English

Flat Norm Decomposition of Integral Currents

Differential Geometry 2017-08-08 v4 Computational Geometry Algebraic Topology

Abstract

Currents represent generalized surfaces studied in geometric measure theory. They range from relatively tame integral currents representing oriented compact manifolds with boundary and integer multiplicities, to arbitrary elements of the dual space of differential forms. The flat norm provides a natural distance in the space of currents, and works by decomposing a dd-dimensional current into dd- and (the boundary of) (d+1)(d+1)-dimensional pieces in an optimal way. Given an integral current, can we expect its flat norm decomposition to be integral as well? This is not known in general, except in the case of dd-currents that are boundaries of (d+1)(d+1)-currents in Rd+1\mathbb{R}^{d+1} (following results from a corresponding problem on the L1L^1 total variation (L1L^1TV) of functionals). On the other hand, for a discretized flat norm on a finite simplicial complex, the analogous statement holds even when the inputs are not boundaries. This simplicial version relies on the total unimodularity of the boundary matrix of the simplicial complex -- a result distinct from the L1L^1TV approach. We develop an analysis framework that extends the result in the simplicial setting to one for dd-currents in Rd+1\mathbb{R}^{d+1}, provided a suitable triangulation result holds. In R2\mathbb{R}^2, we use a triangulation result of Shewchuk (bounding both the size and location of small angles), and apply the framework to show that the discrete result implies the continuous result for 11-currents in R2\mathbb{R}^2.

Keywords

Cite

@article{arxiv.1411.0882,
  title  = {Flat Norm Decomposition of Integral Currents},
  author = {Sharif Ibrahim and Bala Krishnamoorthy and Kevin R. Vixie},
  journal= {arXiv preprint arXiv:1411.0882},
  year   = {2017}
}

Comments

17 pages, adds some related work and applications

R2 v1 2026-06-22T06:47:27.949Z