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100   $a20110513d2011      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aMicrosystems for bioelectronics $ethe nanomorphic cell /$fVictor V. Zhirnov, Ralph K. Cavin III
205   $a1st ed.
210   $aAmsterdam ;$aBoston $cWilliam Andrew/Elsevier$d2011
215   $a1 online resource (209 p.)
225 1 $aMicro & nano technologies series
300   $aDescription based upon print version of record.
311 08$a9781437778403 
311 08$a1437778402 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Microsystems for Bioelectronics; Copyright; Contents; Preface; Acknowledgment; Chapter 1 The nanomorphic cell; 1.1 Introduction; 1.2 Electronic scaling; 1.3 Nanomorphic cell; 1.4 Current status of technologies for autonomous microsystems; 1.5 Concluding remarks; References; Chapter 2 Energy in the small: Integrated micro-scale energy sources; 2.1 Introduction; 2.2 Electrochemical energy: Fundamentals of galvanic cells and supercapacitors; 2.3 Energy from radioisotopes; 2.4 Remarks on energy harvesting; 2.5 Summary; Appendix: A kinetic model to assess the limits of heat removal
327   $aList of symbolsReferences; Chapter 3 Nanomorphic electronics; 3.1 Introduction; 3.2 Information and information processing; 3.3 Basic physics of binary elements; 3.4 System-level analysis; 3.5 Summary; Appendix 1: Quantum confinement; Appendix 2: Derivation of electron travel time (Eq. 3.55); List of symbols; References; Chapter 4 Sensors at the micro-scale; 4.1 Introduction; 4.2 Sensor basics; 4.3 Analog signal; 4.4 Fundamental sensitivity limit of sensors: Thermal noise; 4.5 What information can be obtained from cells?; 4.6 Sensors of bioelectricity; 4.7 Chemical and biochemical sensors
327   $a4.8 Thermal biosensors4.9 Concluding remarks; Glossary of biological terms; List of symbols; References; Chapter 5 Nanomorphic cell communication unit; 5.1 Introduction; 5.2 Electromagnetic radiation; 5.3 Basic RF communication system; 5.4 EM Transducer: A linear antenna; 5.5 Free-space single-photon limit for energy in EM communication; 5.6 Thermal noise limit on communication spectrum; 5.7 The THz communication option (? = 100 ?m); 5.8 Wireless communication for biomedical applications; 5.9 Optical wavelength communication option ?~1 ?m); 5.10 Status of ?-scaled LEDs and PDs
327   $a5.11 Concluding remarksList of symbols; References; Chapter 6 Micron-sized systems: In carbo vs. in silico; 6.1 Introduction; 6.2 Information: A quantitative treatment; 6.3 Abstract information processors; 6.4 In silico and in carbo systems: A design perspective; 6.5 In carbo long-term memory: Storing information in DNA; 6.6 In carbo logic information procession; 6.7 In carbo sensors; 6.8 In carbo communication; 6.9 In carbo energy source; 6.10 Benchmark in carbo information processor; 6.11 Summary; Appendix: Choice of probability values to maximize the entropy function; List of symbols
327   $aReferencesConcluding remarks; Index
330   $a Microsystems for Bioelectronics is the ultimate guide in the biomedical application industry. It provides a physics-based assessment of the limitless potential of miniaturization technologies. This book goes far beyond the complete design of the final systems. It also discusses the developments of computation and communication subsystems. The future of this technology lies in understanding the scaling limits for the individual systems. This includes all of its components and the fundamental energy source that powers all autonomous microsystems.   Rapid advances in microfabrication te
410  0$aMicro & nano technologies.
606   $aMedical electronics
606   $aNanomedicine
606   $aBioelectronics
615  0$aMedical electronics.
615  0$aNanomedicine.
615  0$aBioelectronics.
676   $a610.28/4
700   $aZhirnov$b Victor V$01638005
701   $aCavin$b Ralph K.$f1939-$01231853
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911004776503321
996   $aMicrosystems for bioelectronics$94392863
997   $aUNINA