3.1 Scales of molecular communication; 3.2 Modes of molecular communication. 3.3 Examples of molecular communication3.3.1 Chemotactic signaling; 3.3.2 Vesicular trafficking; 3.3.3 Calcium signaling; 3.3.4 Quorum sensing; 3.3.5 Bacterial migration and conjugation; 3.3.6 Morphogen signaling; 3.3.7 Hormonal signaling; 3.3.8 Neuronal signaling; 3.4 Conclusion and summary; References; 4 Molecular communication paradigm; 4.1 Molecular communication model; 4.2 General characteristics; 4.2.1 Transmission of information molecules; 4.2.2 Information representation; 4.2.3 Slow speed and limited range; 4.2.4 Stochastic communication; 4.2.5 Massive parallelization. 4.2.6 Energy efficiency4.2.7 Biocompatibility; 4.3 Molecular communication network architecture; 4.3.1 Physical layer; 4.3.2 Link layer; 4.3.3 Network layer; 4.3.4 Upper layers and other issues; 4.4 Conclusion and summary; References; 5 Mathematical modeling and simulation; 5.1 Discrete diffusion and Brownian motion; 5.1.1 Environmental assumptions; 5.1.2 The Wiener process; 5.1.3 Markov property; 5.1.4 Wiener process with drift; 5.1.5 Multi-dimensional Wiener processes; 5.1.6 Simulation; 5.2 Molecular motors; 5.3 First arrival times; 5.3.1 Definition and closed-form examples. 5.3.2 First arrival times in multiple dimensions5.3.3 From first arrival times to communication systems; 5.4 Concentration, mole fraction, and counting; 5.4.1 Small numbers of molecules: Counting and inter-symbol interference; 5.4.2 Large numbers of molecules: Towards concentration; 5.4.3 Concentration: random and deterministic; 5.4.4 Concentration as a Gaussian random variable; 5.4.5 Concentration as a random process; 5.4.6 Discussion and communication example; 5.5 Models for ligand-receptor systems; 5.5.1 Mathematical model of a ligand-receptor system; 5.5.2 Simulation.
A comprehensive guide written by pioneers in the field, providing a detailed introduction to the state of the art in molecular communication.
9781107291218 9781107289611 9781461944973 9781139149693
Molecular communication (Telecommunication)
Molecules.
Nanotechnology.
Molecular communication (Telecommunication)
Molecules.
Nanotechnology.
Electronic Books.
TK / .M654 2013
Molecular Communication. - Cambridge : Cambridge University Press, (c)2013. - 1 online resource (194 pages)
Includes bibliographies and index.
Cover; Half Title; Copyright; Title; Contents; Preface; 1 Introduction; 1.1 Molecular communication: Why, what, and how?; 1.1.1 Why molecular communication?; 1.1.2 What uses molecular communication?; 1.1.3 How does it work? A quick introduction; 1.2 A history of molecular communication; 1.2.1 Early history and theoretical research; 1.2.2 More recent theoretical research; 1.2.3 Implementational aspects; 1.2.4 Contemporary research; 1.3 Applications areas; 1.3.1 Biological engineering; 1.3.2 Medical and healthcare applications; 1.3.3 Industrial applications; 1.3.4 Environmental applications. 1.3.5 Information and communication technology applications1.4 Rationale and organization of the book; References; 2 Nature-made biological nanomachines; 2.1 Protein molecules; 2.1.1 Molecular structure; 2.1.2 Functions and roles; 2.2 DNA and RNA molecules; 2.2.1 Molecular structure; 2.2.2 Functions and roles; 2.3 Lipid membranes and vesicles; 2.3.1 Molecular structure; 2.3.2 Functions and roles; 2.4 Whole cells; 2.5 Conclusion and summary; References; 3 Molecular communication in biological systems; 3.1 Scales of molecular communication; 3.2 Modes of molecular communication. 3.3 Examples of molecular communication3.3.1 Chemotactic signaling; 3.3.2 Vesicular trafficking; 3.3.3 Calcium signaling; 3.3.4 Quorum sensing; 3.3.5 Bacterial migration and conjugation; 3.3.6 Morphogen signaling; 3.3.7 Hormonal signaling; 3.3.8 Neuronal signaling; 3.4 Conclusion and summary; References; 4 Molecular communication paradigm; 4.1 Molecular communication model; 4.2 General characteristics; 4.2.1 Transmission of information molecules; 4.2.2 Information representation; 4.2.3 Slow speed and limited range; 4.2.4 Stochastic communication; 4.2.5 Massive parallelization. 4.2.6 Energy efficiency4.2.7 Biocompatibility; 4.3 Molecular communication network architecture; 4.3.1 Physical layer; 4.3.2 Link layer; 4.3.3 Network layer; 4.3.4 Upper layers and other issues; 4.4 Conclusion and summary; References; 5 Mathematical modeling and simulation; 5.1 Discrete diffusion and Brownian motion; 5.1.1 Environmental assumptions; 5.1.2 The Wiener process; 5.1.3 Markov property; 5.1.4 Wiener process with drift; 5.1.5 Multi-dimensional Wiener processes; 5.1.6 Simulation; 5.2 Molecular motors; 5.3 First arrival times; 5.3.1 Definition and closed-form examples. 5.3.2 First arrival times in multiple dimensions5.3.3 From first arrival times to communication systems; 5.4 Concentration, mole fraction, and counting; 5.4.1 Small numbers of molecules: Counting and inter-symbol interference; 5.4.2 Large numbers of molecules: Towards concentration; 5.4.3 Concentration: random and deterministic; 5.4.4 Concentration as a Gaussian random variable; 5.4.5 Concentration as a random process; 5.4.6 Discussion and communication example; 5.5 Models for ligand-receptor systems; 5.5.1 Mathematical model of a ligand-receptor system; 5.5.2 Simulation.
A comprehensive guide written by pioneers in the field, providing a detailed introduction to the state of the art in molecular communication.
9781107291218 9781107289611 9781461944973 9781139149693
Molecular communication (Telecommunication)
Molecules.
Nanotechnology.
Molecular communication (Telecommunication)
Molecules.
Nanotechnology.
Electronic Books.
TK / .M654 2013