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Optimal Device Design

$144.00 (C)

Philip Seliger, A. F. J. Levi, Stephan Haas, K. Magruder, Rodrigo Muniz, Omid Nohadani, Dimitris Bertsimas, I. G. Rosen, C. Wang
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  • Date Published: January 2010
  • availability: In stock
  • format: Hardback
  • isbn: 9780521116602

$ 144.00 (C)
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About the Authors
  • Explore the frontier of device engineering by applying optimization to nanoscience and device design. This cutting-edge work shows how robust, manufacturable designs that meet previously unobtainable system specifications can be created using a combination of modern computer power, adaptive algorithms, and realistic device-physics models. Applying this method to nanoscience is a path to creating new devices with new functionality, and it could be the key design element in making nanoscience a practical technology. Basic introductory examples along with MATLAB code are included, through to more formal and sophisticated approaches, and specific applications and designs are examined. Essential reading for researchers and engineers in electronic devices, nanoscience, materials science, applied mathematics, and applied physics.

    • Describes a vibrant and exciting new direction in device design
    • Covers specific approaches and designs
    • Shows how to optimize device design by combining applied mathematics, smart computation, physical modeling, and 21st century engineering and fabrication tools
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    Product details

    • Date Published: January 2010
    • format: Hardback
    • isbn: 9780521116602
    • length: 294 pages
    • dimensions: 254 x 180 x 19 mm
    • weight: 0.73kg
    • contains: 120 b/w illus.
    • availability: In stock
  • Table of Contents

    Preface
    Acknowledgements
    1. Frontiers in device engineering Philip Seliger and A. F. J. Levi
    2. Atoms-up design Stephan Haas
    3. Electron devices and electron transport K. Magruder, Philip Seliger, and A. F. J. Levi
    4. Aperiodic dielectric design Philip Seliger
    5. Design at the classical-quantum boundary Rodrigo Muniz and Stephan Haas
    6. Robust optimization in high dimensions Omid Nohadani and Dimitris Bertsimas
    7. Mathematical framework for optimal design I. G. Rosen and C. Wang
    8. Future directions A. F. J. Levi
    Appendix A
    About the authors
    Index.

  • Editors

    A. F. J. Levi, University of Southern California
    A. F. J. Levi is Professor of Electrical Engineering and of Physics and Astronomy at the University of Southern California. He joined USC after working for 10 years at AT&T Bell Labs, New Jersey. Professor Levi is the author of the book Applied Quantum Mechanics, Second Edition (Cambridge University Press, 2006).

    Stephan Haas, University of Southern California
    Stephan Haas is Professor of Theoretical Condensed Matter Physics at the University of Southern California.

    Contributors

    Philip Seliger, A. F. J. Levi, Stephan Haas, K. Magruder, Rodrigo Muniz, Omid Nohadani, Dimitris Bertsimas, I. G. Rosen, C. Wang

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