Computational electrodynamics; the finite-difference time-domain method, 3d ed.1580538320 Computational electrodynamics electrodynamics, study of phenomena associated with charged bodies in motion and varying electric and magnetic fields (see charge; electricity); since a moving charge produces a magnetic field, electrodynamics is concerned with effects such as magnetism, ; the finite-difference time-domain method Finite-difference time-domain (FDTD) is a popular computational electrodynamics modeling technique. It is considered easy to understand and easy to implement in software. Since it is a time-domain method, solutions can cover a wide frequency range with a single simulation run. , 3d ed. Taflove, Allen and Susan C. Hagness. Artech House 2005 1006 pages $139.00 Hardcover Artech House antennas and propagation library QC760 In this comprehensive reference, Taflove (Northwestern U.), Hagness (U. of Wisconsin-Madison) and contributors explain this critical method for solving Maxwell equations, including the one-dimensional scalar wave equation, numerical dispersion and stability, incident wave source conditions, analytical absorbing boundary conditions, near-to-far field transformations, dispersive dispersive /dis·per·sive/ (-per´siv) 1. tending to become dispersed. 2. promoting dispersion. , nonlinear and gain materials, grids, bodies of revolution, periodic structures, antennas, photonics, advances in techniques and advances in hardware acceleration for FDTD FDTD Finite Difference Time Domain FDTD From Dusk 'Til Dawn . ([c] 2005 Book News, Inc., Portland, OR) |
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