In mathematics, the Dirichlet energy is a measure of how variable a function is. More abstractly, it is a quadratic functional on the Sobolev space H1. The Dirichlet energy is intimately connected to Laplace's equation and is named after the German mathematician Peter Gustav Lejeune Dirichlet.

Definition

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Given an open set Ω ⊆ Rn and a function u : Ω → R the Dirichlet energy of the function u is the real number

 

where u : Ω → Rn denotes the gradient vector field of the function u.

Properties and applications

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Since it is the integral of a non-negative quantity, the Dirichlet energy is itself non-negative, i.e. E[u] ≥ 0 for every function u.

Solving Laplace's equation   for all  , subject to appropriate boundary conditions, is equivalent to solving the variational problem of finding a function u that satisfies the boundary conditions and has minimal Dirichlet energy.

Such a solution is called a harmonic function and such solutions are the topic of study in potential theory.

In a more general setting, where Ω ⊆ Rn is replaced by any Riemannian manifold M, and u : Ω → R is replaced by u : M → Φ for another (different) Riemannian manifold Φ, the Dirichlet energy is given by the sigma model. The solutions to the Lagrange equations for the sigma model Lagrangian are those functions u that minimize/maximize the Dirichlet energy. Restricting this general case back to the specific case of u : Ω → R just shows that the Lagrange equations (or, equivalently, the Hamilton–Jacobi equations) provide the basic tools for obtaining extremal solutions.

See also

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  • Dirichlet's principle – Concept in potential theory
  • Dirichlet eigenvalue – fundamental modes of vibration of an idealized drum with a given shape
  • Total variation – Measure of local oscillation behavior
  • Bounded mean oscillation – real-valued function whose mean oscillation is bounded
  • Harmonic map – smooth map that is a critical point of the Dirichlet energy functional
  • Capacity of a set – In Euclidean space, a measure of that set's "size"

References

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  • Lawrence C. Evans (1998). Partial Differential Equations. American Mathematical Society. ISBN 978-0821807729.