Euler-Lagrange equation: Difference between revisions

Revision as of 01:46, 15 August 2006

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The Euler-Lagrange equation of a functional $L(u)$ 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

{\frac {d}{d\epsilon }}L(u+\epsilon v)|_{\epsilon =0}=0

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.

@@ Line 3: / Line 3: @@
 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''.

Euler-Lagrange equation: Difference between revisions

Revision as of 01:46, 15 August 2006

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