Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

20.6 CHARACTERISTICS AND THE EXISTENCE OF SOLUTIONS


we may differentiate the two first derivatives∂u/∂xand∂u/∂yalong the boundary


to obtain the pair of equations


d
ds

(
∂u
∂x

)
=

dx
ds

∂^2 u
∂x^2

+

dy
ds

∂^2 u
∂x∂y

,

d
ds

(
∂u
∂y

)
=

dx
ds

∂^2 u
∂x∂y

+

dy
ds

∂^2 u
∂y^2

.

We may now solve these two equations, together with the original PDE (20.43),


for the second partial derivatives ofu,exceptwhere the determinant of their


coefficients equals zero,










ABC
dx
ds

dy
ds

0

0

dx
ds

dy
ds











=0.

Expanding out the determinant,


A

(
dy
ds

) 2
−B

(
dx
ds

)(
dy
ds

)
+C

(
dx
ds

) 2
=0.

Multiplying through by (ds/dx)^2 we obtain


A

(
dy
dx

) 2
−B

dy
dx

+C=0, (20.44)

which is the ODE for the curves in thexy-plane along which the second partial


derivatives ofucannotbe found.


As for the first-order case, the curves satisfying (20.44) are called characteristics

of the original PDE. These characteristics have tangents at each point given by


(whenA=0)


dy
dx

=



B^2 − 4 AC
2 A

. (20.45)


Clearly, when the original PDE is hyperbolic (B^2 > 4 AC), equation (20.45)


defines two families of real curves in thexy-plane; when the equation is parabolic


(B^2 =4AC) it defines one family of real curves; and when the equation is elliptic


(B^2 < 4 AC) it defines two families of complex curves. Furthermore, whenA,


BandCare constants, rather than functions ofxandy, the equations of the


characteristics will be of the formx+λy= constant, which is reminiscent of the


form of solution discussed in subsection 20.3.3.

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