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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a Complication of the Well Known Hanging Cable Problem - Attaching a Point Mass

Let a cable of length $L$ and uniform mass density $\rho=1$. The cable is hanging between two columns of height $h>>1$ separated by a distance $d\in(0,L)$. Let a point mass $m>0$ be attached to the cable at an arc distance $\ell\in(0,L)$ from the…
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An Area Variation Question

I have a question on a non-typical "area" variation question. Let (M,dA) be a 2 dimensional manifold and f be a smooth function. Let $\Gamma$ be a compact 2- dimensional submanifold in M whose boundary is $\gamma(s)$. Consider the…
Sina
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Fastest path for $A$ to catch $B$

I was wondering if is there a way to attack with Euler-Lagrange equation the following problem. Suppose $B$ is moving in straight line with costant velocity $\mathbf{u}=u\,\hat{x}$. What is the fastest path for an $A$, which can move with costant…
pppqqq
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Finding maximum surface area for given length Variational Calc

To find maximum surface area for given arc length on a surface of revolution using cylindrical coordinates, we have to optimize $$∫2π r \sqrt{dr^2+dz^2}+c1∫\sqrt{dr^2+dz^2+(rdθ)^2}$$ with Lagrangian form on $z$ as independent variable along symmetry…
Narasimham
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Derivation of the Euler-Lagrange equation in the isoperimetric case

In this derivation (and also here) of the Euler-Lagrange equation in the isoperimetric case, one begins with an extremising function $y$ and adds two terms, obtaining $\hat{y} = y + \epsilon_1 \eta_1 + \epsilon_2 \eta_2$, where $\epsilon_i \in…
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An isoperimetric problem

How can I find a triangle which encloses the largest area with given (total) length using caculus of variation? I know the direct method but I can't find one using variational method.
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Bolza example like Question

I have to find $u$ minimizing $\int_0^1 F$ with $F(x,u(x),u'(x)) = (1-(u'(x))^2)^2+(u(x))^2$ with $u(0) = 0$ and $u(1) = 1$. I'm relatively new to CoV and got told i should try Euler-Lagrange-Equation which gives me $2u(x) + 4u''(x) - 12{(u'(x))}^2…
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Functional of higher order derivatives

Optimization of functionals derived from the Euler-Lagrange equations is often phrased in terms of integrating a function $F$ of $x, \ f(x), \ f'(x).$ However, what if your differential form contains higher order derivatives such $f''$ or $f'''$?
PhiEarl
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Finding an Extremal for a function.

I need to find the extremals for the following function : $I(y) = \displaystyle \int_{x_0}^{x_1} \dfrac{1 + y^2}{(y')^3} dx$ So, by Euler Lagrange Equations $I_{y}$ -$d/dx(I_{y'}) = 0$ Now, using this I get : $\dfrac{2y}{y'} + \dfrac{2y}{3} =…
zeroflank
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Why $\int{\frac{dr}{r\sqrt{c^{2}r^4 -1}}} = -\frac{1}{2} \arcsin\left(\frac{1}{cr^2}\right)$?

I must solve the following integral, where $c$ is a constant $$\int{\frac{dr}{r\sqrt{c^{2}r^4 -1}}}$$ When I compute and do the calculations, I obtain that $$\int{\frac{dr}{r\sqrt{c^{2}r^4 -1}}} = \frac{1}{2} \arctan \left(\sqrt{c^{2}r^4 -1}…
Curious
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a calculus of variations question

I want to maximize $\int_0^1(g^2(x)+3g^2(x)g'(x)+2[g'(x)]^2)dx$ subject to g(0)=1, g(1)=0. I can find Euler equation but I can not find g(x) that is maximizes this integral. I have to use calculus of variations. Can you help me?
piykam
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finding minimizer of a functional using variations

Find the minimum of the functional $$I[y(x)]=\int_0^1\bigg(\frac{y'^2}{2}+yy'+y'+y\bigg)dx$$ if the values at the ends of the interval are not given. So we have a free boundary condition on both $x=0$ and $x=1$. Taking first variation of the…
am_11235...
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Showing that an operator is self-adjoint

I have an inner product $$\langle\, f,g\,\rangle = \int\int_{\Omega}f(x,y)g(x,y)r(x,y)dA$$ and I want to show that an operator, $L$, is self-adjoint with respect to the inner product by showing that $$\langle \,Lf,g\,\rangle =\langle…
natn2323
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Let $E, F$ normed spaces and $f\in\mathcal{L}(E,F)$. Prove that $\forall a\in E: f'(a)=f$

I have tried to prove it by the definition of differentiability, but I have gotten nowhere. I am not very clear how to proceed. I would really appreciate your help.
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Calculus of variations Euler-Lagrange equation and variational problem

Find all the extrema (local minima and maxima) of the function $$J[y] = \int\limits_1^2(xy' + y)^2\,\mathrm dx;\qquad y(1) = 1, y(2) = \dfrac12.$$ Hint. Once you've found the solution of the Euler-Lagrange equation with the boundary conditions,…