Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

20.6 CHARACTERISTICS AND THE EXISTENCE OF SOLUTIONS


20.6 Characteristics and the existence of solutions

So far in this chapter we have discussed how to find general solutions to various


types of first- and second-order linear PDE. Moreover, given a set of boundary


conditions we have shown how to find the particular solution (or class of solutions)


that satisfies them. For first-order equations, for example, we found that if the


value ofu(x, y) is specified along some curve in thexy-plane then the solution to


the PDE is in general unique, but that ifu(x, y) is specified at only a single point


then the solution is not unique: there exists a class of particular solutions all of


which satisfy the boundary condition. In this section and the next we make more


rigorous the notion of the respective types of boundary condition that cause a


PDE to have a unique solution, a class of solutions, or no solution at all.


20.6.1 First-order equations

Let us consider the general first-order PDE (20.9) but now write it as


A(x, y)

∂u
∂x

+B(x, y)

∂u
∂y

=F(x, y, u). (20.39)

Suppose we wish to solve this PDE subject to the boundary condition that


u(x, y)=φ(s) is specified along some curveCin thexy-plane that is described


parametrically by the equationsx=x(s)andy=y(s), wheresis the arc length


alongC. The variation ofualongCis therefore given by


du
ds

=

∂u
∂x

dx
ds

+

∂u
∂y

dy
ds

=


ds

. (20.40)


We may then solve the two (inhomogeneous) simultaneous linear equations


(20.39) and (20.40) for∂u/∂xand∂u/∂y,unlessthe determinant of the coefficients


vanishes (see section 8.18), i.e. unless




dx/ds dy/ds
AB




∣=0.

At each point in thexy-plane this equation determines a set of curves called


characteristic curves(or justcharacteristics), which thus satisfy


B

dx
ds

−A

dy
ds

=0,

or, multiplying through byds/dxand dividing through byA,


dy
dx

=

B(x, y)
A(x, y)

. (20.41)


However, we have already met (20.41) in subsection 20.3.1 on first-order PDEs,

where solutions of the formu(x, y)=f(p), wherepis some combination ofxandy,

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