224 Chapter 3 The Wave Equation
tare frequencies, in radians per unit time;λnc/ 2 πare frequencies in cycles
per unit time (or Hertz, if the time unit is seconds). For the vibrating string
problem, the possible frequencies of vibration are
(nπ/a)c
2 π=nπc
2 a.
The fact that these form an arithmetic sequence guarantees a common period
for all theun(x,t)in Eq. (8), and thusu(x,t)in Eq. (9) is a function that is
periodic in time.
EXERCISES
1.Verify that the product solutionun(x,t)=sin(λnx)[
ancos(λnct)+bnsin(λnct)]
satisfies the wave equation (1) and the boundary conditions, Eq. (2).
2.Sketchu 1 (x,t)andu 2 (x,t)as functions ofxfor several values oft.Assume
a 1 anda 2 =1,b 1 andb 2 =0. (The solutionsun(x,t)are calledstanding
waves.)
In Exercises 3–5, solve the vibrating string problem, Eqs. (1)–(4), with the ini-
tial conditions given.
3.f(x)=0, g(x)=1, 0 <x<a.4.f(x)=sin(
πx
a)
, g(x)=0, 0 <x<a.5.f(x)={
U 0 , 0 <x<a/2,
0 , a/ 2 <x<a,
g(x)=0, 0 <x<a.
(This initial condition is difficult to justify for a vibrating string, but it
may be reasonable where the unknown function is pressure in a pipe with
a membrane at the midpoint. See Miscellaneous Exercise 18 of this chapter
for some derivations.)
6.If
∑∞n= 1ansin(nπx
a)
=f ̄o(x),∑∞
n= 1bncos(nπx
a)
=G ̄e(x),show thatu(x,t)asgiveninEq.(9)maybewritten