10.5 There and back again - an exploration of the liouville (Page 3/10)

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The inverse problem can be attacked by many means, including several numerical schemes. In order to apply the techniques described in [link] , it is necessary to transform [link] into the Sturm-Liouville equation

- w^{''} + q w = λ w,

where $q$ is called the potential . It is the transformation between these equations that captures the focus of our research and of this paper.

The transformations

Changing from mass density to sturm-liouville potential

To transform [link] into the Sturm-Liouville equation [link] , it is necessary to employ a change of variables that is due to Joseph Liouville [link] . Liouville's transformation requires $ρ \in C^{2}$ [0, L]. If that condition is satisfied, the transformation involves a change of dependent and independent variables. The independent variable $x$ is transformed into a new independent variable $t$ according to

t = \int_{0}^{x} \sqrt{ρ (α)} d α .

(NB: This $t$ is completely unrelated to the $t$ variable used to denote the dependence on time in [link] .) The new dependent variable $w (t)$ is given by

w (t) = y (x) ρ^{1 / 4} (x),

where the variable $x$ on the right-hand side of this equation is meant to be interpreted as a function of $t$ whose definition is given implicitly by the integral [link] .

Taking the derivative once,

\frac{d w}{d t} \frac{d t}{d x} = \frac{1}{4} y (x) {[ρ (x)]}^{- 3 / 4} \frac{d ρ}{d x} + \frac{d y}{d x} {[ρ (x)]}^{1 / 4}

(suppressing the argument of x for now)

\frac{d w}{d t} ρ^{1 / 2} = \frac{1}{4} y ρ^{- 3 / 4} ρ^{'} + y^{'} ρ^{1 / 4}

Taking the derivative again,

\frac{d^{2} w}{d t^{2}} \frac{d t}{d x} ρ^{1 / 2} + \frac{1}{2} \frac{d w}{d t} ρ^{- 1 / 2} ρ^{'} = \frac{1}{2} y^{'} ρ^{- 3 / 4} ρ^{'} - \frac{3}{16} y ρ^{- 7 / 4} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{- 3 / 4} ρ^{''} + y^{''} ρ^{1 / 4}

Substitution and simplifying terms leads to

\frac{d^{2} w}{d t^{2}} ρ + \frac{1}{2} \frac{d w}{d t} ρ^{- 1 / 2} ρ^{'} = \frac{1}{2} y^{'} ρ^{- 3 / 4} ρ^{'} - \frac{3}{16} y ρ^{- 7 / 4} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{- 3 / 4} ρ^{''} + y^{''} ρ^{1 / 4}

\frac{d^{2} w}{d t^{2}} ρ + \frac{ρ^{'}}{2 ρ^{1 / 2}} (\frac{y ρ^{'}}{4 ρ^{5 / 4}} + \frac{y^{'}}{ρ^{1 / 4}}) = \frac{1}{2} y^{'} ρ^{- 3 / 4} ρ^{'} - \frac{3}{16} y ρ^{- 7 / 4} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{- 3 / 4} ρ^{''} + y^{''} ρ^{1 / 4}

\frac{d^{2} w}{d t^{2}} ρ + \frac{ρ^{'}}{2 ρ^{1 / 2}} (\frac{y ρ^{'}}{4 ρ^{5 / 4}} + \frac{y^{'}}{ρ^{1 / 4}}) = \frac{1}{2} y^{'} ρ^{- 3 / 4} ρ^{'} - \frac{3}{16} y ρ^{- 7 / 4} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{- 3 / 4} ρ^{''} - λ y ρ^{5 / 4}

\frac{d^{2} w}{d t^{2}} ρ = \frac{- 5}{16} y ρ^{- 7 / 4} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{- 3 / 4} ρ^{''} - λ y ρ^{5 / 4}

\frac{d^{2} w}{d t^{2}} = \frac{- 5}{16} y ρ^{- 11 / 4} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{- 7 / 4} ρ^{''} - λ y ρ^{1 / 4}

\frac{d^{2} w}{d t^{2}} = \frac{- 5}{16} y ρ^{1 / 4} ρ^{- 3} {(ρ^{'})}^{2} + \frac{1}{4} y ρ^{1 / 4} ρ^{- 2} ρ^{''} - λ y ρ^{1 / 4}

\frac{d^{2} w}{d t^{2}} = \frac{- 5}{16} w ρ^{- 3} {(ρ^{'})}^{2} + \frac{1}{4} w ρ^{- 2} ρ^{''} - λ w

- \frac{d^{2} w}{d t^{2}} + (\frac{1}{4} ρ^{- 2} ρ^{''} - \frac{5}{16} ρ^{- 3} {(ρ^{'})}^{2}) w = λ w

This equation is now in the form of the Sturm-Liouville equation

- \frac{d^{2} w}{d t^{2}} + q (t) w = λ w,

where the Sturm-Liouville Dirichlet potential function , $q (t)$ , is given by

q (t) = \frac{ρ^{''} (x)}{4 ρ^{2} (x)} - \frac{5 {(ρ^{'}, (x))}^{2}}{16 ρ^{3} (x)} .

As in [link] above, the variable $x$ on the right side of this expression is to be interpreted as a function of $t$ defined by [link] .

This section describes what is needed to change from the wave equation with a mass density, $ρ$ , to a Sturm-Liouville equation with a potential, $q$ . The next section describes the reverse, changing from the Sturm-Liouville equation with a potential, $q$ , to a wave equation with a mass density, $ρ$ .

Changing from potential to density

Converting a given Dirichlet potential function $q (t)$ into corresponding mass density $ρ (x)$ amounts to solving the nonlinear ordinary differential equation, or ODE, in [link] for $ρ$ ; however, one must be careful. Using the integral [link] and abusing notation a bit, it is tempting to write $t = t (x)$ and arrive at the ODE

q (t (x)) = \frac{ρ^{''} (x)}{4 ρ^{2} (x)} - \frac{5 {(ρ^{'}, (x))}^{2}}{16 ρ^{3} (x)},

which one would then attempt to solve numerically by selecting some initial conditions for $ρ (x)$ , picking a grid in the $x$ -domain and applying one's ODE solver of choice, using some quadrature scheme to estimate $t (x)$ by approximating [link] . This approach, however, suffers from a somewhat subtle flaw: it presumes that one already knows the domain ofdefinition of $ρ (x)$ , i.e., that the length $L$ of the string can be known a priori.

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Source: OpenStax, The art of the pfug. OpenStax CNX. Jun 05, 2013 Download for free at http://cnx.org/content/col10523/1.34

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