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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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Proving a variant of the lemma of calculus of variations

According to the fundamental lemma of calculus of variations, if $$ \int\limits_a^b f(x)h(x) dx = 0 $$ for an arbitrary $h(x)$, then $f(x) = 0$, for $x$ in $[a, b]$. Of course, accompanied by the usual assumptions. Now, for the case where $$…
jsp13
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Lagrange multiplier Calculus of variations

considering the problem $$\text{max} \int_0^1 v\ dx$$ $$\int_0^1 \sqrt{1+v'^2}\ dx=1$$ I would like to solve it with the Lagrange multipliers. the Lagrangian is $$\mathcal L(v,v')=\int_0^1v-\lambda \sqrt{1+v'^2}dx=\int_0^1 l(v,v')dx$$ and now I…
Davide Maran
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Constrained variational calculus: Are we allowed to make use of the constraint before taking variations?

Suppose that we have a variational problem, $\int_{t_1}^{t_2}f(\vec{x}(t),\vec{x}'(t),|\vec{x}(t)|)dt$ subject to the constraint: $|\vec{x}|=1$ where $\vec{x}(t)=\left\{x_1(t),x_2(t),x_3(t) \right\}.$ Are we allowed to rewrite the integral as…
Tarek
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Constructing an $C^{\infty}$ function, radius $\delta$, centered at $(a,b)$

I'm wondering how to construct a $C^{\infty}$ function which is positive on an open disk of radius $\delta$, centered at the point $(a,b)$ and vanishing outside of the disk. I know that in 1D, a function like $f(x)=e^{-(b-x)^{-1}} \cdot…
natn2323
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Euler-Lagrange Query

Given F: $$ F(x,y,y\prime) = 2\cdot \pi \cdot y \cdot \sqrt{1+(y\prime)^2} $$ We can derive the following Euler-Lagrange equation (I know how to do this part): $$ \frac{d}{dx}\left(\frac{y\cdot y\prime}{\sqrt{1+(y\prime)^2}}\right) -…
Mike
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Simple question on calculus of variations: critical point of functional subject to constraint

Let $V$ be the set of smooth functions $f:[0,1]\to \mathbb{R}$ such that $\int_0^1 f(t) dt =k$. If $F:V\to\mathbb{R}$ is given by $F(f) = \int_0^1 f(t)^2 dt$, show that the only critical point of $F$ is the constant function $f(t)=k$.
user55225
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calculus of variations, don't understand why calculate the second order derivative that way

I am learning calculus of variations and met the following example: Find the extremal of the functional v[y]= ∫ (12ty+(y’)^2)dt, where y=y(t) let F= 12ty+(y’)^2, using the Euler rule, we need to calculate the second order derivative of F with…
thisisjayliu
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Minimization of energy using calculus of variations

I have a math problem coming from physics. How do you push an object $1$ m in $1$ sec under the force $F=-v^2$, so the energy used is minimal? We have to minimize $$\int_0^1\left(\frac{1}{2}a^2+v'(t)*v(t)+v(t)^3 \right) dt$$ under the…
Foldager
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Functional derivative: nested integral

I'm trying to solve the following problem: find $$ \frac{\delta J[f](x)}{\delta f(x')} $$ where $$ J[f](x) = \int_a^x \frac{1}{f(x')} \left( \int_b^{x'} f(x'')dx'' \right) dx' $$ I can't seem to find any resources that discuss how to deal with the…
Nick Woods
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Boundary conditions of Timoshenko equation

On Wikipedia derivation on Timoshenko beam equation we arrive at this: $$ \delta U = \int_L \left[-M_{xx}\frac{\partial (\delta\varphi)}{\partial x} + Q_{x}\left(-\delta\varphi + \frac{\partial (\delta w)}{\partial x}\right)\right]~\mathrm{d}L…
S. Rotos
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Prove two functionals admit the same extremals

Let $f \in C^1(\mathbb{R}^3)$ and $u \in C^2(\mathbb{R}^2)$. Prove that the two following functionals admit the same extremals: $$I(y) = \int_a^b f(x,y,y')\; \text{d}x\text{ and }J(y) = \int_a^b f(x,y,y')+\frac{\partial u}{\partial x}(x,y)+…
user401936
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How to constrain function to be capped by a maximal value in a variational problem?

In a variational problem, where one seeks function $y(x)$ that is an extreme of a functional $$ J[y]=\int_a^b L(y(x), y'(x), x) \, dx\;, $$ one can constrain $y(x)$ by condition $$ C[y]=\int_a^b G(y(x), y'(x), x) \, dx=g $$ by the formalism of…
Irigi
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Arclength integral result does not correspond to intuition

Consider the problem of finding the first variation $\delta_{y_0}J$ for $J(y)=\int_0^1\sqrt{1+y'(x)^2}\,\text{d}x$, given $y_0(x)=ax+b$. I don't know if I'm proceeding correctly and the answer I'm getting does not match my intuition for the problem.…
user401936
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A problem in variational calculus

How do you maximize the quotient ||f||/||f'|| of euclidean norms if f is to be a function on [0,1] which vanishes on the boundary? $||g||^2 = \int_0^1g(x)^2\textrm{d}x$ I guess $f$ needs to be continuously differentiable for it to make sense or…
Joel Sjögren
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a question related to calculus of variations

Consider a particle with coordinates $(x(t),y(t))$ on a smooth curve $\phi(x,y)=0$. If the particle moves from $(x(0),y(0))$ to $(x(\tau),y(\tau))$ for $\tau >0$ such that its kinetic energy is minimized, then $(a)$…
am_11235...
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