Function whose minimum is independent of the input? I

Beryneingmk39

Beryneingmk39

Answered question

2022-03-22

Function whose minimum is independent of the input?
I have a question that asks me to show that the functional
I(x)={x1}x2(x2+3y2)y+2xydx
has an extremal that is independent of the choice of y that joins two arbitrary points (x1,y1),(x2,y2).
So I tried solving for the extremal, which give me the euler lagrange equation:
6yy+2x=2x+6yy
That's not an error it seems that ddx(Fy)=Fy.
Ok then no wonder that the path doesn't matter. But now I am trying to compute the value of the functional for the two points, I tried a straight line between the 2, but this is giving me a messy expression, it's computable but ugly:
J(y)={x1}x2s(x2+3(sx+k)2)+2x(sx+k)dx
(where s and k are the linear coefficients of the line connecting the two points).

Answer & Explanation

Melody Gamble

Melody Gamble

Beginner2022-03-23Added 10 answers

You can actually bypass certain variation considerations for this one, but its good to treat it both ways.
Step 1
Notice I is a line integral. Multiplied out, you are integrating (x2+3y2)dy+(2xy)dx. This has the form of a vector field times a distance element, Fds. By the Fundamental Theorem of Line Integrals, the integral is path independent if F=V for some scalar V. A quick test for that is to take the x derivative of the term being multipled by dy and the y derivative of the term being multiplied by dx. If these derivatives are equal, then you can find the necessary scalar potential and the Theorem applies. In the background this follows because the curl of a gradient is zero and Stoke's Law.
Step 2
To find the potential, integrate the term multiplied by dy with respect to y. To that integral add an arbitrary function g(x), then take the x derivative of the resulting sum. Subtract the term being multiplied by dx and set what remains to zero. Solve the resulting differential equation for g(x).
In this case g(x)=0 and V(x,y)=x2y+y3 as pointed out by one of the comments, so the integral is always V(x2,y2)V(x1,y1) regardless of path.

Do you have a similar question?

Recalculate according to your conditions!

Ask your question.
Get an expert answer.

Let our experts help you. Answer in as fast as 15 minutes.

Didn't find what you were looking for?