Mathematics Stack Exchange
Mathematics Stack Exchange

Questions tagged [calculus-of-variations]

This tag is for problems relating to the calculus of variations that deal with maximizing or minimizing functionals. This problem is a generalization of the problem of finding extrema of functions of several variables. In fact, these variables will themselves be functions and we will be finding extrema of “functions of functions” or functionals.

The calculus of variations seeks to minimize or maximize an entire functional's worth of parameters instead of changing just one parameter. It achieves this by applying standard calculus techniques to the integral of a functional, thereby reducing $\mathbb R \to \mathbb R$ to just one parameter $\in\mathbb R$.

In symbols one considers $\displaystyle\max \int f(x) \ker(x)$ $dx$ rather than $\max f(s)$.

Two famous applications of the calculus of variations are the brachistochrone problem and deriving the catenary shape of a rope hanging between two poles.

Some basic problems in the calculus of variations are:

$(i)$ find minimizers

$(ii)$ find necessary conditions which minimizers must satisfy

$(iii)$ find solutions (extremals) which satisfy the necessary conditions

$(iv)$ find sufficient conditions which guarantee that such solutions are minimizers

$(v)$ qualitative properties of minimizers, like regularity properties

$(vi)$ how do the minimizers depend on parameters?

$(vii)$ stability of extremals depending on parameters.

Application: A huge number of problems in the calculus of variations have their origin in physics where one has to minimize the energy associated to the problem under consideration. Nowadays many problems come from economics.

References:

https://en.wikipedia.org/wiki/Calculus_of_variations

http://mathworld.wolfram.com/CalculusofVariations.html

http://www.math.uni-leipzig.de/~miersemann/variabook.pdf

2968 questions
0
votes
1 answer

A Calculus please help

This is kinda a typical question of. But I'm really stuck in this. Is there any one how to solve thisquestion. Really really appreciate it.
Pe.
  • 11
0
votes
0 answers

Expansion of functional in power terms

https://i.stack.imgur.com/kT1M0.png I'm really lost as to what to do. Do I need to Taylor expand around $\alpha=0$? And if so, how does the third expansion term even look like? I found the first and second terms…
tyvmm8
  • 23
0
votes
2 answers

Finding an extremal of $J[y]=\int_0^1e^y(y')^2 dx$

I have to find the extremal and natural boundary conditions for the following functional: $$J[y]=\int_0^1e^y(y')^2 dx. $$ This is subject to $y(0)=0$ and the right endpoint varying along $x=1$. I have found the Euler-Lagrange equation to be…
user45503
  • 209
  • 2
  • 11
0
votes
1 answer

Unique solution of parametrized functional

Show that for $\lambda \in [0,\pi)$, the functional $$ J_{\lambda}(y) = \frac{1}{2}\int_0^1y'(x)^2 - \lambda^2y(x)^2dx $$ has a unique minimum $ y \equiv 0$ over $y \in C^1[0,1]$ and $y(0) = y(1) = 0$. Solution: Note the Euler-Lagrange…
clocktower
  • 1,447
0
votes
1 answer

Weak minimum vs. strong minimum

Consider the problem of minimizing the functional $$ J(y) = \int_0^1 y'(x)^2(1-y'(x)^2)dx $$ with the end-points condition $y(0) = y(1) = 0$. Is the curve $y \equiv 0$ a weak minimum or a strong minimum of $J$? Clearly, $y$ is a weak minimum.…
clocktower
  • 1,447
0
votes
2 answers

Find the extremal functions $y(x)$ of the integral $\int_0^1(y^2-(y')^2)dx$.

We have to find the extremal functions $y(x)$ of the integral $\int_0^1(y^2-(y')^2)dx$. MY TRY:I used the formula $\frac{\partial F}{\partial y} - \frac{d}{dx}(\frac{\partial F}{\partial y'}) = 0$ and finally got $(y')^2+y^2=c$ but i could not get…
MatheMagic
  • 2,386
0
votes
1 answer

Derivative of $\sqrt{\mathbf {\dot r}\cdot \mathbf{\dot r}}$ with respect to $\mathbf{\dot r}$.

What is the derivative of $\sqrt{\mathbf {\dot r}\cdot \mathbf{\dot r}}$ with respect to $\mathbf {\dot r}$? I'm asking this due to this: $$\delta \mathrm A = \delta \int_A^B n(\mathbf r(s) )\sqrt{\frac{\mathrm d\mathbf r}{\mathrm d s}\cdot…
user142971
0
votes
1 answer

How did $\sqrt{\frac{\mathrm d\mathbf r}{\mathrm d s}\cdot \frac{\mathrm d\mathbf r}{\mathrm ds}}$ come in the variation of the action $\mathrm A$?

I was reading about variational calculus and Euler-Lagrange equation of motion. There the variation of action $\mathrm A$ is defined as: $$\delta \mathrm A = \frac{\mathrm d}{\mathrm d\epsilon}\bigg|_{\varepsilon~=~0}\int_A^B n(\mathbf…
user142971
0
votes
0 answers

Incorrect proof of Morrey's conjecture

Morrey conjectured that Rank 1 convexity does not imply quasiconvexity and this was shown to be true for $n \geq 3$ by V.Sverak. Are there any proofs (rather failed attempts) which went about trying to show Rank-1 convex functions are quasiconvex?…
Adi
  • 247
0
votes
1 answer

Show that functional is constant at stationary solution

Let $F=F\left(y, y^\prime, y^{\prime\prime}, x\right) = F\left(y^\prime, y^{\prime\prime}\right)$ and define $$H = H\left(y^\prime, y^{\prime\prime}\right) = y^{\prime\prime}\frac{\partial F}{\partial y^{\prime\prime}} - y^\prime…
nimble agar
  • 309
0
votes
2 answers

Find the curve connecting $(x_1,y_1)$ to $(x_2,y_2)$ that minimizes the surface area of the volume of revoluion

Given two points $(x_1,y_1)$ and $(x_2,y_2)$, find the curve $\gamma$ connecting them such that the surface area of the volume obtained when rotating the curve along the $x$-axis is minimized. First assume that the curve is given by $(x,y(x))$. Then…
Slugger
  • 5,556
0
votes
0 answers

Minimizing distance between two curves. Can the Calculus of Variations be used?

Given two curves, one might want to find the minimum distance between two points. It is fairly straightforward to find minimums of the function $$(x_1-x_2)^2+(y_1-y_2)^2$$ which corresponds to the square of the distance between two points on the…
DLV
  • 1,740
  • 4
  • 17
  • 28
0
votes
1 answer

Fastest path with limited acceleration

An object on point $A$ with the initial velocity of $\dot{\bf{x}} (t)$ have a maximal acceleration of $a$. What is the fastest path for the object to get to point $B$? I thought this should be all over the Internet but I don't know what to search…
arax
  • 2,779
0
votes
0 answers

Simple form of Euler-Lagrange equations in cylindrical polars for path of light?

What are the Euler-Lagrange equations in cylindrical coordinates $(r,\theta,z)$ for light moving at speed $v(r,\theta)$, where $r$ and $\theta$ depend on $z$? I.e. for the problem of minimising the time taken for light to get from one point to…
Harry Macpherson
  • 1,824
0
votes
1 answer

Clarifying A Calculus of Variations Problem

Let F[y] be a functional defined like so: F[y] = $\int y(x)^2 + (y'(x))^2 dx$. I'm trying to find the function y which maximizes the value of F, and because the Euler Lagrange equation specifies a necessary condition for an extremal y, this looks…
seewalker
  • 105
  • 4
1 2 3
21
22