Synopsis
Please note that the content of this book primarily consists of articles available from Wikipedia or other free sources online. Finite-difference time-domain 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. The FDTD method belongs in the general class of grid-based differential time-domain numerical modeling methods. The time-dependent Maxwell's equations l are discretized using central-difference approximations to the space and time partial derivatives. The resulting finite-difference equations are solved in either software or hardware in a leapfrog manner: the electric field vector components in a volume of space are solved at a given instant in time then the magnetic field vector components in the same spatial volume are solved at the next instant in time; and the process is repeated over and over again until the desired transient or steady-state electromagnetic field behavior is fully evolved. The basic FDTD space grid and time-stepping algorithm trace back to a seminal 1966 paper by Kane Yee in IEEE Transactions on Antennas and Propagation. The descriptor Finite-difference time-domain and its corresponding FDTD acronym were originated by Allen Taflove in a 1980 paper in IEEE Transactions on Electromagnetic Compatibility for these and other important journal papers in the development of FDTD techniques, as well as relevant textbooks and research monographs. Since about 1990, FDTD techniques have emerged as primary means to computationally model many scientific and engineering problems dealing with electromagnetic wave interactions with material structures. As summarized in Taflove & Hagness, current FDTD modeling applications range from near-DC through microwaves to visible light. In 2006, an estimated 2,000 FDTD-related publications appeared in the science and engineering literature
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Présentation de l'éditeur
Please note that the content of this book primarily consists of articles available from Wikipedia or other free sources online. Finite-difference time-domain 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. The FDTD method belongs in the general class of grid-based differential time-domain numerical modeling methods. The time-dependent Maxwell's equations l are discretized using central-difference approximations to the space and time partial derivatives. The resulting finite-difference equations are solved in either software or hardware in a leapfrog manner: the electric field vector components in a volume of space are solved at a given instant in time then the magnetic field vector components in the same spatial volume are solved at the next instant in time; and the process is repeated over and over again until the desired transient or steady-state electromagnetic field behavior is fully evolved. The basic FDTD space grid and time-stepping algorithm trace back to a seminal 1966 paper by Kane Yee in IEEE Transactions on Antennas and Propagation. The descriptor Finite-difference time-domain and its corresponding FDTD acronym were originated by Allen Taflove in a 1980 paper in IEEE Transactions on Electromagnetic Compatibility for these and other important journal papers in the development of FDTD techniques, as well as relevant textbooks and research monographs. Since about 1990, FDTD techniques have emerged as primary means to computationally model many scientific and engineering problems dealing with electromagnetic wave interactions with material structures. As summarized in Taflove & Hagness, current FDTD modeling applications range from near-DC through microwaves to visible light. In 2006, an estimated 2,000 FDTD-related publications appeared in the science and engineering literature
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Finite-difference time-domain method
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ISBN 13: 9786130211882
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Taschenbuch. Condition: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -Finite-difference time-domain 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. The FDTD method belongs in the general class of grid-based differential time-domain numerical modeling methods. The time-dependent Maxwell's equations l are discretized using central-difference approximations to the space and time partial derivatives. The resulting finite-difference equations are solved in either software or hardware in a leapfrog manner: the electric field vector components in a volume of space are solved at a given instant in time then the magnetic field vector components in the same spatial volume are solved at the next instant in time; and the process is repeated over and over again until the desired transient or steady-state electromagnetic field behavior is fully evolved. The basic FDTD space grid and time-stepping algorithm trace back to a seminal 1966 paper by Kane Yee in IEEE Transactions on Antennas and Propagation. The descriptor Finite-difference time-domain and its corresponding FDTD acronym were originated by Allen Taflove in a 1980 paper in IEEE Transactions on Electromagnetic Compatibility for these and other important journal papers in the development of FDTD techniques, as well as relevant textbooks and research monographs. Since about 1990, FDTD techniques have emerged as primary means to computationally model many scientific and engineering problems dealing with electromagnetic wave interactions with material structures. As summarized in Taflove & Hagness, current FDTD modeling applications range from near-DC through microwaves to visible light. In 2006, an estimated 2,000 FDTD-related publications appeared in the science and engineering literature Englisch. Seller Inventory # 9786130211882
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Finite-difference time-domain method | Electromagnetic radiation, Partial differential equation, Maxwell's equations, Computational electromagnetics, Finite-difference frequency-domain, Scattering-matrix method
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Taschenbuch. Condition: Neu. Finite-difference time-domain method | Electromagnetic radiation, Partial differential equation, Maxwell's equations, Computational electromagnetics, Finite-difference frequency-domain, Scattering-matrix method | Frederic P. Miller (u. a.) | Taschenbuch | Englisch | 2026 | OmniScriptum | EAN 9786130211882 | Verantwortliche Person für die EU: preigu GmbH & Co. KG, Lengericher Landstr. 19, 49078 Osnabrück, mail[at]preigu[dot]de | Anbieter: preigu Print on Demand. Seller Inventory # 134831446