1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

2.2 Steady-State Temperatures 145

When the rule given here is applied to this problem, we are led to the following
equations:

d^2 v

dx^2 =^0 ,^0 <x<a,

v( 0 )=T 0 , −κv′(a)=h

(

v(a)−T 1

)

.

The solution of the differential equation isv(x)=A+Bx. The boundary con-
ditions require thatAandBsatisfy

v( 0 )=T 0 :A=T 0 ,

−κv′(a)=h

(

v(a)−T 1

)

:−κB=h(A+Ba−T 1 ).

Solving simultaneously, we find

A=T 0 , B=h(T^1 −T^0 )

κ+ha

.

Thus the steady-state solution of Eqs. (8)–(11) is

v(x)=T 0 +xh(T^1 −T^0 )

κ+ha

. (12)

In both of these examples, the steady-state temperature distribution has
been uniquely determined by the differential equation and boundary condi-
tions. This is usually the case, but not always.

Example.
For the problem

∂^2 u

∂x^2 =

1

k

∂u

∂t,^0 <x<a,^0 <t, (13)

∂u

∂x(^0 ,t)=^0 ,^0 <t, (14)

∂u

∂x(a,t)=^0 ,^0 <t, (15)

u(x, 0 )=f(x), 0 <x<a, (16)

which describes the temperature in an insulated rod that also has insulated
ends, the corresponding steady-state problem forv(x)=limt→∞u(x,t)is

d^2 v

dx^2 =^0 ,^0 <x<a,

dv

dx(^0 )=^0 ,

dv

dx(a)=^0.