Advances in computational electrodynamics : the finite-difference time-domain method

Edited by the pioneer and foremost authority on the subject, here is the first book to assemble in one resource the latest techniques and results of the leading theoreticians and practitioners of FD-TD computational electromagnetics modelling. Designed to build on his popular 1995 book, "Computational Electrodynamics: The Finite-Difference Time-Domain Method", the author describes and shows how to apply the latest advances in FD-TD in designing better-performing microwave and millimeter wave devices and circuits, high-speed digital circuits, VLSI-scale optical devices and ultra-wideband and smart antennas. This single expert source can also help solve a wide variety of problems in the following areas: imaging of underground and biological structures; evaluating the safety of wireless devices, including cellphones; bioelectromagnetics safety assessment and medical applications; and perfectly matched layer media, periodic media, high-order methods, multiresolution techniques and unstructured grids.

• A Survey of the Finite-Difference Time-Domain Literature, by Kurt L. Shlager, Lockheed-Martin Missiles and Space Company, Sunnyvale, CA
• and John B. Schneider, Washington State University. High-Order Methods, by Eli Turkel, Tel Aviv University, Israel. Time-Domain Analysis Using Multiresolution Expansions, by Linda P. B. Katehi, University of Michigan, Ann Arbor
• James F. Harvey, U.S. Army Research Office, Research Triangle Park, NC
• and Emmanouil Tentzeris, Georgia Institute of Technology, Atlanta. Explicit Time-Domain Solutions of Maxwell's Equations via Generalized Grids, by Stephen D. Gedney, University of Kentucky, Lexington
• J. Alan Roden, Georgia Tech Research Institute, Atlanta
• Niel K. Madsen, Lawrence-Livermore National Laboratory, CA
• and Alireza H. Mohammadian, William F. Hall, Vijaya Shankar, and Christopher M. Rowell, Rockwell Science Center, Thousand Oaks, CA. The Perfectly Matched Layer Absorbing Medium, by Stephen D. Gedney, University of Kentucky, Lexington. Analysis of Periodic Structures, by James G. Maloney and Morris P. Kesler, Georgia Tech Research Institute, Atlanta. Modeling of Antennas, by James G. Maloney, Georgia Tech Research Institute, Atlanta
• and Glenn S. Smith, Georgia Institute of Technology, Atlanta. High-Speed Electronic Circuits with Active and Nonlinear Components, by Bijan Houshmand, Jet Propulsion Laboratory, CA
• Tatsuo Itoh, UCLA
• and Melinda Piket-May, University of Colorado, Boulder. Physics-Based Modeling of Millimeter-Wave Devices, by Samir M. El-Ghazaly, Arizona State University, Tempe. Microcavity Resonators, by Susan C. Hagness, University of Wisconsin, Madison. FDTD in Bioelectromagnetics: Safety Assessment and Medical Applications, by Om. P. Gandhi, University of Utah, Salt Lake City. Imaging and Inverse Problems, by Weng C. Chew, University of Illinois, Urbana-Champaign.