Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

PDES: GENERAL AND PARTICULAR SOLUTIONS


Each is a valid solution (the freedom of choice of form arises from the fact thatu
is specified at only one point (1,1), and not along a continuum (say), as in boundary
condition (i)). All three are particular examples ofthe general solution, which may be
written, for example, as


u(x, y)=x^2 y+3+g(x^2 y),

whereg=g(x^2 y)=g(p) is an arbitrary function subject only tog(1) = 0. For this
example, the forms ofgcorresponding to the particular solutions listed above areg(p)=0,
g(p)=3p−3,g(p)=1−p.


As mentioned above, in order to find a solution of the formu(x, y)=f(p)we

require that the original PDE contains no term inu, but only terms containing


its partial derivatives. If a term inuis present, so thatC(x, y)= 0 in (20.9),


then the procedure needs some modification, since we cannot simply divide out


the dependence onf(p) to obtain (20.10). In such cases we look instead for


a solution of the formu(x, y)=h(x, y)f(p). We illustrate this method in the


following example.


Find the general solution of

x

∂u
∂x

+2


∂u
∂y

− 2 u=0. (20.15)

We seek a solution of the formu(x, y)=h(x, y)f(p), with the consequence that


∂u
∂x

=


∂h
∂x

f(p)+h

df(p)
dp

∂p
∂x

,


∂u
∂y

=


∂h
∂y

f(p)+h

df(p)
dp

∂p
∂y

.


Substituting these expressions into the PDE (20.15) and rearranging, we obtain
(
x


∂h
∂x

+2


∂h
∂y

− 2 h

)


f(p)+

(


x

∂p
∂x

+2


∂p
∂y

)


h

df(p)
dp

=0.


The first factor in parentheses is just the original PDE withureplaced byh. Therefore, if
hisanysolution of the PDE,however simple, this term will vanish, to leave
(
x


∂p
∂x

+2


∂p
∂y

)


h

df(p)
dp

=0,


from which, as in the previous case, we obtain


x

∂p
∂x

+2


∂p
∂y

=0.


From (20.11) and (20.12) we see thatu(x, y) will be constant along lines of (x, y)that
satisfy
dx
x


=


dy
2

,


which integrates to givex=cexp(y/2). Identifying the constant of integrationcwithpwe
findp=xexp(−y/2). Thus the general solution of (20.15) is


u(x, y)=h(x, y)f(xexp(−^12 y)),

wheref(p) is any arbitrary function ofpandh(x, y) is any solution of (20.15).

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