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

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Use a varied function to show that a straight line is the minimum distance between 2 points.

I have the following problem, and I don't know where to begin. Consider the curve connecting $(x_0,y_0) = (0,0)$ and $(x_1,y_1) = (1,1)$. Show by explicit computation that the function $y(x) =x$ produces a minimum path length between these points…
Jake
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Curve minimising distance between two points in $ \mathbb{R}^2 $ with a circular obstacle

Minimisation functional problem $$ \min_{y} \int _ {(-\beta,0)}^A\sqrt{(\dot{y}(x))^2+1} dx \mbox{ such that } x^2+y(x)^2\geq R^2$$ Scaling everything, take $R=1, \beta >1$ Starting at $(-\beta,0)$ find the path with minimum distance taking you…
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Show that minimum exists (direct method)

Consider $$ F(v):=\int\limits_0^1\lvert v'(x)\rvert^2\, dx, $$ with $$ \left\{v\in H^{1,2}(0,1), v(0)=0=v(1)\right\}. $$ Show that a minimum exists and use the direct method. When I am right informed, I have to show that: 1.) $H^{1,2}(0,1)$ is…
user34632
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How to show that the variational problem does not attain its infimum

Let $X=\left\{f\in C^1[0,1]: f(0)=0=f(1)\right\}$. Define $J:X \to \Bbb R$ by $J(f)=\int\limits^1_0 e^{-f^\prime (x)^2}dx.$ How to show that $J$ does not attain its infimum. If $F(x,f,f^\prime)=e^{-f^\prime (x)^2}$, using the Euler-Lagrange…
user149418
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Finding a minimal of the following variational problem

Let $X=\left\{f\in C^1[0,1]: f(0)=0=f(1)\right\}$. Define $J:X \to \Bbb R$ by $J(f)=\int\limits^1_0 \left(f^\prime (x)^2-4\pi^2 f(x)^2\right)dx.$ Does $\inf\limits_{f\in X}J(f)$ exist? If $F(x,f,f^\prime)=\left(f^\prime(x)^2-4\pi^2 f(x)^2\right)$,…
user149418
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Strange things about Gelfand-Fomin first variation formula

This is a possible duplicate of this question and probably a few others. However, the question I have on my mind seems to be unanswered. On p. 14 in The calculus of variations by Gelfand and Fomin, the following formula $$ \int_{a}^{b}…
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nature of a stationary path

for my functional $S[y]=\int\limits^{1}_{0}dx(y')^{n}e^{y}\,,$ $y(0)=1,y(1)=A>1$ i have found the stationary path to be $y=n$ln$(cx+e^{1/n})$, where $c=e^{A/n}-e^{1/n}$ i have then found the Jacobi equation to be $2c(cx+d)u'+(cx+d)^2u''=0$ which…
jiboom
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Calculus of variations - minimizing distance squared instead of distance

Very basic question, but we have recently gone over the topic of geodesics in class and I was wondering whether it was permissible to apply Euler-Lagrange to find the extremal of say $ \int \text d s^2 $ instead of the ordinary arc length. I've…
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Variational Calculus problem to determine when variation has local minimum

A function $y(x)$ is defined on $[0,1]$ such that $y(0) = y(1) = 0$. Consider the functional $F[y] = \int\limits_0^1 \frac{1}{2}(y')^2+g(y) \ dx$ where $g(y)$ is a function s.t. $g'(0) = 0$. The Euler-Lagrange equation for this is then $g'(y) =…
Hadi Khan
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A given functional is path independent if k equals to the one of the following:

The functional $$\int_0^1 (y^{\prime 2} + (y + 2y')y'' + kxyy' + y^2) ~dx,$$ $$y(0) = 0, ~y(1) = 1, ~y'(0) = 2, ~y'(1) = 3$$ is path independent if $k$ equals (A) $1$ (B) $2$ (C) $3$ (D) $4$ I have used Euler's formula for extremizing the given…
learner
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Functional derivative of the function $\phi(y,y',x)$ w.r.t. $y$

I have been reading 'Lagrangians and Hamiltonians' by Patrick Hamill and it states that the functional derivative of a function $\phi = \phi(y, y', x)$ w.r.t. $y$, where $y=y(x)$ and $y' = \frac{dy}{dx}$ is given by $$ \frac{\delta \phi}{\delta y}…
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Calculus of variations constraints with different boundaries

If I have a variational problem of the form: $$\min \int_{a}^{b} F(x, y(x), y'(x)dx\quad\text{subject to}\quad \int_{a}^{b} G(x, y(x), y'(x))dx=C\tag{1}$$ The solution can be found by transforming the problem into an unconstrained problem: $$\min…
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Check for understanding

I'm learning how to use Calculus of Variations by applying the process to a problem for research. I'm fairly certain a multiplicity of questions such as these have been asked; to help those like myself, I'll try to be as explicit as possible. In…
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Calculus of Variations: Jacobi Equation

I am a little bit confused when it comes to finding the Euler Lagrange equation of the Jacobi equation $$J(\phi) = \int^b_a f_{uu}\phi^2 + f_{uv}\phi \phi_x + f_{vv}\phi_x^2$$ The Euler Lagrange equation is $$J_\phi - \frac{d}{dx} J_{\phi_x} =…
user197848
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A question in calculus of variations

Consider the functional $$\int_0^1 \sqrt{\left(\frac{dx}{dt}\right)^2+\left(\frac{dy}{dt}\right)^2}\,dt$$ where (x(t),y(t)) is a $C^2$ curve in the plane. Firstly, How can I derive Euler-Lagrange equations? Secondly, How to prove that the smooth…
Rock
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