Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

20.3 GENERAL AND PARTICULAR SOLUTIONS


which, when substituted into the PDE (20.9), give
[
A(x, y)


∂p
∂x

+B(x, y)

∂p
∂y

]
df(p)
dp

=0.

This removes all reference to the actual form of the functionf(p) since for


non-trivialpwe must have


A(x, y)

∂p
∂x

+B(x, y)

∂p
∂y

=0. (20.10)

Let us now consider the necessary condition forf(p) to remain constant asx

andyvary; this is thatpitself remains constant. Thus forfto remain constant


implies thatxandymust vary in such a way that


dp=

∂p
∂x

dx+

∂p
∂y

dy=0. (20.11)

The forms of (20.10) and (20.11) are very alike and become the same if we

require that


dx
A(x, y)

=

dy
B(x, y)

. (20.12)


By integrating this expression the form ofpcan be found.


For

x

∂u
∂x

− 2 y

∂u
∂y

=0, (20.13)


find(i)the solution that takes the value 2 y+1on the linex=1, and(ii)a solution that
has the value 4 at the point(1,1).

If we seek a solution of the formu(x, y)=f(p), we deduce from (20.12) thatu(x, y) will
be constant along lines of (x, y)thatsatisfy


dx
x

=


dy
− 2 y

,


which on integrating givesx=cy−^1 /^2. Identifying the constant of integrationcwithp^1 /^2
(to avoid fractional powers), we conclude thatp=x^2 y. Thus the general solution of the
PDE (20.13) is


u(x, y)=f(x^2 y),

wherefis an arbitrary function.
We must now find the particular solutions that obey each of the imposed boundary
conditions. For boundary condition (i) a little thought shows that the particular solution
required is


u(x, y)=2(x^2 y)+1=2x^2 y+1. (20.14)

For boundary condition (ii) some obviously acceptable solutions are


u(x, y)=x^2 y+3,
u(x, y)=4x^2 y,
u(x, y)=4.
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