$usemubydopeT

$usemubydopeT is to enable the temperature and carrier density dependent mobility module with the predefined function. The function is designed for each region. So if total n regions is used, then you will need to setup n regions. The format is

$usemubydopeT
Type_R1  p1 p2 p3 p4 p5.....p12
Type_R2  p1 p2 p3 p4 p5.....p12
Type_R3  p1 p2 p3 p4 p5.....p12
...
...
... 
Type_RN  p1 p2 p3 p4 .....p12

Type

0: Use the original nonradiative lifetime defined in parameter setions
1: ${\displaystyle {\mu }_n=p1\times (\frac{T}{p3}{)}^{p2}}$ , and 解析失敗 (不明函數 "\m"): {\displaystyle  \mu_{p} = \m_{n} }

2: 解析失敗 (不明函數 "\m"): {\displaystyle  \m_{n} = p1 \times (\frac{T}{p5}) ^{p3} }
 , and ${\displaystyle {\mu }_n=p2\times (\frac{T}{p5}{)}^{p4}}$
3: 解析失敗 (不明函數 "\m"): {\displaystyle  \m_{n} = p1 +  \left(\frac{P2-P1}{1+(\frac{N_{d}}{p3}) ^{p4}} \right) }
 , and ${\displaystyle {\mu }_p={\tau }_n}$
4: 解析失敗 (不明函數 "\m"): {\displaystyle  \m_{n} = p1 +  \left(\frac{P2-P1}{1+(\frac{N_{d}}{p3}) ^{p4}} \right) }
 , and ${\displaystyle {\mu }_p=p5+\left(\frac{P6-P5}{1+(\frac{N_a}{p7}{)}^{p8}}\right)}$
13: 解析失敗 (不明函數 "\m"): {\displaystyle  \m_{n,0} = p1 +  \left(\frac{P2-P1}{1+(\frac{N_{d}}{p3}) ^{p4}} \right) }
,  ${\displaystyle {\mu }_n={\tau }_{n,0}\times (\frac{T}{p5}{)}^{p6}}$ , and ${\displaystyle {\tau }_p={\tau }_n}$
24: 解析失敗 (不明函數 "\m"): {\displaystyle  \m_{n,0} = p1 +  \left(\frac{P2-P1}{1+(\frac{N_{d}}{p3}) ^{p4}} \right) }
,  ${\displaystyle {\mu }_n={\tau }_{n,0}\times (\frac{T}{p5}{)}^{p6}}$ , and 
    解析失敗 (不明函數 "\m"): {\displaystyle  \m_{p,0} = p7 +  \left(\frac{P8-P7}{1+(\frac{N_{d}}{p9}) ^{p10}} \right) }
,  ${\displaystyle {\mu }_p={\tau }_{p,0}\times (\frac{T}{p11}{)}^{p12}}$.

If the mobility is for activated dopant density then

31: ${\displaystyle {\mu }_n=p1+\left(\frac{P2-P1}{1+(\frac{N_d^{+}}{p3}{)}^{p4}}\right)}$ , and ${\displaystyle {\mu }_p={\mu }_n}$
41: ${\displaystyle {\mu }_n=p1+\left(\frac{P2-P1}{1+(\frac{N_d^{+}}{p3}{)}^{p4}}\right)}$ , and ${\displaystyle {\mu }_p=p5+\left(\frac{P6-P5}{1+(\frac{N_a^{-1}}{p7}{)}^{p8}}\right)}$
131: ${\displaystyle {\mu }_{n,0}=p1+\left(\frac{P2-P1}{1+(\frac{N_d^{+}}{p3}{)}^{p4}}\right)}$,  ${\displaystyle {\mu }_n=\mu n,0\times (\frac{T}{p5}{)}^{p6}}$ , and ${\displaystyle {\tau }_p={\tau }_n}$
241: ${\displaystyle {\mu }_{n,0}=p1+\left(\frac{P2-P1}{1+(\frac{N_d^{+}}{p3}{)}^{p4}}\right)}$,  ${\displaystyle {\mu }_n={\mu }_{n,0}\times (\frac{T}{p5}{)}^{p6}}$ , and 
    ${\displaystyle {\mu }_{p,0}=p7+\left(\frac{P8-P7}{1+(\frac{N_a^{-}}{p9}{)}^{p10}}\right)}$,  ${\displaystyle {\mu }_p={\mu }_{p,0}\times (\frac{T}{p11}{)}^{p12}}$.