Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

20.4 THE WAVE EQUATION


20.4 The wave equation

We have already found that the general solution of the one-dimensional wave


equation is


u(x, t)=f(x−ct)+g(x+ct), (20.26)

wherefandgare arbitrary functions. However, the equation is of such general


importance that further discussion will not be out of place.


Let us imagine thatu(x, t)=f(x−ct) represents the displacement of a string at

timetand positionx. It is clear that all positionsxand timestfor whichx−ct=


constant will have the same instantaneous displacement. Butx−ct= constant


is exactly the relation between the time and position of an observer travelling


with speedcalong the positivex-direction. Consequently this moving observer


sees a constant displacement of the string, whereas to a stationary observer, the


initial profileu(x,0) moves with speedcalong thex-axis as if it were a rigid


system. Thusf(x−ct) represents a wave form of constant shape travelling along


the positivex-axis with speedc, the actual form of the wave depending upon


the functionf. Similarly, the termg(x+ct) is a constant wave form travelling


with speedcin the negativex-direction. The general solution (20.23) represents


a superposition of these.


If the functionsf andg are the same then the complete solution (20.23)

represents identical progressive waves going in opposite directions. This may


result in a wave pattern whose profile does not progress, described as astanding


wave. As a simple example, suppose bothf(p)andg(p) have the form§


f(p)=g(p)=Acos(kp+).

Then (20.23) can be written as


u(x, t)=A[cos(kx−kct+)+cos(kx+kct+)]

=2Acos(kct)cos(kx+).

The important thing to notice is that the shape of the wave pattern, given by the


factor inx, is the same at all times but that its amplitude 2Acos(kct) depends


upon time. At some pointsxthat satisfy


cos(kx+)=0

there is no displacement at any time; such points are callednodes.


So far we have not imposed any boundary conditions on the solution (20.26).

The problem of finding a solution to the wave equation that satisfies given bound-


ary conditions is normally treated using the method of separation of variables


§In the usual notation,kis the wave number (= 2π/wavelength) andkc=ω, the angular frequency
of the wave.
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