telegraph equation

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

$\displaystyle f_{xx}''-af_{tt}''-bf_t'-cf = 0,$ (1)

where $ x$ is distance, $ t$ is time and $ a,\,b,\,c$ are non-negative constants. The equation is a generalised form of the wave equation.

If the initial conditions are $ f(x,\,0) = f_t'(x,\,0) = 0$ and the boundary conditions $ f(0,\,t) = g(t)$, $ f(\infty,\,t) = 0$, then the Laplace transform of the solution function $ f(x,\,t)$ is

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

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

$\displaystyle f(x,\,t) = e^{-\frac{bx}{2\sqrt{a}}}g(t-x\sqrt{a})H(t-x\sqrt{a}).$ (3)

Justification of (2). Transforming the differential equation (1) gives

$\displaystyle F_{xx}''(x,\,s)-a[s^2F(x,\,s)-sf(x,\,0)-f_t'(x,\,0)]-b[sF(x,\,s)-f(x,\,0)]-cF(x,\,s) = 0,$

which due to the initial conditions simplifies to

$\displaystyle F_{xx}''(x,\,s) = (\underbrace{as^2+bs+c}_{K^2})F(x,\,s).$

The solution of this ordinary differential equation is

$\displaystyle F(x,\,s) = C_1e^{Kx}+C_2e^{-Kx}.$

Using the latter boundary condition, we see that

$\displaystyle F(\infty,\,s) = \int_0^\infty e^{-st}f(\infty,\,t)\,dt \equiv 0,$

whence $ C_1 = 0$. Thus the former boundary condition implies

$\displaystyle C_2 = F(0,\,s) = \mathcal{L}\{g(t)\} = G(s).$

So we obtain the equation (2).

Justification of (3). When the discriminant of the quadratic equation $ as^2\!+\!bs\!+\!c = 0$ vanishes, the roots coincide to $ s = -\frac{b}{2a}$, and $ as^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 theorem, we have

$\displaystyle \mathcal{L}^{-1}\{e^{-ks}G(s)\} = g(t-k)H(t-k),$

wnere $ H$ is Heaviside step function. Thus we obtain for $ \mathcal{L}^{-1}\{F(x,\,s)\}$ the expression of (3).



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