1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

348 Chapter 5 Higher Dimensions and Other Coordinates

Figure 15 Graphs of the solution of the example problem, withu(φ, 0 )positive
in the north and negative in the south. The functionu(φ,t)is shown as a function
ofφin the range 0 toπfor times chosen so that the dimensionless timekt/R^2
takes the values 0, 0.01, 0.1, and 1; for convenience,T 0 =100.

problem is

1

ρ^2

∂

∂ρ

(

ρ^2 ∂∂ρu

)

+ρ (^2) sin^1 (φ)∂φ∂

(

sin(φ)∂∂φu

)

=c^12 ∂

(^2) u
∂t^2 ,
0 <ρ<a, 0 <φ<π, 0 <t,
u(a,φ,t)= 0 , 0 <φ<π, 0 <t,
u(ρ, φ, 0 )=f(ρ, φ), 0 <ρ<a, 0 <φ<π,
∂u
∂t
(ρ, φ, 0 )=g(ρ, φ), 0 <ρ<a, 0 <φ<π.

(12)

As usual, we require in addition thatube bounded asρ→0andasφ→ 0
andφ→π.
First, we seek solutions in the product formu(ρ, φ,t)=R(ρ)(φ)T(t).
Insertinguin this form into the partial differential equation (12) and manip-
ulating, we find

1

ρ^2

(

(ρ^2 R′)′

R +

(sin(φ)′)′

sin(φ)

)

=T

′′

c^2 T. (13)

Both sides of this equation must have the same and constant value, say,−λ^2.
Thus, we must have

(ρ^2 R′)′

R

+(sin(φ)

′)′

sin(φ)

=−λ^2 ρ^2.