English

Shape Partitioning via L$_p$ Compressed Modes

Numerical Analysis 2018-04-23 v1

Abstract

The eigenfunctions of the Laplace Beltrami operator (Manifold Harmonics) define a function basis that can be used in spectral analysis on manifolds. In [21] the authors recast the problem as an orthogonality constrained optimization problem and pioneer the use of an L1L_1 penalty term to obtain sparse (localized) solutions. In this context, the notion corresponding to sparsity is compact support which entails spatially localized solutions. We propose to enforce such a compact support structure by a variational optimization formulation with an LpL_p penalization term, with 0<p<10<p<1. The challenging solution of the orthogonality constrained non-convex minimization problem is obtained by applying splitting strategies and an ADMM-based iterative algorithm. The effectiveness of the novel compact support basis is demonstrated in the solution of the 2-manifold decomposition problem which plays an important role in shape geometry processing where the boundary of a 3D object is well represented by a polygonal mesh. We propose an algorithm for mesh segmentation and patch-based partitioning (where a genus-0 surface patching is required). Experiments on shape partitioning are conducted to validate the performance of the proposed compact support basis.

Keywords

Cite

@article{arxiv.1804.07620,
  title  = {Shape Partitioning via L$_p$ Compressed Modes},
  author = {Martin Huska and Damiana Lazzaro and Serena Morigi},
  journal= {arXiv preprint arXiv:1804.07620},
  year   = {2018}
}
R2 v1 2026-06-23T01:29:54.870Z