Given a collection of (unlabelled) data inhabiting some high dimensional space, can you determine whether they actually lie on some lower dimensional manifold in this space ?This talk was a great window into an area of machine learning with strong geometric connections, an area where geometers could profitably play and make useful contributions.
Now NIPS (one of the major machine learning conferences) is returning the favor, with a workshop devoted to the topic of Topology Learning:
The list of invited speakers bridges geometry, topology and learning. It looks like a great forum for continuing the machine learning-computational geometry cross-talk that Partha kicked off at SoCG.
There is a growing interest in Machine Learning, in applying geometrical and topological tools to high-dimensional data analysis and processing.
Considering a finite set of points in a high-dimensional space, the approaches developed in the field of Topology Learning intend to learn, explore and exploit the topology of the shapes (topological invariants such as the connectedness, the intrinsic dimension or the Betti numbers), manifolds or not, from which these points are supposed to be drawn.
Applications likely to benefit from these topological characteristics have been identified in the field of Exploratory Data Analysis, Pattern Recognition, Process Control, Semi-Supervised Learning, Manifold Learning and Clustering.
However it appears that the integration in the Machine Learning and Statistics frameworks of the problems we are faced with in Topology Learning, is still in its infancy. So we wish this workshop to ignite cross-fertilization between Machine Learning, Computational Geometry and Topology, likely to benefit to all of them by leading to new approaches, deeper understanding, and stronger theoretical results about the problems carried by Topology Learning.