Phase-field models on graphs

Template:Short description Phase-field models on graphs are a discrete analogue to phase-field models, defined on a graph. They are used in image analysis (for feature identification) and for the segmentation of social networks.

For a graph with vertices V and edge weights ${\displaystyle {\omega }_{i,j}}$, the graph Ginzburg–Landau functional of a map ${\displaystyle u:V\to ℝ}$ is given by

${\displaystyle F_{\epsilon }(u)=\frac{\epsilon }{2}\sum _{i,j\in V}{\omega }_{ij}(u_i-u_j{)}^2+\frac{1}{\epsilon }\sum _{i\in V}W(u_i),}$

where W is a double well potential, for example the quartic potential W(x) = x²(1 − x²). The graph Ginzburg–Landau functional was introduced by Bertozzi and Flenner.^[1] In analogy to continuum phase-field models, where regions with u close to 0 or 1 are models for two phases of the material, vertices can be classified into those with u_j close to 0 or close to 1, and for small ${\displaystyle \epsilon }$, minimisers of ${\displaystyle F_{\epsilon }}$ will satisfy that u_j is close to 0 or 1 for most nodes, splitting the nodes into two classes.

To effectively minimise ${\displaystyle F_{\epsilon }}$, a natural approach is by gradient flow (steepest descent). This means to introduce an artificial time parameter and to solve the graph version of the Allen–Cahn equation,

${\displaystyle \frac{d}{dt}{u}_j=-\epsilon (\mathrm{\Delta }u{)}_j-\frac{1}{\epsilon }{W}^{\prime }(u_j),}$

where ${\displaystyle \mathrm{\Delta }}$ is the graph Laplacian. The ordinary continuum Allen–Cahn equation and the graph Allen–Cahn equation are natural counterparts, just replacing ordinary calculus by calculus on graphs. A convergence result for a numerical graph Allen–Cahn scheme has been established by Luo and Bertozzi.^[2]

It is also possible to adapt other computational schemes for mean curvature flow, for example schemes involving thresholding like the Merriman–Bence–Osher scheme, to a graph setting, with analogous results.^[3]

• Graph cuts in computer vision

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