Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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CALCULUS OF VARIATIONS


22.3.1 Several dependent variables

Here we haveF=F(y 1 ,y′ 1 ,y 2 ,y 2 ′,...,yn,yn′,x)whereeachyi=yi(x). The analysis


in this case proceeds as before, leading tonseparate but simultaneous equations


for theyi(x),


∂F
∂yi

=

d
dx

(
∂F
∂yi′

)
,i=1, 2 ,...,n. (22.12)

22.3.2 Several independent variables

Withnindependent variables, we need to extremise multiple integrals of the form


I=

∫∫
···


F

(
y,

∂y
∂x 1

,

∂y
∂x 2

,...,

∂y
∂xn

,x 1 ,x 2 ,...,xn

)
dx 1 dx 2 ···dxn.

Using the same kind of analysis as before, we find that the extremising function


y=y(x 1 ,x 2 ,...,xn) must satisfy


∂F
∂y

=

∑n

i=1


∂xi

(
∂F
∂yxi

)
, (22.13)

whereyxistands for∂y/∂xi.


22.3.3 Higher-order derivatives

If in (22.1)F=F(y, y′,y′′,...,y(n),x) then using the same method as before


and performing repeated integration by parts, it can be shown that the required


extremising functiony(x) satisfies


∂F
∂y


d
dx

(
∂F
∂y′

)
+

d^2
dx^2

(
∂F
∂y′′

)
−···+(−1)n

dn
dxn

(
∂F
∂y(n)

)
=0, (22.14)

provided thaty=y′=···=y(n−1)= 0 at both end-points. Ify, or any of its


derivatives, is not zero at the end-points then a corresponding contribution or


contributions will appear on the RHS of (22.14).


22.3.4 Variable end-points

We now discuss the very important generalisation to variable end-points. Suppose,


as before, we wish to find the functiony(x) that extremises the integral


I=

∫b

a

F(y, y′,x)dx,

but this time we demand only that the lower end-point is fixed, while we allow


y(b) to be arbitrary. Repeating the analysis of section 22.1, we find from (22.4)

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