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
2
votes
1 answer

Calculus of variation Transformation

Find the transformations that transform $$X = -y \frac{\partial}{\partial x} + x \frac{\partial}{\partial y}$$ to $\bar{X}$ = $\frac{\partial}{\partial s}$ That is X(s)=1 and X(t)=0 I know we have to solve differential equations for dependent and…
s.kadwa
  • 125
2
votes
2 answers

A variational problem with a lagrangian , what is the lagrangian?

given the 2 PDE $$ \Delta u-au_{tt}+u_{t}=0$$ and $$ \Delta u + Du*Df=0 $$ here $ \Delta u $ is the Laplacian $ Du= grad(u) $ is the gradient and * means scalar product $u_{t} = \frac{\partial u}{\partial t}$ my doubt is what term should i include…
Jose Garcia
  • 8,506
2
votes
1 answer

a variational problem involving $L^p$ norm

Is there any way to prove that there are only finitely many maximizers to the following variational problem: $$\max\left\{||f||_{L^p[0,1]}-\int_0^1(f'(t))^2dt\right\}$$ over all functions $f$ which are absolutely continuous and $f(0)=0$? We can…
user108871
  • 151
  • 6
2
votes
0 answers

Lemma of calculus of variation for Green's function!

OK, I know the title is fundamentally wrong! But I guess you know where I'm going with it! Basically, I'm wondering if it's possible to prove that if $\int_{x\in\Omega}G(x,x')h(x')dV=0$ for any $\Omega$, which includes the support of a localized…
Hossein
  • 21
2
votes
2 answers

An extremal property of the distance function

Let $\Omega \subseteq \mathbb{R}^N$ be open and bounded, let $\mathcal{I}:C(\overline{\Omega}) \ni u\mapsto \int_\Omega u(x)\ \text{d} x \in \mathbb{R}$ and set: $$\phi(x):=\text{dist} (x,\partial \Omega) =\inf_{y\in \partial \Omega} |x-y|$$ for…
Pacciu
  • 6,251
2
votes
0 answers

Broken Extremal.

Consider the Functional $$J(y)=\int_0^2(1-y’^2)^2dx$$ defined on $$\{y\in C[0,2]\mid \text{y is piecewise $C^1$ and $y(0)=y(2)=0$}\}$$ Let $y_e$ be a minimizer of the above functional. Then $y_e$ has $1.$ A unique corner point. $2.$ Two corner point…
neelkanth
  • 6,048
  • 2
  • 30
  • 71
2
votes
1 answer

Find function that maximizes value at x = 1

I have conjured a problem, for which I believe I have numerically found the solution for, but for which I am not sure about. I'm not able to solve it analytically (or maybe only a numerical approach would work). It goes like this: For the family of…
Gandhal
  • 23
2
votes
1 answer

Lagrangian and corresponding functional

Here is a question : Consider the Lagrangian $L(x, u, p) = 1/2((p^2 -1)^2) +1/2(u^2)$ and consider the corresponding functional $I(u)$ := $\int_0^1$ $L(x, u(x), u′ (x)) dx.$ Consider $A := \{w\in C^1: w(0)=w(1)=0\}$. Answer the following questions…
Lalbahadur Sahu
  • 99
2
votes
1 answer

Is there a piecewise differentiable minimizer that vanishes at the endpoints of [0,1] of $I(u) = \int_0^1 e^{−u'^2(x)}dx$?

I am working on this problem Consider the functional $I=\int^a_b f (u'(x))dx$; where $f \in C^1(\mathbb{R}; \mathbb{R})$ and $u \in \Phi =\{ u \in$ $D^1([a, b]; \mathbb{R})| u(a) = \alpha; u(b) = \beta \}$, for given $\alpha; \beta \in…
some_math_guy
  • 3,230
2
votes
0 answers

Boundary conditions in variational problems

I'm having trouble understanding how appropriate boundary conditions are obtained as part of deriving the Euler-Lagrange equations for a given variational problem. Using the particular example I'm working on at the moment, suppose we wish to…
Othman El Hammouchi
  • 734
  • 4
  • 12
2
votes
0 answers

Variation of arctan with respect to $q$ and $p$

How can I obtain the variation of $$y = \arctan(\frac{q}{p})$$ For example the variation of $\delta (x^2) = 2x\delta x$. Since there's both $q$ and $p$, I was not sure how to approach the problem. Because I need to obtain the variation of both. I…
seVenVo1d
  • 452
2
votes
1 answer

Simple second variation

I am new to calculus of variation and try to understand some simple special cases. In particular, what is the second variation for a functional $$J[y]=\int_{a}^{b} F(x, y(x)) dx$$ without the $y'(x)$ term in $F$? Is it $$ \frac{1}{2}\int_{a}^{b}…
Benjiaming Fung
  • 443
2
votes
0 answers

Finding the extremal of the problem $ I[y(x)] = \int_{x_1}^{x_2} \sqrt{ 1+ \left( \frac{dy}{dx} \right)^2 }dx $

This is a question from a mathematical contest. Let $y=y(x)$ be the extremal of the functional $$ I[y(x)] = \int_{x_1}^{x_2} \sqrt{ 1+ \left( \frac{dy}{dx} \right)^2 }dx $$ Subject to the condition that the left end of the extremal moves along…
Kashif
  • 710
2
votes
1 answer

Basis for solution space of Jacobi accessory equation

The Jacobi accessory equation has importance as a means of checking candidates for functional extrema. A book of mine ($\textit{Calculus of variations}$, by van Brunt) proves that we can find solutions to the Jacobi accessory equation by…
Mr. Chip
  • 5,009
2
votes
1 answer

Variation vs Differential

I am a bit confused about the difference between variation $\delta u$ and differential $du$. I saw them in terms of minimizing a functional. The way the variation operates seems very similar to derivatives (chain-rule and so on). I have a hunch that…
User 10482
  • 113
1 2 3
21 22