Mathematical Tools for Physics - Department of Physics - University

16—Calculus of Variations 386

plus terms of higher order inδyandδy′.

Put this into Eq. (16.6), and

δI=

∫b

a

dx

[

∂F

∂y

δy+

∂F

∂y′

δy′

]

(16.7)

For example, LetF=x^2 +y^2 +y′^2 on the interval 0 ≤x≤ 1. Take a base path to be a straight

line from(0,0)to(1,1). Choose for the change in the pathδy(x) =x(1−x). This is simple and it

satisfies the boundary conditions.

I[y]=

∫ 1

0

dx

[

x^2 +y^2 +y′^2

]

=

∫ 1

0

dx

[

x^2 +x^2 + 1^2

]

=

5

3

I[y+δy]=

∫ 1

0

[

x^2 +

(

x+x(1−x)

) 2

+

(

1 +(1− 2 x)

) 2 ]

=

5

3

+

1

6

+

11

30

^2

(16.8)

The value of Eq. (16.7) is

δI=

∫ 1

0

dx

[

2 yδy+ 2y′δy′

]

=

∫ 1

0

dx[2xx(1−x) + 2(1− 2 x)] =

1

6

Return to the general case of Eq. (16.7) and you will see that I’ve explicitly used onlypartof the

assumption that the endpoint of the path hasn’t moved,∆a= ∆b= 0. There’s nothing in the body

of the integral itself that constrains the change in they-direction, and I had to choose the functionδy

by hand so that this constraint held. In order to use the equationsδy(a) =δy(b) = 0more generally,

there is a standard trick: integrate by parts. You’llalwaysintegrate by parts in these calculations.

∫b

a

dx

∂F

∂y′

δy′=

∫b

a

dx

∂F

∂y′

dδy

dx

=

∂F

∂y′

δy

∣

∣∣

b

a

−

∫b

a

dx

d

dx

(

∂F

∂y′

)

δy(x)

This expression allows you to use the information that the path hasn’t moved at its endpoints in they

direction either. The boundary term from this partial integration is

∂F

∂y′

δy

∣

∣∣

∣

b

a

=

∂F

∂y′

(

b,y(b)

)

δy(b)−

∂F

∂y′

(

a,y(a)

)

δy(a) = 0

Put the last two equations back into the expression forδI, Eq. (16.7) and the result is

δI=

∫b

a

dx

[

∂F

∂y

−

d

dx

(

∂F

∂y′

)]

δy (16.9)

Use this expression for the same exampleF=x^2 +y^2 +y′^2 withy(x) =xand you have

δI=

∫ 1

0

dx

[

2 y−

d

dx

2 y′

]

δy=

∫ 1

0

dx[2x−0]x(1−x) =

1

6

This is sort of like Eq. (8.16),

df=G~.d~r= gradf.d~r=∇f.d~r=

∂f

∂xk

dxk=

∂f

∂x 1

dx 1 +

∂f

∂x 2

dx 2 +···

Mathematical Tools for Physics - Department of Physics - University

plus terms of higher order inδyandδy′.

δI=

dx

[

∂F

∂y

δy+

∂F

∂y′

δy′

]

(16.7)

For example, LetF=x^2 +y^2 +y′^2 on the interval 0 ≤x≤ 1. Take a base path to be a straight

line from(0,0)to(1,1). Choose for the change in the pathδy(x) =x(1−x). This is simple and it

I[y]=

∫ 1

dx

[

x^2 +y^2 +y′^2

]

=

∫ 1

dx

[

x^2 +x^2 + 1^2

]

=

5

3

I[y+δy]=

∫ 1

[

x^2 +

(

x+x(1−x)

) 2

+

(

1 +(1− 2 x)

) 2 ]

=

5

3

+

1

6

+

11

30

^2

(16.8)

δI=

∫ 1

dx

[

2 yδy+ 2y′δy′

]

=

∫ 1

dx[2xx(1−x) + 2(1− 2 x)] =

1

6



assumption that the endpoint of the path hasn’t moved,∆a= ∆b= 0. There’s nothing in the body

of the integral itself that constrains the change in they-direction, and I had to choose the functionδy

by hand so that this constraint held. In order to use the equationsδy(a) =δy(b) = 0more generally,

dx

∂F

∂y′

δy′=

dx

∂F

∂y′

dδy

dx

=

∂F

∂y′

δy

line from(0,0)to(1,1). Choose for the change in the pathδy(x) =x(1−x). This is simple and it

x+x(1−x)

1 +(1− 2 x)

+

^2

dx[2xx(1−x) + 2(1− 2 x)] =

dx[2x−0]x(1−x) =