Learning a Lie Algebra from Unlabeled Data Pairs
Abstract
Deep convolutional networks (convnets) show a remarkable ability to learn disentangled representations. In recent years, the generalization of deep learning to Lie groups beyond rigid motion in has allowed to build convnets over datasets with non-trivial symmetries, such as patterns over the surface of a sphere. However, one limitation of this approach is the need to explicitly define the Lie group underlying the desired invariance property before training the convnet. Whereas rotations on the sphere have a well-known symmetry group (), the same cannot be said of many real-world factors of variability. For example, the disentanglement of pitch, intensity dynamics, and playing technique remains a challenging task in music information retrieval. This article proposes a machine learning method to discover a nonlinear transformation of the space which maps a collection of -dimensional vectors onto a collection of target vectors . The key idea is to approximate every target by a matrix--vector product of the form , where the matrix belongs to a one-parameter subgroup of . Crucially, the value of the parameter may change between data pairs and does not need to be known in advance.
Cite
@article{arxiv.2009.09321,
title = {Learning a Lie Algebra from Unlabeled Data Pairs},
author = {Christopher Ick and Vincent Lostanlen},
journal= {arXiv preprint arXiv:2009.09321},
year = {2020}
}
Comments
2 pages, 1 figure. Presented at the first DeepMath conference, New York City, NY, USA, November 2020