Euler-Lagrange equation: Difference between revisions

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The '''Euler-Lagrange equation''' of a functional <math>L(u)</math> is an equation which is necessarily satisfied (formally, at least) by critical points of that functional.  It can be computed formally by starting with the equation
The '''Euler-Lagrange equation''' of a functional <math>L(u)</math> is an equation which is necessarily satisfied (formally, at least) by critical points of that functional.  It can be computed formally by starting with the equation


<center><math>\frac{d}{d\eps} L(u+\eps v)|_{\eps = 0} = 0 </math></center>
<center><math>\frac{d}{d\epsilon} L(u+\epsilon v)|_{\epsilon = 0} = 0 </math></center>


for arbitrary test functions ''v'', and then using duality to eliminate ''v''.
for arbitrary test functions ''v'', and then using duality to eliminate ''v''.

Revision as of 01:46, 15 August 2006


The Euler-Lagrange equation of a functional is an equation which is necessarily satisfied (formally, at least) by critical points of that functional. It can be computed formally by starting with the equation

for arbitrary test functions v, and then using duality to eliminate v.

Equations which are Hamiltonian can (in principle, at least) be expressed as the Euler-Lagrange equation of a functional, and conversely Euler-Lagrange equations can in principle be reformulated in a Hamiltonian manner.