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Bio-Inspired and Nanoscale Integrated Computing
Mary Mehrnoosh Eshaghian-Wilner (Edited by), M Eshaghian–Wilne (Author)
9780470116593, Wiley
Hardback, published 26 June 2009
576 pages
24.3 x 16 x 3.1 cm, 0.894 kg
Brings the latest advances in nanotechnology and biology to computing This pioneering book demonstrates how nanotechnology can create even faster, denser computing architectures and algorithms. Furthermore, it draws from the latest advances in biology with a focus on bio-inspired computing at the nanoscale, bringing to light several new and innovative applications such as nanoscale implantable biomedical devices and neural networks. Bio-Inspired and Nanoscale Integrated Computing features an expert team of interdisciplinary authors who offer readers the benefit of their own breakthroughs in integrated computing as well as a thorough investigation and analyses of the literature. Carefully edited, the book begins with an introductory chapter providing a general overview of the field. It ends with a chapter setting forth the common themes that tie the chapters together as well as a forecast of emerging avenues of research. Among the important topics addressed in the book are modeling of nano devices, quantum computing, quantum dot cellular automata, dielectrophoretic reconfigurable nano architectures, multilevel and three-dimensional nanomagnetic recording, spin-wave architectures and algorithms, fault-tolerant nanocomputing, molecular computing, self-assembly of supramolecular nanostructures, DNA nanotechnology and computing, nanoscale DNA sequence matching, medical nanorobotics, heterogeneous nanostructures for biomedical diagnostics, biomimetic cortical nanocircuits, bio-applications of carbon nanotubes, and nanoscale image processing. Readers in electrical engineering, computer science, and computational biology will gain new insights into how bio-inspired and nanoscale devices can be used to design the next generation of enhanced integrated circuits.
Foreword vii Preface ix Contributors xiii 1 An Introduction to Nanocomputing 1 2 Nanoscale Devices: Applications and Modeling 31 3 Quantum Computing 67 4 Computing with Quantum-dot Cellular Automata 111 5 Dielectrophoretic Architectures 155 6 Multilevel and Three-dimensional Nanomagnetic Recording 175 7 Spin-wave Architectures 203 8 Parallel Computing with Spin Waves 225 9 Nanoscale Standard Digital Modules 243 10 Fault- and Defect-tolerant Architectures For Nanocomputing 263 11 Molecular Computing: Integration of Molecules For Nanocomputing 295 12 Self-assembly of Supramolecular Nanostructures: Ordered Arrays of Metal Ions and CarbonNanotubes 327 13 DNA Nanotechnology and Its Biological Applications 349 14 DNA Sequence Matching at Nanoscale Level 377 15 Computational Tasks in Medical Nanorobotics 391 16 Heterogeneous Nanostructures for Biomedical Diagnostics 429 17 Biomimetic Cortical Nanocircuits 455 18 Biomedical and Biomedicine Applications of CNTs 483 19 Nanoscale Image Processing 515 20 Concluding Remarks at the Beginning of a New Computing Era 535 Index 547
Elaine Ann Ebreo Cara, Stephen Chu, Mary Mehrnoosh Eshaghian-Wilner, Eric Mlinar, Alireza Nojeh, Fady Rofail, Michael M. Safaee, Shawn Singh, Daniel Wu, and Chun Wing Yip
Alireza Nojeh
John H. Reif
Konrad Walus and Graham A. Jullien
Alexander D. Wissner-Gross
S. Khizroev, R. Chomko, I. Dumer, and D. Litvinov
Mary Mehrnoosh Eshaghian-Wilner, Alex Khitun, Shiva Navab, and Kang L. Wang
Mary Mehrnoosh Eshaghian-Wilner and Shiva Navab
Shiva Navab
Sumit Ahuja, Gaurav Singh, Debayan Bhaduri, and Sandeep Shukla
James M. Tour and Lin Zhong
Mario Ruben
John H. Reif and Thomas H. LaBean
Mary Mehrnoosh Eshaghian-Wilner, Ling Lau, Shiva Navab, and David D. Shen
Robert A. Freitas, Jr.
Hongyu Yu, Mahsa Rouhanizadeh, Lisong Ai, and Tzung K. Hsiai
Alice C. Parker, Aaron K. Friesz, and Ko-Chung Tseng
Tulin Mangir
Mary Mehrnoosh Eshaghian-Wilner and Shiva Navab
Varun Bhojwani, Stephen Chu, Mary Mehrnoosh Eshaghian-Wilner, Shawn Singh, and Chun Wing Yip
Subject Areas: Electronics & communications engineering [TJ]
