3.6 Wave Equation in Unbounded Regions 245
EXERCISES
- Derive a formula similar to Eq. (6) for the case in which the boundary con-
dition Eq. (4) is replaced by
∂u
∂x
( 0 ,t)= 0 , 0 <t.- Derive Eq. (6) from Eq. (5) by using trigonometric identities for the prod-
uct sin(λx)·cos(λct), and so forth, and recognizing certain Fourier inte-
grals. - Sketch the solution of Eqs. (1)–(4) as a function ofxat timest=0, 1/ 2 c,
1 /c,2/c,3/c,ifg(x)=0everywhereandf(x)is the rectangular pulse
f(x)={ 0 , 0 <x<1,
1 , 1 <x<2,
0 , 2 <x.- Same as Exercise 3, butf(x)=0andg(x)is the rectangular pulse
g(x)={ 0 , 0 <x<1,
c, 1 <x<2,
0 , 2 <x.- Sketch the solution of Eqs. (7)–(10) at timest=0,π/2,π,3π/2, 2π,5π/2,
ifh(t)=sin(t).Takec=1. - Sketch the solution of Eqs. (7)–(10) at timest=0, 1/2, 3/2, and 5/2, if
c=1and
h(t)={ 0 , 0 <t<1,
1 , 1 <t<2,
0 , 2 <t.- Use the d’Alembert solution of the wave equation to solve the problem
∂^2 u
∂x^2 =1
c^2∂^2 u
∂t^2 , −∞<x<∞,^0 <t,
u(x, 0 )=f(x), −∞<x<∞,
∂u
∂t(x,^0 )=g(x), −∞<x<∞.- The solution of the problem stated in Exercise 7 is sometimes written
u(x,t)=1
2
(
f(x+ct)+f(x−ct))
+
1
2 c∫x+ctx−ctg(z)dz.