Computational Analysis of Deformable Manifolds: from Geometric Modelling to Deep Learning

TL;DR

This paper explores geometric methods for shape processing and data analysis on manifolds, integrating differential geometry, PDE modeling, and deep learning to handle high-dimensional, deformable data.

Contribution

It introduces novel techniques for non-isometric shape matching, generalizes CNNs to deformable manifolds, and proposes an auto-regressive model capturing intrinsic data geometry.

Findings

Effective non-isometric shape matching via variational models

Generalized convolutional neural networks for deformable manifolds

A new auto-regressive model for intrinsic data geometry

Abstract

Leo Tolstoy opened his monumental novel Anna Karenina with the now famous words: Happy families are all alike; every unhappy family is unhappy in its own way A similar notion also applies to mathematical spaces: Every flat space is alike; every unflat space is unflat in its own way. However, rather than being a source of unhappiness, we will show that the diversity of non-flat spaces provides a rich area of study. The genesis of the so-called big data era and the proliferation of social and scientific databases of increasing size has led to a need for algorithms that can efficiently process, analyze and, even generate high dimensional data. However, the curse of dimensionality leads to the fact that many classical approaches do not scale well with respect to the size of these problems. One technique to avoid some of these ill-effects is to exploit the geometric structure of coherent data. In this thesis, we will explore geometric methods for shape processing and data analysis. More specifically, we will study techniques for representing manifolds and signals supported on them through a variety of mathematical tools including, but not limited to, computational differential geometry, variational PDE modeling, and deep learning. First, we will explore non-isometric shape matching through variational modeling. Next, we will use ideas from parallel transport on manifolds to generalize convolution and convolutional neural networks to deformable manifolds. Finally, we conclude by proposing a novel auto-regressive model for capturing the intrinsic geometry and topology of data. Throughout this work, we will use the idea of computing correspondences as a though-line to both motivate our work and analyze our results.