Abstract
An emerging technique in image segmentation, semi-supervised learning and general classification problems concerns the use of phase-separating flows defined on finite graphs. This technique was pioneered in Bertozzi and Flenner (2012, Multiscale Modeling and Simulation10(3), 1090–1118), which used the Allen–Cahn flow on a graph, and was then extended in Merkurjev et al. (2013, SIAM J. Imaging Sci.6(4), 1903–1930) using instead the Merriman–Bence–Osher (MBO) scheme on a graph. In previous work by the authors, Budd and Van Gennip (2020, SIAM J. Math. Anal.52(5), 4101–4139), we gave a theoretical justification for this use of the MBO scheme in place of Allen–Cahn flow, showing that the MBO scheme is a special case of a ‘semi-discrete’ numerical scheme for Allen–Cahn flow. In this paper, we extend this earlier work, showing that this link via the semi-discrete scheme is robust to passing to the mass-conserving case. Inspired by Rubinstein and Sternberg (1992, IMA J. Appl. Math.48, 249–264), we define a mass-conserving Allen–Cahn equation on a graph. Then, with the help of the tools of convex optimisation, we show that our earlier machinery can be applied to derive the mass-conserving MBO scheme on a graph as a special case of a semi-discrete scheme for mass-conserving Allen–Cahn. We give a theoretical analysis of this flow and scheme, proving various desired properties like existence and uniqueness of the flow and convergence of the scheme, and also show that the semi-discrete scheme yields a choice function for solutions to the mass-conserving MBO scheme.
Highlights
In this paper, we will investigate variants of the Allen–Cahn equation and Merriman–Bence– Osher (MBO) scheme on a graph, modified to ensure that mass is conserved along trajectories
We have shown a new result, that shows that the semi-discrete scheme link between the Allen–Cahn flow and the MBO scheme in the non-mass-conserving case is robust in the presence of a mass constraint
We showed that the MBO scheme was a special time discretisation of Allen–Cahn flow with a double-obstacle potential and investigated properties of this Allen–Cahn flow and time discretisation scheme
Summary
We will investigate variants of the Allen–Cahn equation and Merriman–Bence– Osher (MBO) scheme on a graph, modified to ensure that mass is conserved along trajectories. We formulate on a graph the mass-conserving Allen–Cahn flow devised by Rubinstein and Sternberg [34], noticing that mass conservation continues to hold in the discrete setting. Following our earlier work in [14] and drawing on work in Van Gennip [37], we show that formulation of a mass-conserving MBO scheme arises naturally as a special case of a semidiscrete scheme for the mass-conserving Allen–Cahn flow with the double-obstacle potential. We examine various theoretical properties of this mass-conserving semi-discrete scheme
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