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  用DRUDE色散模型
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  Dielectric dispersion frame
  Dispersion model: Here, different dielectric dispersion models can be chosen, each definable by a different set of specific material properties.
  The first material parameter for all dielectric dispersions models is the epsilon infinity value, representing the high frequency limit of the permittivity.
  Debye 1st order:  The first order Debye dispersion describes a material relaxation process, determined by the relaxation time and the epsilon static value.
  Debye 2nd order: The second order Debye dispersion describes a superposed relaxation process given by the summation of two separate first order Debye models. The corresponding parameters are the two relaxation times as well as both epsilon static values.
  Drude: The Drude dispersion model describes the dielectric behavior of plasma material, determined by the plasma frequency and the collision frequency representing damping effects.
  Lorentz:  The Lorentz dispersion model describes a material resonance process, determined by the epsilon static value, the resonance frequency and the damping factor.
  Gyrotropic: The electric gyrotropic or so-called gyroelectric dispersion behavior is relevant for magnetized plasma media. The material parameters comprise the plasma frequency and the collision frequency as for the Drude dispersion. In addition, the cyclotron frequency and the biasing direction describe the effect of the homogeneous biasing field. Note that this material dispersion is not selectable for anisotropic material settings.
  General 1st order:  For a detailed information, see Material Overview.
  General 2nd order:  For a detailed information, see Material Overview.
  User:
  The dispersion fit is based either on a constant conductivity, general 1st order, or a general 2st order model. A list of eps' eps'' values can be defined by different frequency points by pressing the Dispersion List button.
  Magnetic dispersion frame
  Dispersion model: Here, different magnetic dispersion models can be chosen, each definable by a different set of specific material properties.
  The first material parameter for all magnetic dispersions models is the mue infinity value, representing the high frequency limit of the permeability.
  Debye 1st order:  The first order Debye dispersion describes a material relaxation process, determined by the relaxation time and the mue static value.
  Debye 2nd order: The second order Debye dispersion describes a superposed relaxation process given by the summation of two separate first order Debye models. The corresponding parameters are the two relaxation times as well as both mue static values.
  Drude: The description of this dispersion model corresponds to that of the dielectric material above. However, here this model offers just the possibility to define a specialized dispersion curve, the parameters plasma and collision frequency have no exact physical equivalence.
  Lorentz:  The Lorentz dispersion model describes a material resonance process, determined by the mue static value, the resonance frequency and the damping factor.
  Gyrotropic: The magnetic gyrotropic or so-called gyromagnetic dispersion behavior is relevant for ferrite materials that are magnetized up to saturation by a homogeneous static magnetic field. The corresponding parameters can be defined either in the Gauss or SI unit system. In Gauss units, they are given by the  Landé factor, saturation magnetization (4 Pi M), the resonance line width representing the damping effects and finally the external applied magnetic field vector (x,y,z). Using SI units as the input system instead, the parameters are given by the Larmor frequency, the gyrotropic frequency, the damping factor and finally the unit vector for the biasing direction (x,y,z). Note that this material dispersion is not selectable for anisotropic material settings.
  See the Material Overview for a description of inhomogeneously biased ferrites.
  General 1st order:  For a detailed information see Material Overview.
  General 2nd order:  For a detailed information see Material Overview.
  User:
  The dispersion fit is based either on a constant conductivity, general 1st order, or a general 2st order model. A list of mue' mue'' values can be defined by different frequency points by pressing the Dispersion List… button.
  Parameter conversion frame
  Note: This frame is only available for a selected magnetic gyrotropic dispersion model.
  System: The Gauss or SI unit system can be selected for different input parameters of the gyrotropic material.
  Frequency: Reference frequency for the conversion of material parameters given in Gauss units into the SI system.
  
  See also
  Material Parameters, Material Overview (HF), Change Material, Modeller View, Dielectric Dispersion Fit, Magnetic Dispersion Fit

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  Drude模型里的plasma frequency 和collision frequency 以及epsilon infinity value能從介電常數(shù)計(jì)算出來(lái)嗎？

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  Drude模型里的plasma frequency 和collision frequency以及epsilon infinity value的值能不能直接從介電常數(shù)計(jì)算出來(lái)？

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  自己頂一下，繼續(xù)期待高手！

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