Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

27.7 HIGHER-ORDER EQUATIONS


0. 2


0. 2


0. 4


0. 4


0. 6


0. 6


0. 8


0. 8


1. 0


1. 0


c

y

y

x

− 1. 0


− 0. 8


− 0. 6


− 0. 4


− 0. 2


− 0. 1


Figure 27.6 The isocline method. The cross lines on each isocline show the
slopes that solutions ofdy/dx=− 2 xymust have at the points where they
cross the isoclines. The heavy line is the solution withy(0) = 1, namely
exp(−x^2 ).

second calculational pointx 2. The integration of these equations by the methods


discussed in the previous section presents no particular difficulty, provided that


all the equations are advanced through each particular step before any of them


is taken through the following step.


Higher-order equations in one dependent and one independent variable can be

reduced to a set of simultaneous equations, provided that they can be written in


the form


dRy
dxR

=f(x, y, y′,...,y(R−1)), (27.82)

whereRis the order of the equation. To do this, a new set of variablesp[r]is


defined by


p[r]=

dry
dxr

,r=1, 2 ,...,R− 1. (27.83)

Equation (27.82) is then equivalent to the following set of simultaneous first-order


equations:


dy
dx

=p[1],

dp[r]
dx

=p[r+1],r=1, 2 ,...,R− 2 , (27.84)

dp[R−1]
dx

=f(x, y, p[1],...,p[R−1]).
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