Banks H.T., Buksas M., Lin T. — Electromagnetic Material Interrogation Using Conductive Interfaces and Acoustic Wavefronts :: Электронная библиотека попечительского совета мехмата МГУ

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Banks H.T., Buksas M., Lin T. — Electromagnetic Material Interrogation Using Conductive Interfaces and Acoustic Wavefronts

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Название: Electromagnetic Material Interrogation Using Conductive Interfaces and Acoustic Wavefronts

Авторы: Banks H.T., Buksas M., Lin T.

Аннотация:

The authors begin with basic electromagnetics, such as Maxwell's equations, and present modeling, theory, and computational results. The book systematically exploits interface phenomena, the electrodynamics of material responses, and time-dependent interrogating signals in an integrated manner. An excellent and robust source of applied mathematics and engineering challenges for the future.

Язык:

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Год издания: 2000

Количество страниц: 146

Добавлена в каталог: 12.04.2010

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Предметный указатель

Absorbing boundary condition      19 57
Acoustic      112
Acoustic gratings      14 112
Acoustic waves      xi
Acoustooptic effect      14
Acoustooptics      8 18
Conduction current density      9
Conductivity      3 7 9 10 48 68 133
Conductivity susceptibility kernels      3
Conductivity, Drude      133
Conductivity, Ohmic      1 10
Continuous dependence      27 32
Convolution      10 28
Convolution kernel      106
Crank — Nicholson scheme      60 61
Dielectric parameters      4
Dielectric permittivity      9
Differential Debye model      97
Dispersive materials      1
Displacement susceptibility kernel      3 4
Electric flux density      9
Electric polarization      3
Electromagnetic waves      7
Existence      27 28
Finite difference      108
Finite element approximations      42 47 108
Frequency domain      3
Galerkin      28 64
Galerkin finite element approximation      57
General polarization      57
Gronwall inequality      35
Hysteresis Debye polarization models      98
Invariant imbedding      1 2
Inverse problem      18 42 49 57 63
Least squares functional      49
Magnetic fields      9
Magnetic flux densities      9
MATLAB      80
Maxwell's equations      4 8 9
Method of mappings      16 22
Microwaves      7

Minimization problem      49
Ohm's law      9
Parameter estimation problems      48
Permittivity      58
Permittivity, relative      11 12 58
Planar electromagnetic waves      1
Polarization      3 7 10 15 16 28 48
Polarization displacement susceptibility kernel      3 35
Polarization, constitutive laws      9 16
Polarization, Debye      4 12 26 35 79 133
Polarization, dielectric response function (DRF)      4 10
Polarization, dipolar      11
Polarization, dipole      10
Polarization, displacement susceptibility kernel      10 35
Polarization, electronic      10 12
Polarization, frequency dependence      9 10
Polarization, general nth order mechanisms      12
Polarization, instantaneous      11 12 15
Polarization, ionic      10
Polarization, Lorentz      4 12 35 79 133
Polarization, orientational      10 11
Polarized planar wave      18
Precursors      4
Precursors, Brillouin      4 80 84 130
Precursors, Sommerfeld      4 80 84 130
Random noise      71
Regularity      27 42
Runga — Kutta      80
Scattering techniques      2
Semigroup      35
Sesquilinear forms      28
Source current      21
Source current density      9
Supraconductive      20 23
Supraconductive material      4 8
Susceptibility kernel      14
Uniqueness      27 33
Wave splitting technique      1 2
Well-posedness      27
Windowed microwave pulses      xi
Windowed pulse input signal      22 110
Windowed signal      21

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