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Main Authors: Liu, Xuanjie, Chin, Daniel, Huang, Yichen, Xia, Gus
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2302.10890
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author Liu, Xuanjie
Chin, Daniel
Huang, Yichen
Xia, Gus
author_facet Liu, Xuanjie
Chin, Daniel
Huang, Yichen
Xia, Gus
contents We have recently seen great progress in learning interpretable music representations, ranging from basic factors, such as pitch and timbre, to high-level concepts, such as chord and texture. However, most methods rely heavily on music domain knowledge. It remains an open question what general computational principles give rise to interpretable representations, especially low-dim factors that agree with human perception. In this study, we take inspiration from modern physics and use physical symmetry as a self consistency constraint for the latent space of time-series data. Specifically, it requires the prior model that characterises the dynamics of the latent states to be equivariant with respect to certain group transformations. We show that physical symmetry leads the model to learn a linear pitch factor from unlabelled monophonic music audio in a self-supervised fashion. In addition, the same methodology can be applied to computer vision, learning a 3D Cartesian space from videos of a simple moving object without labels. Furthermore, physical symmetry naturally leads to counterfactual representation augmentation, a new technique which improves sample efficiency.
format Preprint
id arxiv_https___arxiv_org_abs_2302_10890
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Learning Interpretable Low-dimensional Representation via Physical Symmetry
Liu, Xuanjie
Chin, Daniel
Huang, Yichen
Xia, Gus
Machine Learning
Artificial Intelligence
We have recently seen great progress in learning interpretable music representations, ranging from basic factors, such as pitch and timbre, to high-level concepts, such as chord and texture. However, most methods rely heavily on music domain knowledge. It remains an open question what general computational principles give rise to interpretable representations, especially low-dim factors that agree with human perception. In this study, we take inspiration from modern physics and use physical symmetry as a self consistency constraint for the latent space of time-series data. Specifically, it requires the prior model that characterises the dynamics of the latent states to be equivariant with respect to certain group transformations. We show that physical symmetry leads the model to learn a linear pitch factor from unlabelled monophonic music audio in a self-supervised fashion. In addition, the same methodology can be applied to computer vision, learning a 3D Cartesian space from videos of a simple moving object without labels. Furthermore, physical symmetry naturally leads to counterfactual representation augmentation, a new technique which improves sample efficiency.
title Learning Interpretable Low-dimensional Representation via Physical Symmetry
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2302.10890