Aufgaben:Exercise 4.1Z: Transmission Behavior of Short Cables: Difference between revisions

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:$$U_2(f)  =  U_1(f) \cdot  {\rm e}^{-\hspace{0.02cm}\gamma(f) \hspace{0.05cm} \cdot \hspace{0.05cm}l}  \hspace{0.05cm}.$$
:$$U_2(f)  =  U_1(f) \cdot  {\rm e}^{-\hspace{0.02cm}\gamma(f) \hspace{0.05cm} \cdot \hspace{0.05cm}l}  \hspace{0.05cm}.$$
Here  $\gamma(f)$  describes the  '''complex propagation function'''  of an extremely short line of infinitesimal length  $dx$,  which can be represented with the parameters  $R\hspace{0.05cm}'$,  $L\hspace{0.05cm}'$,  $G\hspace{0.08cm}'$ and  $C\hspace{0.08cm}'$ (see diagram) as follows:
Here  $\gamma(f)$  describes the  '''complex propagation function'''  of an extremely short line of infinitesimal length  $dx$,  which can be represented with the parameters  $R\hspace{0.05cm}'$,  $L\hspace{0.05cm}'$,  $G\hspace{0.08cm}'$ and  $C\hspace{0.08cm}'$ (see diagram) as follows:
:$$\gamma(f)  =  \sqrt{(R\hspace{0.05cm}' + {\rm j}  \cdot 2\pi f \cdot  L\hspace{0.05cm}')  \cdot  (G\hspace{0.08cm}' + {\rm j}  \cdot  2\pi f \cdot  C\hspace{0.08cm}')} =
:$$\gamma(f)  =  \sqrt{(R\hspace{0.05cm}' + {\rm j}  \cdot 2\pi f \cdot  L\hspace{0.05cm}')  \cdot  (G\hspace{0.08cm}' + {\rm j}  \cdot  2\pi f \cdot  C\hspace{0.08cm}')} =\alpha (f) + {\rm j}  \cdot \beta (f)\hspace{0.05cm}.$$
\alpha (f) + {\rm j}  \cdot \beta (f)\hspace{0.05cm}.$$
The real part of  $\gamma(f)$  results in
The real part of  $\gamma(f)$  results in
*The real part of  $\gamma(f)$  results in the attenuation function $\alpha(f)$  (per unit length).  
*The real part of  $\gamma(f)$  results in the attenuation function $\alpha(f)$  (per unit length).  
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After some calculation one can write for these sizes:
After some calculation one can write for these sizes:
:$$\alpha(f)  =  \sqrt{{1}/{2}\cdot \left (R\hspace{0.05cm}' \cdot G\hspace{0.08cm}' - \omega^2 \cdot L\hspace{0.05cm}'  \cdot C\hspace{0.08cm}'\right)+
:$$\alpha(f)  =  \sqrt{{1}/{2}\cdot \left (R\hspace{0.05cm}' \cdot G\hspace{0.08cm}' - \omega^2 \cdot L\hspace{0.05cm}'  \cdot C\hspace{0.08cm}'\right)+{1}/{2}\cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.08cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.08cm}'\hspace{0.05cm}^2)}}\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pif},$$
  {1}/{2}\cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.08cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.08cm}'\hspace{0.05cm}^2)}}
:$$\beta(f)  =  \sqrt{{1}/{2}\cdot \left (-R\hspace{0.05cm}' \cdot G\hspace{0.08cm}' + \omega^2 \cdot L\hspace{0.05cm}'  C\hspace{0.08cm}'\right)+{1}/{2}\cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.08cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.08cm}'\hspace{0.05cm}^2)}}\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$
\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
f},$$
:$$\beta(f)  =  \sqrt{{1}/{2}\cdot \left (-R\hspace{0.05cm}' \cdot G\hspace{0.08cm}' + \omega^2 \cdot L\hspace{0.05cm}'  C\hspace{0.08cm}'\right)+
  {1}/{2}\cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.08cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.08cm}'\hspace{0.05cm}^2)}}
\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$


*For the attenuation function  $a(f)$  the pseudo unit  "Neper"  (Np)  has to be added additionally and for the phase function  $b(f)$  "Radian"  (rad).    
*For the attenuation function  $a(f)$  the pseudo unit  "Neper"  (Np)  has to be added additionally and for the phase function  $b(f)$  "Radian"  (rad).    
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Another important descriptive quantity besides  $\gamma(f)$  is the  '''wave impedance'''  $Z_{\rm W}(f)$,  which gives the relationship between voltage and current of the two running waves at each location.  It holds:
Another important descriptive quantity besides  $\gamma(f)$  is the  '''wave impedance'''  $Z_{\rm W}(f)$,  which gives the relationship between voltage and current of the two running waves at each location.  It holds:
:$$Z_{\rm W}(f)  =  \sqrt{\frac {R\hspace{0.05cm}' + {\rm j}  \cdot \omega  L\hspace{0.05cm}'}{G\hspace{0.08cm}' + {\rm j}  \cdot \omega  C\hspace{0.08cm}'}}
:$$Z_{\rm W}(f)  =  \sqrt{\frac {R\hspace{0.05cm}' + {\rm j}  \cdot \omega  L\hspace{0.05cm}'}{G\hspace{0.08cm}' + {\rm j}  \cdot \omega  C\hspace{0.08cm}'}}\hspace{0.1cm}\bigg |_{\hspace{0.05cm} \omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$
\hspace{0.1cm}\bigg |_{\hspace{0.05cm} \omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$




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*Use the following values for the numerical calculations:
*Use the following values for the numerical calculations:
:$$R\hspace{0.05cm}' = 100\,\,{\rm \Omega}/{ {\rm km} }\hspace{0.05cm},\hspace{0.3cm}
:$$R\hspace{0.05cm}' = 100\,\,{\rm \Omega}/{ {\rm km} }\hspace{0.05cm},\hspace{0.3cm}G\hspace{0.08cm}' = 1\,\,{\rm µ S}/{ {\rm km}}\hspace{0.05cm},\hspace{0.3cm}2\pi  L\hspace{0.03cm}' = 2\,\,{\rm mH}/{ {\rm km}}  \hspace{0.05cm},\hspace{0.3cm}2\pi  C\hspace{0.08cm}' = 200\,\,{\rm nF}/{ {\rm km}}\hspace{0.05cm}.$$
G\hspace{0.08cm}' = 1\,\,{\rm µ S}/{ {\rm km}}\hspace{0.05cm},\hspace{0.3cm}
2\pi  L\hspace{0.03cm}' = 2\,\,{\rm mH}/{ {\rm km}}  \hspace{0.05cm},\hspace{0.3cm}
2\pi  C\hspace{0.08cm}' = 200\,\,{\rm nF}/{ {\rm km}}
\hspace{0.05cm}.$$




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{{ML-Kopf}}
{{ML-Kopf}}
'''(1)'''  If you insert the frequency  $f = 0$  into the given equations, we obtain
'''(1)'''  If you insert the frequency  $f = 0$  into the given equations, we obtain
:$$\alpha(f = 0)    =  [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm} \sqrt{{1}/{2}\hspace{-0.03cm}\cdot \hspace{-0.03cm}  R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}  G\hspace{0.03cm}'+ {1}/{2}\cdot R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}  
:$$\alpha(f = 0)    =  [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm} \sqrt{{1}/{2}\hspace{-0.03cm}\cdot \hspace{-0.03cm}  R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}  G\hspace{0.03cm}'+ {1}/{2}\cdot R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}G\hspace{0.03cm}'} =  [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm}  \sqrt{ R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}  G\hspace{0.03cm}'} =  [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm}  \sqrt{ 100\,{\rm \Omega/km} \hspace{-0.03cm}\cdot \hspace{-0.03cm}  10^{-6}\,{\rm (\Omega \hspace{-0.03cm}\cdot \hspace{-0.03cm}  km})^{-1}}\hspace{0.15cm}\underline{= 0.01\,{\rm Np}/{ {\rm km}}}\hspace{0.05cm},$$
G\hspace{0.03cm}'} =  [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm}  \sqrt{ R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}  G\hspace{0.03cm}'} =  [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm}  \sqrt{ 100\,{\rm \Omega/km} \hspace{-0.03cm}\cdot \hspace{-0.03cm}  10^{-6}\,{\rm (\Omega \hspace{-0.03cm}\cdot \hspace{-0.03cm}  km})^{-1}}
:$$\beta(f = 0)  =  [1\,{\rm rad}] \cdot \sqrt{-{1}/{2}\cdot R\hspace{0.03cm}' \cdot G\hspace{0.03cm}'+ {1}/{2}\cdot R\hspace{0.03cm}' \cdotG\hspace{0.03cm}'} \hspace{0.15cm}\underline{=  0 }\hspace{0.05cm},$$
\hspace{0.15cm}\underline{= 0.01\,{\rm Np}/{ {\rm km}}
:$$Z_{\rm W}(f = 0)  =  \sqrt{\frac {R\hspace{0.03cm}'}{G\hspace{0.03cm}'}} =  \sqrt{\frac {100\,{\rm \Omega/km}}{{\rm 10^{-6}/(\Omega \cdot km})}}\hspace{0.15cm}\underline{=  10\, {\rmk \Omega}}\hspace{0.05cm}.$$
}\hspace{0.05cm},$$
:$$\beta(f = 0)  =  [1\,{\rm rad}] \cdot \sqrt{-{1}/{2}\cdot R\hspace{0.03cm}' \cdot G\hspace{0.03cm}'+ {1}/{2}\cdot R\hspace{0.03cm}' \cdot
G\hspace{0.03cm}'} \hspace{0.15cm}\underline{=  0 }\hspace{0.05cm},$$
:$$Z_{\rm W}(f = 0)  =  \sqrt{\frac {R\hspace{0.03cm}'}{G\hspace{0.03cm}'}} =  \sqrt{\frac {100\,{\rm \Omega/km}}{{\rm 10^{-6}/(\Omega \cdot km})}}\hspace{0.15cm}\underline{=  10\, {\rm
k \Omega}}\hspace{0.05cm}.$$


The DC signal attenuation becomes relevant,  
The DC signal attenuation becomes relevant,  
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f \cdot  2\pi  C'  =  10^5\,\frac{1}{ {\rm s}} \cdot 2 \cdot
f \cdot  2\pi  C'  =  10^5\,\frac{1}{ {\rm s}} \cdot 2 \cdot
10^{-7}\,\frac{\rm  s}{ {\rm \Omega \cdot km}}= 0.02
10^{-7}\,\frac{\rm  s}{ {\rm \Omega \cdot km}}= 0.02
\,\frac{\rm 1 }{ {\rm \Omega \cdot km}} \hspace{0.05cm}.$$
\,\frac{\rm 1 }{ {\rm \Omega \cdot km}} \hspace{0.05cm}.$$This results in the following for the attenuation function in "Np/km"::$$\alpha(f = 100\,{\rm kHz})
This results in the following for the attenuation function in "Np/km":
:$$\alpha(f = 100\,{\rm kHz})
=  \sqrt{ {1}/{2}\cdot \left (100 \cdot 10^{-6} - 200 \cdot 0.02 \right)+
=  \sqrt{ {1}/{2}\cdot \left (100 \cdot 10^{-6} - 200 \cdot 0.02 \right)+
   {1}/{2} \cdot  \sqrt{(100^2 + 200^2) \cdot (10^{-12} + 0.02^2)}} $$
   {1}/{2} \cdot  \sqrt{(100^2 + 200^2) \cdot (10^{-12} + 0.02^2)}} $$:$$ \Rightarrow \; \;  \alpha(f = 100\,{\rm kHz}) \approx  \sqrt{{1}/{2}\cdot \left (10^{-4} - 4 \right)+
:$$ \Rightarrow \; \;  \alpha(f = 100\,{\rm kHz}) \approx  \sqrt{{1}/{2}\cdot \left (10^{-4} - 4 \right)+
  {1}/{2}\cdot \sqrt{5 \cdot 10^{4} \cdot 4 \cdot 10^{-4}}} \approx \sqrt {-2 + \frac{\sqrt{20}}{
  {1}/{2}\cdot \sqrt{5 \cdot 10^{4} \cdot 4 \cdot 10^{-4}}} \approx \sqrt {-2 + \frac{\sqrt{20}}{
  2}} \hspace{0.15cm}\underline{\approx 0.486 \ {\rm Np/km}} \hspace{0.05cm}.$$
  2}} \hspace{0.15cm}\underline{\approx 0.486 \ {\rm Np/km}} \hspace{0.05cm}.$$'''(3)'''  The limit for  $f  → \infty$  results if one neglects the second terms in the numerator  $R\hspace{0.03cm}'$  and in the denominator  $G\hspace{0.08cm}'$ ::$$\lim_{f \rightarrow \infty} \hspace{0.1cm} Z_{\rm W}(f)
 
 
'''(3)'''  The limit for  $f  → \infty$  results if one neglects the second terms in the numerator  $R\hspace{0.03cm}'$  and in the denominator  $G\hspace{0.08cm}'$ :
:$$\lim_{f \rightarrow \infty} \hspace{0.1cm} Z_{\rm W}(f)
  = \lim_{\omega \rightarrow \infty} \hspace{0.1cm}  \sqrt{\frac {R\hspace{0.03cm}' + {\rm j}  \cdot \omega L'}{G' + {\rm j}  \cdot \omega  C\hspace{0.03cm}'}}
  = \lim_{\omega \rightarrow \infty} \hspace{0.1cm}  \sqrt{\frac {R\hspace{0.03cm}' + {\rm j}  \cdot \omega L'}{G' + {\rm j}  \cdot \omega  C\hspace{0.03cm}'}}
  =\sqrt{\frac {2 \pi L\hspace{0.03cm}' }{2 \pi C\hspace{0.03cm}'}}=\sqrt{\frac {2 \cdot 10^{-3}\,{\rm \Omega \cdot s} }
  =\sqrt{\frac {2 \pi L\hspace{0.03cm}' }{2 \pi C\hspace{0.03cm}'}}=\sqrt{\frac {2 \cdot 10^{-3}\,{\rm \Omega \cdot s} }
  {2 \cdot 10^{-73}\,{\rm s/\Omega} }} \hspace{0.15cm}\underline{= 100\,{\rm \Omega }}\hspace{0.05cm}.$$
  {2 \cdot 10^{-73}\,{\rm s/\Omega} }} \hspace{0.15cm}\underline{= 100\,{\rm \Omega }}\hspace{0.05cm}.$$*The approximation for the attenuation function is more difficult to derive.  Starting from:$$\alpha(\omega)  =  \sqrt{ {1}/{2}\cdot \left (R\hspace{0.03cm}' G\hspace{0.03cm}' - \omega^2 \cdot L\hspace{0.03cm}'  C\hspace{0.03cm}'\right)+
*The approximation for the attenuation function is more difficult to derive.  Starting from
   {1}/{2}\sqrt{(R\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2) \cdot (G\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot C\hspace{0.03cm}\hspace{0.03cm}'^2)}}$$:then also the following applies::$$2 \cdot \alpha^2(\omega)    =  R\hspace{0.03cm}' G\hspace{0.03cm}' + \omega^2 \cdot L'
:$$\alpha(\omega)  =  \sqrt{ {1}/{2}\cdot \left (R\hspace{0.03cm}' G\hspace{0.03cm}' - \omega^2 \cdot L\hspace{0.03cm}'  C\hspace{0.03cm}'\right)+
   {1}/{2}\sqrt{(R\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2) \cdot (G\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot C\hspace{0.03cm}\hspace{0.03cm}'^2)}}$$  
:then also the following applies:
:$$2 \cdot \alpha^2(\omega)    =  R\hspace{0.03cm}' G\hspace{0.03cm}' + \omega^2 \cdot L'
  C'\cdot
  C'\cdot
  \left [-1 +\sqrt{(1 + \frac{R\hspace{0.03cm}'^2}{ \omega^2 \cdot L\hspace{0.03cm}'^2}) \cdot (1 + \frac{G\hspace{0.03cm}'^2}{ \omega^2 \cdot C\hspace{0.03cm}'^2})} \hspace{0.1cm}
  \left [-1 +\sqrt{(1 + \frac{R\hspace{0.03cm}'^2}{ \omega^2 \cdot L\hspace{0.03cm}'^2}) \cdot (1 + \frac{G\hspace{0.03cm}'^2}{ \omega^2 \cdot C\hspace{0.03cm}'^2})} \hspace{0.1cm}
  \right]$$
  \right]$$:$$\Rightarrow \; \; 2 \cdot \alpha^2(\omega)      \approx  R\hspace{0.03cm}' G\hspace{0.03cm}' + \omega^2 \cdot L'
:$$\Rightarrow \; \; 2 \cdot \alpha^2(\omega)      \approx  R\hspace{0.03cm}' G\hspace{0.03cm}' + \omega^2 \cdot L'
  C\hspace{0.03cm}'\cdot
  C\hspace{0.03cm}'\cdot
  \left [-1 +\sqrt{1 + \frac{R'^2}{ \omega^2 \cdot L'^2}+ \frac{G\hspace{0.03cm}'^2}{ \omega^2 \cdot C\hspace{0.03cm}'^2}} \hspace{0.1cm}
  \left [-1 +\sqrt{1 + \frac{R'^2}{ \omega^2 \cdot L'^2}+ \frac{G\hspace{0.03cm}'^2}{ \omega^2 \cdot C\hspace{0.03cm}'^2}} \hspace{0.1cm}
  \right].$$
  \right].$$*Using the approximation  $\sqrt{1 + x}\approx 1+x/2$  valid for small  $x$,  one arrives at the intermediate result for (infinitely) large frequencies::$$2 \cdot \alpha^2(\omega \rightarrow \infty)    =  R\hspace{0.03cm}' G\hspace{0.05cm}' + \omega^2 \cdot L'
*Using the approximation  $\sqrt{1 + x}\approx 1+x/2$  valid for small  $x$,  one arrives at the intermediate result for (infinitely) large frequencies:
:$$2 \cdot \alpha^2(\omega \rightarrow \infty)    =  R\hspace{0.03cm}' G\hspace{0.05cm}' + \omega^2 \cdot L'
  C\hspace{0.05cm}'\cdot
  C\hspace{0.05cm}'\cdot
  \left [ -1 +1 + {1}/{2} \cdot  \left ( \frac{R\hspace{0.03cm}'\hspace{0.03cm}^2}{ \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2}+ \frac{G\hspace{0.03cm}'\hspace{0.03cm}^2}{ \omega^2 \cdot C\hspace{0.03cm}'\hspace{0.03cm}^2}
  \left [ -1 +1 + {1}/{2} \cdot  \left ( \frac{R\hspace{0.03cm}'\hspace{0.03cm}^2}{ \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2}+ \frac{G\hspace{0.03cm}'\hspace{0.03cm}^2}{ \omega^2 \cdot C\hspace{0.03cm}'\hspace{0.03cm}^2}
  \right) \hspace{0.1cm}
  \right) \hspace{0.1cm}
  \right]  $$
  \right]  $$:$$\Rightarrow \hspace{0.3cm}  2  \cdot \alpha^2(\omega \rightarrow \infty) =  \frac{2 \cdot  R\hspace{0.03cm}'  G\hspace{0.03cm}'  C\hspace{0.03cm}'  L'+ R\hspace{0.03cm}'\hspace{0.03cm}^2  C\hspace{0.03cm}'\hspace{0.03cm}^2+
:$$\Rightarrow \hspace{0.3cm}  2  \cdot \alpha^2(\omega \rightarrow \infty) =  \frac{2 \cdot  R\hspace{0.03cm}'  G\hspace{0.03cm}'  C\hspace{0.03cm}'  L'+ R\hspace{0.03cm}'\hspace{0.03cm}^2  C\hspace{0.03cm}'\hspace{0.03cm}^2+
   G\hspace{0.03cm}'\hspace{0.03cm}^2  L\hspace{0.03cm}'\hspace{0.03cm}^2}{2 \cdot C\hspace{0.03cm}'  L\hspace{0.03cm}'
   G\hspace{0.03cm}'\hspace{0.03cm}^2  L\hspace{0.03cm}'\hspace{0.03cm}^2}{2 \cdot C\hspace{0.03cm}'  L\hspace{0.03cm}'
   }=  \frac{(R\hspace{0.03cm}'  C\hspace{0.03cm}' + G\hspace{0.03cm}'  L\hspace{0.03cm}')^2}{2 \cdot C\hspace{0.03cm}'  L\hspace{0.03cm}' }$$
   }=  \frac{(R\hspace{0.03cm}'  C\hspace{0.03cm}' + G\hspace{0.03cm}'  L\hspace{0.03cm}')^2}{2 \cdot C\hspace{0.03cm}'  L\hspace{0.03cm}' }$$:$$\Rightarrow \hspace{0.3cm} \alpha(\omega \rightarrow \infty)  =
:$$\Rightarrow \hspace{0.3cm} \alpha(\omega \rightarrow \infty)  =
   {1}/{2}\cdot \frac{R\hspace{0.03cm}' C\hspace{0.03cm}' + G\hspace{0.03cm}'  L\hspace{0.03cm}'}{\sqrt{ C\hspace{0.03cm}'  L\hspace{0.03cm}' }}=
   {1}/{2}\cdot \frac{R\hspace{0.03cm}' C\hspace{0.03cm}' + G\hspace{0.03cm}'  L\hspace{0.03cm}'}{\sqrt{ C\hspace{0.03cm}'  L\hspace{0.03cm}' }}=
   {1}/{2}\cdot \left [R\hspace{0.03cm}' \cdot \sqrt{\frac{C\hspace{0.03cm}'}{L\hspace{0.03cm}'}}+G\hspace{0.03cm}' \cdot \sqrt{\frac{L\hspace{0.03cm}'}{C\hspace{0.03cm}'}}\right]\hspace{0.05cm}.$$
   {1}/{2}\cdot \left [R\hspace{0.03cm}' \cdot \sqrt{\frac{C\hspace{0.03cm}'}{L\hspace{0.03cm}'}}+G\hspace{0.03cm}' \cdot \sqrt{\frac{L\hspace{0.03cm}'}{C\hspace{0.03cm}'}}\right]\hspace{0.05cm}.$$*With the numerical values inserted,  we get:$$\alpha(f \rightarrow \infty)  =  \alpha(\omega \rightarrow \infty)
*With the numerical values inserted,  we get  
:$$\alpha(f \rightarrow \infty)  =  \alpha(\omega \rightarrow \infty)
  =  {0.5\,{\rm Np/km}}\cdot \left [100 \cdot \sqrt{\frac{2 \cdot 10^{-7}}{2 \cdot10^{-3}}}+10^{-6} \cdot
  =  {0.5\,{\rm Np/km}}\cdot \left [100 \cdot \sqrt{\frac{2 \cdot 10^{-7}}{2 \cdot10^{-3}}}+10^{-6} \cdot
   \sqrt{\frac{2 \cdot10^{-3}}{2 \cdot10^{-7}}}\right]
   \sqrt{\frac{2 \cdot10^{-3}}{2 \cdot10^{-7}}}\right]
\hspace{0.15cm}\underline{\approx 0.5 \, {\rm Np}/{\rm km}}\hspace{0.05cm}.$$
\hspace{0.15cm}\underline{\approx 0.5 \, {\rm Np}/{\rm km}}\hspace{0.05cm}.$$'''(4)'''  For small frequencies,  $\omega L\hspace{0.03cm}' \ll R\hspace{0.03cm}'$  and  $ \omega C\hspace{0.03cm}' \gg G\hspace{0.03cm}'$ apply.*Neglecting the  $\omega^2$–part, one obtains::$$\alpha(f)    =  \sqrt{\frac {1}{2}\cdot \left (R\hspace{0.03cm}' G\hspace{0.03cm}' - \omega^2 \cdot L\hspace{0.03cm}'  C\hspace{0.03cm}'\right)+
 
 
'''(4)'''  For small frequencies,  $\omega L\hspace{0.03cm}' \ll R\hspace{0.03cm}'$  and  $ \omega C\hspace{0.03cm}' \gg G\hspace{0.03cm}'$ apply.  
*Neglecting the  $\omega^2$–part, one obtains:
:$$\alpha(f)    =  \sqrt{\frac {1}{2}\cdot \left (R\hspace{0.03cm}' G\hspace{0.03cm}' - \omega^2 \cdot L\hspace{0.03cm}'  C\hspace{0.03cm}'\right)+
  \frac {1}{2}\sqrt{(R\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2) \cdot (G\hspace{0.03cm}'\hspace{0.03cm}^2+ \omega^2 \cdot C\hspace{0.03cm}'\hspace{0.03cm}^2)}}
  \frac {1}{2}\sqrt{(R\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2) \cdot (G\hspace{0.03cm}'\hspace{0.03cm}^2+ \omega^2 \cdot C\hspace{0.03cm}'\hspace{0.03cm}^2)}}
  \hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
  \hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
  f}$$
  f}$$:$$ \Rightarrow \hspace{0.3cm} \alpha(f)    \approx  \sqrt{\frac {R\hspace{0.03cm}' G\hspace{0.03cm}'}{2}+
:$$ \Rightarrow \hspace{0.3cm} \alpha(f)    \approx  \sqrt{\frac {R\hspace{0.03cm}' G\hspace{0.03cm}'}{2}+
  \frac {R\hspace{0.03cm}' \cdot \omega C\hspace{0.03cm}'}{2}}
  \frac {R\hspace{0.03cm}' \cdot \omega C\hspace{0.03cm}'}{2}}
  \hspace{0.1cm}\bigg |_{\hspace{0.03cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
  \hspace{0.1cm}\bigg |_{\hspace{0.03cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
  f} \approx \sqrt{
  f} \approx \sqrt{
   {1}/{2} \cdot f \cdot R\hspace{0.03cm}' \cdot 2 \pi C\hspace{0.03cm}'}
   {1}/{2} \cdot f \cdot R\hspace{0.03cm}' \cdot 2 \pi C\hspace{0.03cm}'}
  \hspace{0.05cm}.$$
  \hspace{0.05cm}.$$*Here it is considered that the first part can be neglected according to subtask  '''(1)'''  except for the frequency  $f = 0$ .*For the frequency  $f = 1 \ \rm kHz$  we get the approximation:$$\alpha(f = 1\,{\rm kHz})  = \sqrt{
*Here it is considered that the first part can be neglected according to subtask  '''(1)'''  except for the frequency  $f = 0$ .  
*For the frequency  $f = 1 \ \rm kHz$  we get the approximation
:$$\alpha(f = 1\,{\rm kHz})  = \sqrt{
   {1}/{2} \cdot 10^{3}\,{\rm Hz} \cdot 100\,\frac{\rm \Omega }{ {\rm km}} \cdot 2 \cdot 10^{-7}
   {1}/{2} \cdot 10^{3}\,{\rm Hz} \cdot 100\,\frac{\rm \Omega }{ {\rm km}} \cdot 2 \cdot 10^{-7}
  \,\frac{\rm s }{ {\rm \Omega \cdot km}}}
  \,\frac{\rm s }{ {\rm \Omega \cdot km}}}
\hspace{0.15cm}\underline{= 0.1\,{\rm Np }/{ {\rm km}}}
\hspace{0.15cm}\underline{= 0.1\,{\rm Np }/{ {\rm km}}}
  \hspace{0.05cm}.$$
  \hspace{0.05cm}.$$*For frequency  $f = 4 \ \rm kHz$  the attenuation function per unit length is twice as large::$$\alpha(f = 4\,{\rm kHz})  \hspace{0.15cm}\underline{ = 0.2\,{\rm Np }/{ {\rm km}}}
*For frequency  $f = 4 \ \rm kHz$  the attenuation function per unit length is twice as large:
  \hspace{0.05cm}.$$'''(5)'''  The wave impedance at low frequencies is approximated by::$$Z_{\rm W}(f)  =  \sqrt{\frac {R\hspace{0.03cm}' + {\rm j}  \cdot f \cdot 2 \pi  L\hspace{0.03cm}'}{G\hspace{0.03cm}' + {\rm j}    \cdot f \cdot 2 \pi  C\hspace{0.03cm}'}}
:$$\alpha(f = 4\,{\rm kHz})  \hspace{0.15cm}\underline{ = 0.2\,{\rm Np }/{ {\rm km}}}
  \hspace{0.05cm}.$$
 
 
 
'''(5)'''  The wave impedance at low frequencies is approximated by:  
:$$Z_{\rm W}(f)  =  \sqrt{\frac {R\hspace{0.03cm}' + {\rm j}  \cdot f \cdot 2 \pi  L\hspace{0.03cm}'}{G\hspace{0.03cm}' + {\rm j}    \cdot f \cdot 2 \pi  C\hspace{0.03cm}'}}
  \approx \sqrt\frac{1 }{  {\rm j}} \cdot \sqrt{\frac {R\hspace{0.03cm}' }{  f \cdot 2 \pi
  \approx \sqrt\frac{1 }{  {\rm j}} \cdot \sqrt{\frac {R\hspace{0.03cm}' }{  f \cdot 2 \pi
  C\hspace{0.03cm}'}}= (1 - {\rm j})\cdot \sqrt{\frac {R\hspace{0.03cm}' }{  2 \cdot f \cdot 2 \pi
  C\hspace{0.03cm}'}}= (1 - {\rm j})\cdot \sqrt{\frac {R\hspace{0.03cm}' }{  2 \cdot f \cdot 2 \pi
  C\hspace{0.03cm}'}}\hspace{0.05cm}.$$
  C\hspace{0.03cm}'}}\hspace{0.05cm}.$$*With the specified line fittings we obtain::$${\rm Re}\{Z_{\rm W}(f= 1\,{\rm kHz})\}  =  \sqrt{\frac {100\,{\rm \Omega/km }}{  2 \cdot 10^{3}\,{\rm Hz} \cdot 2 \cdot 10^{-7}
*With the specified line fittings we obtain:
:$${\rm Re}\{Z_{\rm W}(f= 1\,{\rm kHz})\}  =  \sqrt{\frac {100\,{\rm \Omega/km }}{  2 \cdot 10^{3}\,{\rm Hz} \cdot 2 \cdot 10^{-7}
  \,{\rm s/(\Omega \cdot km) }}} \hspace{0.15cm}\underline{= 500\,{\rm
  \,{\rm s/(\Omega \cdot km) }}} \hspace{0.15cm}\underline{= 500\,{\rm
  \Omega}}\hspace{0.05cm},$$
  \Omega}}\hspace{0.05cm},$$:$$ {\rm Im}\{Z_{\rm W}(f= 1\,{\rm kHz})\} =  -{\rm Re}\{Z_{\rm W}(f= 1\,{\rm kHz})\}\hspace{0.15cm}\underline{= -500\,{\rm
:$$ {\rm Im}\{Z_{\rm W}(f= 1\,{\rm kHz})\} =  -{\rm Re}\{Z_{\rm W}(f= 1\,{\rm kHz})\}\hspace{0.15cm}\underline{= -500\,{\rm
  \Omega}}\hspace{0.05cm}.$$
  \Omega}}\hspace{0.05cm}.$$
{{ML-Fuß}}
{{ML-Fuß}}

Revision as of 15:48, 16 March 2026

Short line section

We assume a homogeneous and reflection-free terminated line of length  $l$  so that the following applies to the spectral function at the output:

$$U_2(f) = U_1(f) \cdot {\rm e}^{-\hspace{0.02cm}\gamma(f) \hspace{0.05cm} \cdot \hspace{0.05cm}l} \hspace{0.05cm}.$$

Here  $\gamma(f)$  describes the  complex propagation function  of an extremely short line of infinitesimal length  $dx$,  which can be represented with the parameters  $R\hspace{0.05cm}'$,  $L\hspace{0.05cm}'$,  $G\hspace{0.08cm}'$ and  $C\hspace{0.08cm}'$ (see diagram) as follows:

$$\gamma(f) = \sqrt{(R\hspace{0.05cm}' + {\rm j} \cdot 2\pi f \cdot L\hspace{0.05cm}') \cdot (G\hspace{0.08cm}' + {\rm j} \cdot 2\pi f \cdot C\hspace{0.08cm}')} =\alpha (f) + {\rm j} \cdot \beta (f)\hspace{0.05cm}.$$

The real part of  $\gamma(f)$  results in

  • The real part of  $\gamma(f)$  results in the attenuation function $\alpha(f)$  (per unit length).
  • The imaginary part of  $\gamma(f)$  results in the phase function  $\beta(f)$ (per unit length).


After some calculation one can write for these sizes:

$$\alpha(f) = \sqrt{{1}/{2}\cdot \left (R\hspace{0.05cm}' \cdot G\hspace{0.08cm}' - \omega^2 \cdot L\hspace{0.05cm}' \cdot C\hspace{0.08cm}'\right)+{1}/{2}\cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.08cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.08cm}'\hspace{0.05cm}^2)}}\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pif},$$
$$\beta(f) = \sqrt{{1}/{2}\cdot \left (-R\hspace{0.05cm}' \cdot G\hspace{0.08cm}' + \omega^2 \cdot L\hspace{0.05cm}' C\hspace{0.08cm}'\right)+{1}/{2}\cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.08cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.08cm}'\hspace{0.05cm}^2)}}\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$
  • For the attenuation function  $a(f)$  the pseudo unit  "Neper"  (Np)  has to be added additionally and for the phase function  $b(f)$  "Radian"  (rad).  
  • Since the primary line parameters are each related to the line length,  $\alpha(f)$  and  $\beta(f)$  have the units  "Np/km"  and  "rad/km",  respectively.


Another important descriptive quantity besides  $\gamma(f)$  is the  wave impedance  $Z_{\rm W}(f)$,  which gives the relationship between voltage and current of the two running waves at each location.  It holds:

$$Z_{\rm W}(f) = \sqrt{\frac {R\hspace{0.05cm}' + {\rm j} \cdot \omega L\hspace{0.05cm}'}{G\hspace{0.08cm}' + {\rm j} \cdot \omega C\hspace{0.08cm}'}}\hspace{0.1cm}\bigg |_{\hspace{0.05cm} \omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$



Notes:

  • Use the following values for the numerical calculations:
$$R\hspace{0.05cm}' = 100\,\,{\rm \Omega}/{ {\rm km} }\hspace{0.05cm},\hspace{0.3cm}G\hspace{0.08cm}' = 1\,\,{\rm µ S}/{ {\rm km}}\hspace{0.05cm},\hspace{0.3cm}2\pi L\hspace{0.03cm}' = 2\,\,{\rm mH}/{ {\rm km}} \hspace{0.05cm},\hspace{0.3cm}2\pi C\hspace{0.08cm}' = 200\,\,{\rm nF}/{ {\rm km}}\hspace{0.05cm}.$$



Questions

1 Specify  $\alpha(f)$,  $\beta(f)$ and  $Z_{\rm W}(f)$  for frequency  $f = 0$  ("direct current").

$\alpha(f =0) \ =$ $\ \rm Np/km$
$\beta(f = 0) \ =$ $\ \rm rad/km$
$Z_{\rm W}(f = 0) \ =$ $\ \rm \Omega$

2 Calculate the attenuation function  $\alpha(f)$  (per unit length)  for  $f = 100\ \rm kHz$.

$\alpha(f = 100\ \rm kHz) \ = \ $ $\ \rm Np/km$

3 Give the approximations of  $Z_{\rm W}(f)$  and  $\alpha(f)$,  valid for  $f → \infty$ .

$ Z_{\rm W}(f → \infty) \ = \ $ $\ \rm \Omega$
$\alpha(f → \infty) \ = \ $ $\ \rm Np/km$

4 Use  $\omega L\hspace{0.03cm}' \ll R\hspace{0.05cm}'$  and  $\omega C\hspace{0.08cm}' \gg G\hspace{0.08cm}'$  to derive an  $\alpha(f)$  approximation for  (not too)  small frequencies.
What is the attenuation function per unit length for  $ f = 1 \ \rm kHz$  and  $ f = 4 \ \rm kHz$?

$\alpha(f = 1\  \rm kHz) \ = \ $ $\ \rm Np/km$
$\alpha(f = 4\ \rm kHz) \ = \ $ $\ \rm Np/km$

5 For the same frequency range,  give a suitable approximation for the wave impedance  $Z_{\rm W}(f)$ .
What value results for  $ f = 1 \ \rm kHz$?

${\rm Re}\{Z_{\rm W}(f = 1\ \rm kHz)\} \ = \ $ $\ \rm \Omega$
${\rm Im}\{Z_{\rm W}(f = 1\ \rm kHz)\} \ = \ $ $\ \rm \Omega$


Solution

(1)  If you insert the frequency  $f = 0$  into the given equations, we obtain

$$\alpha(f = 0) = [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm} \sqrt{{1}/{2}\hspace{-0.03cm}\cdot \hspace{-0.03cm} R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm} G\hspace{0.03cm}'+ {1}/{2}\cdot R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm}G\hspace{0.03cm}'} = [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm} \sqrt{ R\hspace{0.03cm}' \hspace{-0.03cm}\cdot \hspace{-0.03cm} G\hspace{0.03cm}'} = [1\,{\rm Np}] \hspace{-0.03cm}\cdot \hspace{-0.03cm} \sqrt{ 100\,{\rm \Omega/km} \hspace{-0.03cm}\cdot \hspace{-0.03cm} 10^{-6}\,{\rm (\Omega \hspace{-0.03cm}\cdot \hspace{-0.03cm} km})^{-1}}\hspace{0.15cm}\underline{= 0.01\,{\rm Np}/{ {\rm km}}}\hspace{0.05cm},$$
$$\beta(f = 0) = [1\,{\rm rad}] \cdot \sqrt{-{1}/{2}\cdot R\hspace{0.03cm}' \cdot G\hspace{0.03cm}'+ {1}/{2}\cdot R\hspace{0.03cm}' \cdotG\hspace{0.03cm}'} \hspace{0.15cm}\underline{= 0 }\hspace{0.05cm},$$
$$Z_{\rm W}(f = 0) = \sqrt{\frac {R\hspace{0.03cm}'}{G\hspace{0.03cm}'}} = \sqrt{\frac {100\,{\rm \Omega/km}}{{\rm 10^{-6}/(\Omega \cdot km})}}\hspace{0.15cm}\underline{= 10\, {\rmk \Omega}}\hspace{0.05cm}.$$

The DC signal attenuation becomes relevant,

  • if the useful signal is to be transmitted in the baseband and has a DC component,  or
  • if the network termination at the participant must be supplied with power from the local exchange  ("remote power supply").


(2)  With  $f = 10^{5} \ \rm Hz$  and the specified values,  the following holds:

$$f \cdot 2\pi L' = 10^5\,\frac{1}{ {\rm s}} \cdot 2 \cdot

10^{-3}\,\frac{\rm \Omega \cdot s}{ {\rm km}}= 200 \,\frac{\rm \Omega }{ {\rm km}} \hspace{0.05cm},\hspace{1.05cm} f \cdot 2\pi C' = 10^5\,\frac{1}{ {\rm s}} \cdot 2 \cdot 10^{-7}\,\frac{\rm s}{ {\rm \Omega \cdot km}}= 0.02 \,\frac{\rm 1 }{ {\rm \Omega \cdot km}} \hspace{0.05cm}.$$This results in the following for the attenuation function in "Np/km"::$$\alpha(f = 100\,{\rm kHz}) = \sqrt{ {1}/{2}\cdot \left (100 \cdot 10^{-6} - 200 \cdot 0.02 \right)+

 {1}/{2} \cdot  \sqrt{(100^2 + 200^2) \cdot (10^{-12} + 0.02^2)}} $$:$$ \Rightarrow \; \;  \alpha(f = 100\,{\rm kHz}) \approx   \sqrt{{1}/{2}\cdot \left (10^{-4} - 4 \right)+
{1}/{2}\cdot \sqrt{5 \cdot 10^{4} \cdot 4 \cdot 10^{-4}}} \approx \sqrt {-2 + \frac{\sqrt{20}}{
2}} \hspace{0.15cm}\underline{\approx 0.486 \ {\rm Np/km}} \hspace{0.05cm}.$$(3)  The limit for  $f  → \infty$  results if one neglects the second terms in the numerator  $R\hspace{0.03cm}'$  and in the denominator  $G\hspace{0.08cm}'$ ::$$\lim_{f \rightarrow \infty} \hspace{0.1cm} Z_{\rm W}(f)
= \lim_{\omega \rightarrow \infty} \hspace{0.1cm}  \sqrt{\frac {R\hspace{0.03cm}' + {\rm j}   \cdot \omega L'}{G' + {\rm j}   \cdot \omega  C\hspace{0.03cm}'}}
=\sqrt{\frac {2 \pi L\hspace{0.03cm}' }{2 \pi C\hspace{0.03cm}'}}=\sqrt{\frac {2 \cdot 10^{-3}\,{\rm \Omega \cdot s} }
{2 \cdot 10^{-73}\,{\rm s/\Omega} }} \hspace{0.15cm}\underline{= 100\,{\rm \Omega }}\hspace{0.05cm}.$$*The approximation for the attenuation function is more difficult to derive.  Starting from:$$\alpha(\omega)  =  \sqrt{ {1}/{2}\cdot \left (R\hspace{0.03cm}' G\hspace{0.03cm}' - \omega^2 \cdot L\hspace{0.03cm}'  C\hspace{0.03cm}'\right)+
 {1}/{2}\sqrt{(R\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2) \cdot (G\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot C\hspace{0.03cm}\hspace{0.03cm}'^2)}}$$:then also the following applies::$$2 \cdot \alpha^2(\omega)    =   R\hspace{0.03cm}' G\hspace{0.03cm}' + \omega^2 \cdot L'
C'\cdot
\left [-1 +\sqrt{(1 + \frac{R\hspace{0.03cm}'^2}{ \omega^2 \cdot L\hspace{0.03cm}'^2}) \cdot (1 + \frac{G\hspace{0.03cm}'^2}{ \omega^2 \cdot C\hspace{0.03cm}'^2})} \hspace{0.1cm}
\right]$$:$$\Rightarrow \; \; 2 \cdot \alpha^2(\omega)      \approx   R\hspace{0.03cm}' G\hspace{0.03cm}' + \omega^2 \cdot L'
C\hspace{0.03cm}'\cdot
\left [-1 +\sqrt{1 + \frac{R'^2}{ \omega^2 \cdot L'^2}+ \frac{G\hspace{0.03cm}'^2}{ \omega^2 \cdot C\hspace{0.03cm}'^2}} \hspace{0.1cm}
\right].$$*Using the approximation  $\sqrt{1 + x}\approx 1+x/2$  valid for small  $x$,  one arrives at the intermediate result for (infinitely) large frequencies::$$2 \cdot \alpha^2(\omega \rightarrow \infty)    =   R\hspace{0.03cm}' G\hspace{0.05cm}' + \omega^2 \cdot L'
C\hspace{0.05cm}'\cdot
\left [ -1 +1 + {1}/{2} \cdot  \left ( \frac{R\hspace{0.03cm}'\hspace{0.03cm}^2}{ \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2}+ \frac{G\hspace{0.03cm}'\hspace{0.03cm}^2}{ \omega^2 \cdot C\hspace{0.03cm}'\hspace{0.03cm}^2}
\right) \hspace{0.1cm}
\right]  $$:$$\Rightarrow \hspace{0.3cm}  2  \cdot \alpha^2(\omega \rightarrow \infty) =  \frac{2 \cdot  R\hspace{0.03cm}'  G\hspace{0.03cm}'  C\hspace{0.03cm}'  L'+ R\hspace{0.03cm}'\hspace{0.03cm}^2  C\hspace{0.03cm}'\hspace{0.03cm}^2+
 G\hspace{0.03cm}'\hspace{0.03cm}^2  L\hspace{0.03cm}'\hspace{0.03cm}^2}{2 \cdot C\hspace{0.03cm}'  L\hspace{0.03cm}'
 }=  \frac{(R\hspace{0.03cm}'  C\hspace{0.03cm}' + G\hspace{0.03cm}'  L\hspace{0.03cm}')^2}{2 \cdot C\hspace{0.03cm}'  L\hspace{0.03cm}' }$$:$$\Rightarrow \hspace{0.3cm} \alpha(\omega \rightarrow \infty)   =
  {1}/{2}\cdot \frac{R\hspace{0.03cm}' C\hspace{0.03cm}' + G\hspace{0.03cm}'  L\hspace{0.03cm}'}{\sqrt{ C\hspace{0.03cm}'  L\hspace{0.03cm}' }}=
  {1}/{2}\cdot \left [R\hspace{0.03cm}' \cdot \sqrt{\frac{C\hspace{0.03cm}'}{L\hspace{0.03cm}'}}+G\hspace{0.03cm}' \cdot \sqrt{\frac{L\hspace{0.03cm}'}{C\hspace{0.03cm}'}}\right]\hspace{0.05cm}.$$*With the numerical values inserted,  we get:$$\alpha(f \rightarrow \infty)   =  \alpha(\omega \rightarrow \infty)
=  {0.5\,{\rm Np/km}}\cdot \left [100 \cdot \sqrt{\frac{2 \cdot 10^{-7}}{2 \cdot10^{-3}}}+10^{-6} \cdot
 \sqrt{\frac{2 \cdot10^{-3}}{2 \cdot10^{-7}}}\right]

\hspace{0.15cm}\underline{\approx 0.5 \, {\rm Np}/{\rm km}}\hspace{0.05cm}.$$(4)  For small frequencies,  $\omega L\hspace{0.03cm}' \ll R\hspace{0.03cm}'$  and  $ \omega C\hspace{0.03cm}' \gg G\hspace{0.03cm}'$ apply.*Neglecting the  $\omega^2$–part, one obtains::$$\alpha(f) = \sqrt{\frac {1}{2}\cdot \left (R\hspace{0.03cm}' G\hspace{0.03cm}' - \omega^2 \cdot L\hspace{0.03cm}' C\hspace{0.03cm}'\right)+

\frac {1}{2}\sqrt{(R\hspace{0.03cm}'\hspace{0.03cm}^2 + \omega^2 \cdot L\hspace{0.03cm}'\hspace{0.03cm}^2) \cdot (G\hspace{0.03cm}'\hspace{0.03cm}^2+ \omega^2 \cdot C\hspace{0.03cm}'\hspace{0.03cm}^2)}}
\hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
f}$$:$$ \Rightarrow \hspace{0.3cm} \alpha(f)     \approx  \sqrt{\frac {R\hspace{0.03cm}' G\hspace{0.03cm}'}{2}+
\frac {R\hspace{0.03cm}' \cdot \omega C\hspace{0.03cm}'}{2}}
\hspace{0.1cm}\bigg |_{\hspace{0.03cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi
f} \approx \sqrt{
 {1}/{2} \cdot f \cdot R\hspace{0.03cm}' \cdot 2 \pi C\hspace{0.03cm}'}
\hspace{0.05cm}.$$*Here it is considered that the first part can be neglected according to subtask  (1)  except for the frequency  $f = 0$ .*For the frequency  $f = 1 \ \rm kHz$  we get the approximation:$$\alpha(f = 1\,{\rm kHz})   = \sqrt{
 {1}/{2} \cdot 10^{3}\,{\rm Hz} \cdot 100\,\frac{\rm \Omega }{ {\rm km}} \cdot 2 \cdot 10^{-7}
\,\frac{\rm s }{ {\rm \Omega \cdot km}}}

\hspace{0.15cm}\underline{= 0.1\,{\rm Np }/{ {\rm km}}}

\hspace{0.05cm}.$$*For frequency  $f = 4 \ \rm kHz$  the attenuation function per unit length is twice as large::$$\alpha(f = 4\,{\rm kHz})  \hspace{0.15cm}\underline{ = 0.2\,{\rm Np }/{ {\rm km}}}
\hspace{0.05cm}.$$(5)  The wave impedance at low frequencies is approximated by::$$Z_{\rm W}(f)  =  \sqrt{\frac {R\hspace{0.03cm}' + {\rm j}   \cdot f \cdot 2 \pi  L\hspace{0.03cm}'}{G\hspace{0.03cm}' + {\rm j}    \cdot f \cdot 2 \pi  C\hspace{0.03cm}'}}
\approx \sqrt\frac{1 }{  {\rm j}} \cdot \sqrt{\frac {R\hspace{0.03cm}' }{  f \cdot 2 \pi
C\hspace{0.03cm}'}}= (1 - {\rm j})\cdot \sqrt{\frac {R\hspace{0.03cm}' }{  2 \cdot f \cdot 2 \pi
C\hspace{0.03cm}'}}\hspace{0.05cm}.$$*With the specified line fittings we obtain::$${\rm Re}\{Z_{\rm W}(f= 1\,{\rm kHz})\}  =   \sqrt{\frac {100\,{\rm \Omega/km }}{  2 \cdot 10^{3}\,{\rm Hz} \cdot 2 \cdot 10^{-7}
\,{\rm s/(\Omega \cdot km) }}} \hspace{0.15cm}\underline{= 500\,{\rm
\Omega}}\hspace{0.05cm},$$:$$ {\rm Im}\{Z_{\rm W}(f= 1\,{\rm kHz})\} =  -{\rm Re}\{Z_{\rm W}(f= 1\,{\rm kHz})\}\hspace{0.15cm}\underline{= -500\,{\rm
\Omega}}\hspace{0.05cm}.$$