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Taflove A. — Computational Electrodynamics The Finite-Difference Time-Domain Method
Taflove A. — Computational Electrodynamics The Finite-Difference Time-Domain Method



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Название: Computational Electrodynamics The Finite-Difference Time-Domain Method

Автор: Taflove A.

Аннотация:

Computational Electrodynamics: The Finite-Difference Time-Domain Method is the essential reference for professional engineers, university professors and students using, teaching, or learning FDTD solutions to Maxwell's equations. The book provides a comprehensive tutorial of FDTD theory and techniques as well as details on the latest FDTD methods for the efficient design of key electronic components such as antennas for wireless communications devices, high-speed digital and microwave circuits, and integrated optics.


Язык: en

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Год издания: 1995

Количество страниц: 599

Добавлена в каталог: 05.09.2009

Операции: Положить на полку | Скопировать ссылку для форума | Скопировать ID
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Предметный указатель
Higdon, R.L.      171—174 181 188 195 200—202 383 557
Hildebrand, F.B.      471
Historical background      1
Historical background, heritage of the 1980's      1
Historical background, key developments and publications      4
Historical background, rise of partial differential equation methods in computational electromagnetics      3
Hoefer, W.J.      5 31 341 472
Holland, R.H.      5 30 79 142 201 341 391 543
Homsleth, S.N.      544
Horn antenna modeling example      487
Houshmand, B.      32 224 455 472 473 510
Howard, G.      543
Hu, Y.F.      583
Huang, T.W.      224 472
Human eye modeling example      530
Hunsberger, F.      31 225 237 274
Hyman, M.      92
Hyperthermia example, patient-specific thigh model derived from CT scans      18 535
IBM thermal conduction module digital interconnect structure modeling example      387
Imbriale, W.      581
Impedance      433
Incident wave source conditions      107
Incident wave source conditions, hard source      109 138
Incident wave source conditions, initial conditions      108
Incident wave source conditions, plane wave      108
Incident wave source conditions, resistive source      140
Incident wave source conditions, scattered-field formulation      134
Incident wave source conditions, total-field/scattered-field method      111 139
Incident wave source conditions, waveguides      137
Inductor, FD-TD model      460
Intel Delta performance benchmarks on parallel FD-TD algorithm      558
Interconnect modeling examples      20 21 387 440
Iskander, M.F.      543
Itoh, T.      32 224 472 473 510
Jackel, J.L.      277
Jackson, J.D.      224 247 277
Jacoby, N.      33 581 582
James, B.J.      543
Janaswamy, R.      509
Jandhyala V.      472
Jecko, B.      340 509
Jensen, M.A.      509 544
Jin, J.      392
Johnson, R.C.      507
Jones, M.E.      33 472
Joseph, R.M.      5 32 33 201 250 252 267 277 543
Joshi, R.P.      32 472
Judkins, J.B.      5 32 277
Jurgens, T.G.      5 31 79 294 297 301 302 305 340 391 397 429 541
Kallman, J.S.      278
Kaplan, S.      92
Karp, S.N.      198
Kashiwa, T.      5 31 238 274 277 392 472
Katehi, L.P.      471
Katz, D.S.      5 6 30 32 33 191 192 193 200 201 487—490 507 508 510 542 581
Kay, S.M.      471
Kellali, S.      326 340
Keller, J.B.      30
Kim, I.S.      341
Kleinman, R.E.      341
Ko, K.      429
Ko, W.L.      224 471
Kong, J.A.      340 391 470 582
Kouyoumjian, R.G.      30
Kraus, J.D.      507
Kreiss, H.O.      92 390
Kress, M.      429
Kriegsmann, G.A.      5 31 142 200 340
Kuempel, W.      472 582
Kumaresan, R.      471
Kunz, K.S.      5 30 31 142 225 274 340 341 509 543
Lansing, F.      6 33 343 368 377 383—387 392 582
Larson, R.      581
Laser cavity, micron scale      538
Lasing (gain) media model      270
Lau, R.W.      543
Lax, M.      278
Le Roux, J.      471
Leaird, D.E.      277
Lee, C.F.      327 340
Lee, J.-F.      362 391 471
Lee, K.L.      543
Lee, K.M.      5 30
Leontovich, M.A.      340
Lesoinne, M.      567 568 583
Liang, G.-C.      472
Liao extrapolation      174
Liao, Z.P.      91 174—178 181 195 200 202 557
Liewer, P.C.      33 581 582
Lin, C.C.      31
Lin, J.      472 473 510
Lin, W.-C.      33 507 542
Linear superposition of three-dimensional electromagnetic fields      506
Ling, K.-M.      472
Litva, J.      201 471 510
Liu, Y.-W.      31 472 473
Livesay, D.E.      542
Lo, T.K.      471
Lockhart, T.G.      33 581 582
Louisell, W.H.      278
Ludwig, A.      300 541
Luebbers, R.J.      5 30 31 219 225 228 233 274 340 509
Lumped circuit elements, FD-TD models      456
Lumped inductance due to an interconnect discontinuity      437
Luther, H.A.      92 200
Lyzenga, G.A.      33 581 582 583
Madsen, N.K.      5 31 368 371 391 392
Maeda, S.      472
Magic time step      38 43 46
Mahapatra, S.      508
Majda, A.      91 153 154 161 172 174 180 181 187 188 190 200—202 557
Maloney, J.G.      5 32 306 311 313 314 318—320 324 326 340 471 480—483 485 486 507 509
Mankofsky, A.      429
Mann, S.M.      544
Manteuffel, T.A.      390
Marcozzi, P.      201
Marple, L.      471
Material sheet, thin      304
Maxwell's equations equivalence to the wave equation in one dimension      57
Maxwell's equations, in differential form      51 52
Maxwell's equations, in integral form      51 52
Maxwell's equations, in three dimensions      51
Maxwell's equations, reduction to one dimension      56
Maxwell's equations, reduction to two dimensions      54
Maxwell's equations, TM and TE modes      55
McKnight, W.B.      278
McNamara D.A.      201
Mei — Fang superabsorption      178
Mei, K.K.      31 178—181 188 200 202 341 391 470 472 473
Meller, R.      429
Merewether, D.E.      429 507 543
Mezzanotte, P.      473
Michielssen, E.      472
Microlaser cavity modeling example      538
Missile guidance section modeling example      518
Mittal, B.B.      33 507 542
Mittra R.      224 391 471 472 582
Moghaddam, M.      200 429
Moglie, F.      201
Mohammadian, A.H.      31 391
Mondelli, A.      429
Mongiardo, M.      473
Monk, P.      344 348 390
Monopole antenna models input admittance      486
Monopole antenna models, PEC      480
Monopole antenna models, resistively loaded      310
Monopole antenna models, snapshots of radiated wave      484
Monopole antenna models, surface charge density      482
Montry, G.R.      582
Moore, T.G.      5 31 79 146 164 166 168—170 200 340 391 429 541
Moraites, S.      582
Morrow, J.D.      509
Morton, K.W.      92
Multilayered digital interconnect example      20 21 440
Multiprocessor computers      551
Mur finite-difference scheme      158
Mur, G.      5 29 31 142 157—162 175 176 178 187 190—193 195 200—202 268 298 439 489 490 512 515 536 557 558 583
Near-to-far-field transformation      203
Near-to-far-field transformation, application of Green's theorem      205
Near-to-far-field transformation, discrete Fourier transformation      210
Near-to-far-field transformation, far-field limit      206
Near-to-far-field transformation, phasor domain, three dimensions      215
Near-to-far-field transformation, phasor domain, two dimensions      204
Near-to-far-field transformation, surface equivalence theorem      213
Near-to-far-field transformation, time domain      219
Neureuther, A.      582
Ng, K.-Y.      429
Ng, P.      581
Ni, L.M.      582
Nonlinear optical material models      257
Nonlinear predictor      451
Nonorthogonal and unstructured grids      343
Nonorthogonal and unstructured grids, generalized Yee algorithm      369 376
Nonorthogonal and unstructured grids, global curvilinear coordinates      353
Nonorthogonal and unstructured grids, Gysel power divider, example      22 386
Nonorthogonal and unstructured grids, inhomogeneous media      374
Nonorthogonal and unstructured grids, irregular nonorthogonal structured grids      361
Nonorthogonal and unstructured grids, irregular nonorthogonal unstructured grids      368
Nonorthogonal and unstructured grids, locally conformal grid, globally orthogonal      353
Nonorthogonal and unstructured grids, nonorthogonal curvilinear FD-TD algorithm      353
Nonorthogonal and unstructured grids, nonuniform orthogonal grids      344
Nonorthogonal and unstructured grids, numerical stability      91 338 359 367 373
Nonorthogonal and unstructured grids, planar generalized Yee algorithm      377 382
Nonorthogonal and unstructured grids, printed circuit devices, examples      382
Nonorthogonal and unstructured grids, projection schemes      371 380
Nonorthogonal and unstructured grids, supraconvergence      344
Nonorthogonal and unstructured grids, thermal conduction module example      387
Nonorthogonal and unstructured grids, Wilkinson power divider, example      383
Norris, A.N.      200
Nour-Omid, B.      583
Numerical dispersion of basic Yee algorithm      93
Numerical dispersion of basic Yee algorithm, analysis procedure, TM mode      94
Numerical dispersion of basic Yee algorithm, comparison with the ideal dispersion case      97
Numerical dispersion of basic Yee algorithm, dispersion-optimized algorithm      101
Numerical dispersion of basic Yee algorithm, dispersion-optimized algorithm with fourth-order accurate spatial central differences      102
Numerical dispersion of basic Yee algorithm, extension to three dimensions      96
Numerical dispersion of basic Yee algorithm, reduction to the ideal dispersion case      101
Numerical dispersion of basic Yee algorithm, traveling wave trial solutions      95
Numerical dispersion of wave equation in one dimension      40
Numerical group velocity      45
Numerical phase velocity, TM mode, two dimensions      98
Numerical phase velocity, wave equation, one dimension      42
Numerical stability of basic Yee algorithm      81
Numerical stability of basic Yee algorithm, analysis procedure, TM mode      82
Numerical stability of basic Yee algorithm, enforcement of stability      87
Numerical stability of basic Yee algorithm, extension to three dimensions      88
Numerical stability of basic Yee algorithm, generalized stability problem      90
Numerical stability of basic Yee algorithm, space eigenvalue problem      85
Numerical stability of basic Yee algorithm, time eigenvalue problem      83
Numerical stability of generalizations of the Yee algorithm, body of revolution algorithm      417
Numerical stability of generalizations of the Yee algorithm, generalized Yee algorithm      373
Numerical stability of generalizations of the Yee algorithm, irregular nonorthogonal structured grids      367
Numerical stability of generalizations of the Yee algorithm, nonlinear dispersive materials      270
Numerical stability of generalizations of the Yee algorithm, nonorthogonal curvilinear grids      359
Numerical stability of generalizations of the Yee algorithm, subcell models      338
Numerical wavenumber      41
Nuttal, A.H.      471
O'Brien, G.      92
O'Sullivan, M.      582
Oliver, M.K.      277
Olivier, J.C.      201
Onishi, T.      392
Opsahl, T.      33 582
Oughstun, K.E.      277
Ozaki, T.      472
Palendech, R.      391
Panofsky, W.K.      429
Papiemik, A.      471
Parallel FD-TD algorithms      555 560 561
Parallel-plate waveguide with lossy walls      317
Parker, J.      33 582
Particle accelerator fields      423
Pathak, P.H.      30
Patterson, J.E.      33 581 582
Pauli, W.      340
Peaceman, D.W.      92
Penetration and coupling, modeling examples      517
Penetration and coupling, modeling examples, cavity, empty cylindrical PEC      517
Penetration and coupling, modeling examples, missile guidance section, loaded      518
Penetration and coupling, modeling examples, spatial decomposition via a Schelkunoff equivalence principle      522
Penetration and coupling, modeling examples, wire bundle in free space      526
Penetration and coupling, modeling examples, wire bundle in PLUTO cavity      526
Penney, C.W.      509
Pereda, J.A.      446 471
Perfectly matched layer absorbing boundary condition      6 8 19 181
Perfectly matched layer absorbing boundary condition, body of revolution grid      417
Perfectly matched layer absorbing boundary condition, numerical experiments      190
Perfectly matched layer absorbing boundary condition, TE mode      182
Perfectly matched layer absorbing boundary condition, three-dimensional case      189
Perfectly matched layer absorbing boundary condition, TM mode      188
Perfectly matched layer absorbing boundary condition, waveguides      196 417
Perlik, A.T.      33 582
Petillo, J.      429
Photonic bandgap structure      538
Piket-May, M.J.      32 33 142 431 441 461 463 464 466 471 472 507—509 537 539 542
Pillai, E.      473
Pipelined RISC and vector processors      546
Plane wave source condition, choice of incident plane wave formulation      137
Plane wave source condition, hard source      109
Plane wave source condition, insertion as an initial condition      108
Plane wave source condition, requirements      108
Plane wave source condition, scattered-field formulation      135
Plane wave source condition, total-field/scattered-field formulation      111
PLUTO cavity penetration modeling example      526
Poe, S.      509
Pompei, D.      471
Pozar, D.M.      509
Prasad, S.N.      508
Prescott, D.T.      341
Prieto, A.      471
Prince, J.      392 473
Projection operators      380
Prony's method      315 324 443
Purchine, M.P.      510
Rachford, Jr., H.H.      92
Raefsky, A.      583
Rahmat-Samii, Y.      509 544
Railton, C.J.      341 391
Ramo, S.      202 471
Rao, S.M.      30
Rascoe, D.      392
Ray, S.      392
Recursive convolution method, linear gyrotropic materials      237
Recursive convolution method, linear isotropic materials      228
Recursive convolution method, scattered-field formulation      233
Recursive convolution method, time-domain susceptibility functions      239
Recursive convolution method, total-field formulation      228
Reineix, A.      340 509
Reiss, E.L.      200
Relativistically moving PEC boundaries, subcell models      331
Relativistically moving PEC boundaries, subcell models, basis      331
Relativistically moving PEC boundaries, subcell models, oblique incidence      336
Relativistically moving PEC boundaries, subcell models, uniform translation      335
Relativistically moving PEC boundaries, subcell models, vibration      336
Ren, J.      341 509
Resistive voltage source, FD-TD model      459
Resistor, FD-TD model      458
Retinal rod modeling example      19 535
Reuter, C.R.      6 32 194 197 199 201 508 509
Richtmyer, R.D.      92
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