User:DVD206/Printed Version/Harmonic functions

Harmonic functions can be defined as solutions of differential and difference Laplace equation as follows.

A function/vector u defined on the vertices of a graph w/boundary is harmonic if its value at every interior vertex p is the average of its values at neighboring vertices. That is,

${\displaystyle u(p)=\sum _{p\rightarrow q}\gamma (pq)u(q)/\sum _{p\rightarrow q}\gamma (pq).}$

Or, alternatively, u satisfies Kirchhoff law for potential at every interior vertex p:

${\displaystyle \sum _{p\rightarrow q}\gamma (pq)(u(p)-u(q))=0.}$

Harmonic function on a manifold M is a twice continuously differentiable function u : M → R, where u satisfies Laplace equation:

${\displaystyle \Delta _{\gamma }u=\nabla \cdot (\gamma \nabla u)=0.}$

Harmonic function defined on open subset of the plane satisfies the following differential equation:

${\displaystyle (\gamma u_{x})_{x}+(\gamma u_{y})_{y}=0.}$

The harmonic functions satisfy the following properties:

• mean-value property,

The value of a harmonic function is a weighted average of its values at the neighbor vertices,

• maximum principle,

(corollary), the maximum (and the minimum) of a harmonic functions occurs on the boundary of the graph or the manifold,

• harmonic conjugate,

the system of Cauchy-Riemann equations,

${\displaystyle {\begin{cases}\gamma u_{x}=v_{y},\\\gamma u_{y}=-v_{x}\end{cases}}}$

can be used to define the harmonic conjugate,

• harmonic continuation

is an extension of the domain of definition of a given harmonic function.

Dirichlet problem[edit | edit source]

Harmonic functions minimize the energy integral or the sum:

${\displaystyle \int _{\Omega }\gamma |\nabla u|^{2}{\mbox{ and }}\sum _{e=(p,q)\in E}\gamma (e)(u(p)-u(q))^{2}}$

if the values of the functions are fixed at the boundary of the domain or the network in the continuous and discrete models respectively. The minimizing function/vector is the solution of the Dirichlet problem with the prescribed boundary data.