Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

PDES: GENERAL AND PARTICULAR SOLUTIONS


describes the quantum mechanical wavefunctionu(r,t) of a non-relativistic particle


of massm;is Planck’s constant divided by 2π. Like the diffusion equation it is


second order in the three spatial variables and first order in time.


20.2 General form of solution

Before turning to the methods by which we may hope to solve PDEs such as


those listed in the previous section, it is instructive, as for ODEs in chapter 14, to


study how PDEs may be formed from a set of possible solutions. Such a study


can provide an indication of how equations obtained not from possible solutions


but from physical arguments might be solved.


For definiteness let us suppose we have a set of functions involving two

independent variablesxandy. Without further specification this is of course a


very wide set of functions, and we could not expect to find a useful equation that


they all satisfy. However, let us consider a type of functionui(x, y)inwhichxand


yappear in a particular way, such thatuican be written as a function (however


complicated)of a single variablep, itself a simple function ofxandy.


Let us illustrate this by considering the three functions

u 1 (x, y)=x^4 +4(x^2 y+y^2 +1),

u 2 (x, y)=sinx^2 cos 2y+cosx^2 sin 2y,

u 3 (x, y)=

x^2 +2y+2
3 x^2 +6y+5

.

These are all fairly complicated functions ofxandyand a single differential


equation of which each one is a solution is not obvious. However, if we observe


that in fact each can be expressed as a function of the variablep=x^2 +2yalone


(withnootherxoryinvolved) then a great simplification takes place. Written


in terms ofpthe above equations become


u 1 (x, y)=(x^2 +2y)^2 +4=p^2 +4=f 1 (p),

u 2 (x, y)=sin(x^2 +2y)=sinp=f 2 (p),

u 3 (x, y)=

(x^2 +2y)+2
3(x^2 +2y)+5

=

p+2
3 p+5

=f 3 (p).

Let us now form, for eachui, the partial derivatives∂ui/∂xand∂ui/∂y.Ineach


case these are (writing both the form for generalpand the one appropriate to


our particular case,p=x^2 +2y)


∂ui
∂x

=

dfi(p)
dp

∂p
∂x

=2xfi′,

∂ui
∂y

=

dfi(p)
dp

∂p
∂y

=2fi′,

fori= 1, 2, 3. All reference to the form offican be eliminated from these

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