1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

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3.6 Wave Equation in Unbounded Regions 239
This method of estimating the first eigenvalue is calledRayleigh’s method,
and the ratioN(y)/D(y)is called theRayleigh quotient.Insomemechanical
systems, the Rayleigh quotient may be interpreted as the ratio between poten-
tial and kinetic energy. There are many other methods for estimating eigenval-
ues and for systematically improving the estimates.


EXERCISES



  1. Using Eq. (3), show that ifq≥0, thenλ^21 ≥0also.

  2. Verify the results for at least one of the trial functions used in the second
    example.

  3. Estimate the first eigenvalue of the problem


φ′′+λ^2 ( 1 +x)φ= 0 , 0 <x< 1 ,
φ( 0 )=φ( 1 )= 0.


  1. Verify that the general solution of the following differential equation is
    axcos(λ/x)+bxsin(λ/x), and then solve the eigenvalue problem.


φ′′+λ

2
x^4

φ= 0 , 1 <x< 2 ,
φ( 1 )= 0 ,φ( 2 )= 0.


  1. Estimate the lowest eigenvalue of the problem in Exercise 4 usingy=
    (x− 1 )( 2 −x).

  2. Estimate the lowest eigenvalue of the problem


φ′′+λ^2 xφ= 0 , 0 <x< 1 ,
φ( 0 )= 0 ,φ( 1 )= 0.

Use the trial functionxb( 1 −x), and minimize the Rayleigh quotient with
respect tob.

3.6 Wave Equation in Unbounded Regions


When the wave equation is to be solved for 0<x<∞or for −∞<
x<∞, we can proceed as we did for the solution of the heat equation in these
unbounded regions. That is to say, we separate variables and use a Fourier
integral to combine the product solutions.

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