Talk:Distributed Parameter Line Model

Footnotes

Derivation of A₁ and A₂

Based on the boundary conditions at the receiving end of the line (${\displaystyle x=0\,}$), i.e.

${\displaystyle {\boldsymbol {V}}(0)={\boldsymbol {V_{r}}}\,}$

${\displaystyle {\boldsymbol {I}}(0)={\boldsymbol {I_{r}}}\,}$

The voltage and current equations are as follows:

${\displaystyle {\boldsymbol {V}}(0)={\boldsymbol {V_{r}}}=A_{1}e^{{\boldsymbol {\gamma }}(0)}+A_{2}e^{-{\boldsymbol {\gamma }}(0)}\,}$

${\displaystyle {\boldsymbol {I}}(0)={\boldsymbol {I_{r}}}={\frac {A_{1}e^{\gamma (0)}-A_{2}e^{-\gamma (0)}}{{\boldsymbol {Z}}_{c}}}\,}$

Therefore,

${\displaystyle {\boldsymbol {V_{r}}}=A_{1}+A_{2}\,}$

${\displaystyle {\boldsymbol {I_{r}}}={\frac {A_{1}-A_{2}}{{\boldsymbol {Z}}_{c}}}\,}$

Substituting ${\displaystyle A_{1}={\boldsymbol {I_{r}}}{\boldsymbol {Z}}_{c}+A_{2}\,}$ into ${\displaystyle {\boldsymbol {V_{r}}}\,}$:

${\displaystyle {\boldsymbol {V_{r}}}={\boldsymbol {I_{r}}}{\boldsymbol {Z}}_{c}+A_{2}+A_{2}\,}$

${\displaystyle \Rightarrow A_{2}={\frac {{\boldsymbol {V_{r}}}-{\boldsymbol {I_{r}}}{\boldsymbol {Z}}_{c}}{2}}\,}$

Solving for A₁, we get:

${\displaystyle {\boldsymbol {V_{r}}}=A_{1}+{\frac {{\boldsymbol {V_{r}}}-{\boldsymbol {I_{r}}}{\boldsymbol {Z}}_{c}}{2}}\,}$

${\displaystyle \Rightarrow A_{1}={\frac {{\boldsymbol {V_{r}}}+{\boldsymbol {I_{r}}}{\boldsymbol {Z}}_{c}}{2}}\,}$

Diagonality of Modal Characteristic Impedance Matrix

The modal characteristic impedance matrix is:

${\displaystyle [Z_{c}]=[\gamma ]^{-1}[T_{v}]^{-1}[Z][T_{i}]\,}$

If ${\displaystyle [\gamma ]\,}$ is diagonal, then we shall prove that ${\displaystyle [Z_{c}]\,}$ is also diagonal. This is done by proving that ${\displaystyle [T_{v}]^{-1}[Z][T_{i}]\,}$ is diagonal.

We saw that after transformation, the first order differential equations for voltage and current are:

${\displaystyle {\frac {d{\boldsymbol {V'}}}{dx}}=[T_{v}]^{-1}[Z][T_{i}]{\boldsymbol {I'}}\,}$ ... Equ. (F1)

${\displaystyle {\frac {d{\boldsymbol {I'}}}{dx}}=[T_{i}]^{-1}[Y][T_{v}]{\boldsymbol {V'}}\,}$ ... Equ. (F2)

We also saw that the square of the modal propagation constants are the eigenvalues of [Z][Y] and [Y][Z], i.e.

${\displaystyle [\gamma ]^{2}=[\lambda ]=[T_{v}]^{-1}[Z][Y][T_{v}]=[T_{i}]^{-1}[Y][Z][T_{i}]\,}$ ... Equ. (F3)

If we were to multiply the coefficients of Equations (F1) and (F2), we'd get:

${\displaystyle ([T_{v}]^{-1}[Z][T_{i}])([T_{i}]^{-1}[Y][T_{v}])=[T_{v}]^{-1}[Z][Y][T_{v}]\,}$ ... Equ. (F4a)

or

${\displaystyle ([T_{i}]^{-1}[Y][T_{v}])([T_{v}]^{-1}[Z][T_{i}])=[T_{i}]^{-1}[Y][Z][T_{i}]\,}$ ... Equ. (F4b)

We can therefore equate (F4a) and (F4b) with (F3):

${\displaystyle ([T_{v}]^{-1}[Z][T_{i}])([T_{i}]^{-1}[Y][T_{v}])=([T_{i}]^{-1}[Y][T_{v}])([T_{v}]^{-1}[Z][T_{i}])=[\gamma ]^{2}\,}$ ... Equ. (F5)

We know that the modal propagation constant matrix ${\displaystyle [\gamma ]^{2}\,}$ is diagonal. Thus for Equation (F5) to hold, then ${\displaystyle ([T_{v}]^{-1}[Z][T_{i}])\,}$ and ${\displaystyle ([T_{i}]^{-1}[Y][T_{v}])\,}$ must also be diagonal. And therefore the modal characteristic impedance matrix is also diagonal.