1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

336 Chapter 5 Higher Dimensions and Other Coordinates

of variables:

1

ρ^2

{

∂

∂ρ

(

ρ^2 ∂u

∂ρ

)

+^1

sin(φ)

∂

∂φ

(

sin(φ)∂u

∂φ

)}

= 0 ,

0 <ρ<c, 0 <φ<π, (1)

u(c,φ)=f(φ), 0 <φ<π. (2)

From the assumptionu(ρ, φ)=R(ρ)(φ), it follows that

(ρ^2 R′(ρ))′

R(ρ)

+(sin(φ)

′(φ))′

sin(φ)(φ)

= 0.

Both terms are constant, and the second is negative,−μ^2 , because the bound-
ary condition atρ=cwill have to be satisfied by a linear combination of func-
tions ofφ. The separated equations are
(
ρ^2 R′

)′

−μ^2 R= 0 , 0 <ρ<c,( 3 )

(

sin(φ)′

)′

+μ^2 sin(φ)= 0 , 0 <φ<π. ( 4 )

Neither equation has a boundary condition. However,ρ=0 is a singular point
of the first equation, and bothφ=0andρ=πare singular points of the sec-
ond equation. (At these points, the coefficient of the highest-order derivative
is zero, while some other coefficient is nonzero.) At each of the singular points,
we impose a boundedness condition:

R( 0 )bounded,( 0 ) and (π)bounded.
Equation (4) can be simplified by the change of variables x=cos(φ),
(φ)=y(x).(Ofcourse,xisnotthe Cartesian coordinate.) By the chain rule,
the relevant derivatives are

d

dφ

=−sin(φ)dy

dx

,

d

dφ

(

sin(φ)d

dφ

)

=sin^3 (φ)d

(^2) y
dx^2
−2sin(φ)cos(φ)dy
dx

.

The differential equation becomes

sin^2 (φ)

d^2 y

dx^2 −2cos(φ)

dy

dx+μ

(^2) y= 0 ,
or, in terms ofxalone,
(
1 −x^2

)

y′′− 2 xy′+μ^2 y= 0 , − 1 <x< 1. (5)

In addition, we require thaty(x)be bounded atx=±1.