"$MaterialParameter" 修訂間的差異

出自 DDCC TCAD TOOL Manual
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(Format)
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=='''Format'''==
  
=='''Format'''==
 
$MaterialParameter
  
$MaterialParameter
''type<sub>dis</sub> N ε<sub>r,∞</sub> μ<sub>r</sub> σ<sub>E</sub> σ<sub>H</sub>''
 +
''type<sub>dis</sub> N ε<sub>r,∞</sub> μ<sub>r</sub> σ<sub>E</sub> σ<sub>H</sub>''
 
''par<sub>1</sub>(1) par<sub>1</sub>(2) par<sub>1</sub>(3) par<sub>1</sub>(4)''
  
''par<sub>1</sub>(1) par<sub>1</sub>(2) par<sub>1</sub>(3) par<sub>1</sub>(4)''
 
''par<sub>2</sub>(1) par<sub>2</sub>(2) par<sub>2</sub>(3) par<sub>2</sub>(4)''
  
''par<sub>2</sub>(1) par<sub>2</sub>(2) par<sub>2</sub>(3) par<sub>2</sub>(4)''
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<font size=4>Lorentz model: </font><math>\chi_p(\omega) = \frac{(\varepsilon_{s,p}-\varepsilon_{\infty,p})\omega_p^2}{\omega_p^2+2j\omega\delta_p-\omega^2}</math><br><br>
  
<font size=4>Lorentz model: </font><math>\chi_p(\omega) = \frac{(\varepsilon_{s,p}-\varepsilon_{\infty,p})\omega_p^2}{\omega_p^2+2j\omega\delta_p-\omega^2}</math><br><br>
 
<font size=4>Drude model: </font><math>\chi_p(\omega) = -\frac{\omega_p^2}{\omega^2-j\omega\gamma_p}</math><br><br>
  
<font size=4>Drude model: </font><math>\chi_p(\omega) = -\frac{\omega_p^2}{\omega^2-j\omega\gamma_p}</math><br><br>
 
   
 
=='''Example'''==
  
=='''Example'''==

於 2018年7月18日 (三) 13:01 的修訂

Format

$MaterialParameter
 typedis       N         εr,∞        μr          σE          σH
 par1(1)    par1(2)    par1(3)    par1(4)
 par2(1)    par2(2)    par2(3)    par2(4)
   .          .          .          .
   .          .          .          .
   .          .          .          .
 parp(1)    parp(2)    parp(3)    parp(4)
   .          .          .          .
   .          .          .          .
   .          .          .          .
 parN(1)    parN(2)    parN(3)    parN(4)                // where typedis and N are integers, but the others are floating points.

Refer to Chap. 9 at p.353 - p.368.
typedis means the type of dispersive model. N means the number of poles in this material. εr,∞ is the relative permittivity at infinite frequency, μr is relative permeability, σE is electric conductivity, and σH is equivalent magnetic loss, respectively.

Models typedis parp(1) parp(2) parp(3) parp(4)
non-dispersive 0 0 0 0 0
Debye 1 εs,p ε∞,p τp 0
Lorentz 2 εs,p ε∞,p ωp δp
Drude 3 ωi γp 0 0

\varepsilon(\omega) = \varepsilon_\infty + \sum_{p=1}^P \chi_p(\omega)

Debye model: \chi_p(\omega) = \frac{(\varepsilon_{s,p}-\varepsilon_{\infty,p})}{1+j\omega\tau_p}

Lorentz model: \chi_p(\omega) = \frac{(\varepsilon_{s,p}-\varepsilon_{\infty,p})\omega_p^2}{\omega_p^2+2j\omega\delta_p-\omega^2}

Drude model: \chi_p(\omega) = -\frac{\omega_p^2}{\omega^2-j\omega\gamma_p}

Example

$NumberofObject
 1
$MaterialParameter
 2 3 10 1 0 0
 10 7 1.2566e15 1e14
 10 7 2.5133e15 2e14
 10 7 3.7699e15 3e14


Related commands

Input file 1: $NumberofObject, $MaterialStructure
Input file 2: $Backgroundparameter
取自 "http://yrwu-wk.ee.ntu.edu.tw/mediawiki/index.php?title=$MaterialParameter&oldid=1121"