1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

0.3 Boundary Value Problems 29

Figure 5 Cylinder of heat-conducting material.

This is approximately true for a suspension bridge. The boundary value prob-
lem to be solved is then

d^2 u

dx^2

=w

T

, 0 <x<a,

u( 0 )=h 0 , u(a)=h 1. (7)

The general solution of the differential equation (7) can be found by the
procedures of Sections 1 and 2. It is

u(x)=

(w

2 T

)

x^2 +c 1 x+c 2 ,

wherec 1 andc 2 are arbitrary. The two boundary conditions require

u( 0 )=h 0 : c 2 =h 0 ,

u(a)=h 1 :

(

w

2 T

)

a^2 +c 1 a+c 2 =h 1.

Thesetwoaresolvedforc 1 andc 2 in terms of given parameters. The result,
after some beautifying algebra, is

u(x)= w

2 T

(

x^2 −ax

)

+h^1 −h^0

a

x+h 0. (8)

Clearly, this function specifies the cable’s shape as part of a parabola opening
upward.

Example: Heat Conduction in a Rod.
A long rod of uniform material and cross section conducts heat along its axial
direction (see Fig. 5). We assume that the temperature in the rod,u(x),does
not change in time. A heat balance (“what goes in must come out”) applied to
a slice of the rod betweenxandx+ x(Fig. 6) shows that the heat flow rate
q, measured in units of heat per unit time per unit area, obeys the equation

q(x)A+g(x)A x=q(x+ x)A, (9)