PlanetPhysics/Telegraph Equation

Both the electric voltage and the current in a double conductor satisfy the telegraph equation

${\displaystyle \begin{array}{c}{f}_{x^{″}x}-a{f}_{t^{″}t}-b{f_t}^{\prime }-cf=0,\end{array}}$

where ${\displaystyle x}$ is distance, ${\displaystyle t}$ is time and\, ${\displaystyle a,b,c}$\, are non-negative constants.\, The equation is a generalised form of the [[../WaveEquation/|wave equation]].

If the initial conditions are\, ${\displaystyle f(x,0)={f_t}^{\prime }(x,0)=0}$\, and the [[../PiecewiseLinear/|boundary]] conditions \,${\displaystyle f(0,t)=g(t)}$,\, ${\displaystyle f(\mathrm{\infty },t)=0}$,\, then the [[../2DLT/|Laplace transform]] of the solution [[../Bijective/|function]] \,${\displaystyle f(x,t)}$\, is

${\displaystyle \begin{array}{c}F(x,s)=G(s)e^{-x\sqrt{a{s}^2+bs+c}}.\end{array}}$

In the special case\, ${\displaystyle b^2-4ac=0}$,\, the solution is

${\displaystyle \begin{array}{c}f(x,t)=e^{-\frac{bx}{2\sqrt{a}}}g(t-x\sqrt{a})H(t-x\sqrt{a}).\end{array}}$

Justification of (2).\; Transforming the [[../DifferentialEquations/|differential equation]] (1) gives ${\displaystyle F_{x^{″}x}(x,s)-a[s^{2}F(x,s)-sf(x,0)-{f_t}^{\prime }(x,0)]-b[sF(x,s)-f(x,0)]-cF(x,s)=0,}$ which due to the initial conditions simplifies to ${\displaystyle F_{x^{″}x}(x,s)=(\underset{K^2}{\underbrace{a{s}^2+bs+c}})F(x,s).}$ The solution of this [[../DifferentialEquations/|ordinary differential equation]] is ${\displaystyle F(x,s)=C_1{e}^{Kx}+C_2{e}^{-Kx}.}$ Using the latter boundary condition, we see that ${\displaystyle F(\mathrm{\infty },s)={\displaystyle \underset{0}{\overset{\mathrm{\infty }}{\int }}}{e}^{-st}f(\mathrm{\infty },t)dt\equiv 0,}$ whence\, ${\displaystyle C_1=0}$.\, Thus the former boundary condition implies ${\displaystyle C_2=F(0,s)=ℒ\{g(t)\}=G(s).}$ So we obtain the equation (2).

Justification of (3).\; When the [[../QuadraticFormula/|discriminant]] of the [[../QuadraticFormula/|quadratic equation]] \,${\displaystyle a{s}^2+bs+c=0}$\, vanishes, the roots coincide to\, ${\displaystyle s=-\frac{b}{2a}}$,\, and\, ${\displaystyle a{s}^2+bs+c=a(s+\frac{b}{2a}{)}^2}$.\, Therefore (2) reads ${\displaystyle F(x,s)=G(s)a^{-x\sqrt{a}(s+\frac{b}{2a})}=e^{-\frac{bx}{2\sqrt{a}}}{e}^{-x\sqrt{a}s}G(s).}$ According to the delay [[../Formula/|theorem]], we have ${\displaystyle {ℒ}^{-1}\{e^{-ks}G(s)\}=g(t-k)H(t-k),}$ wnere ${\displaystyle H}$ is Heaviside step function.\, Thus we obtain for ${\displaystyle {ℒ}^{-1}\{F(x,s)\}}$ the expression of (3).

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