THE MANIFOLD SCATTERING TRANSFORM FOR HIGH-DIMENSIONAL POINT CLOUD DATA

Joyce Chew; Holly Steach; Siddharth Viswanath; Hau Tieng Wu; Matthew Hirn; Deanna Needell; Matthew D. Vesely; Smita Krishnaswamy; Michael Perlmutter

THE MANIFOLD SCATTERING TRANSFORM FOR HIGH-DIMENSIONAL POINT CLOUD DATA

Joyce Chew, Holly Steach, Siddharth Viswanath, Hau Tieng Wu, Matthew Hirn, Deanna Needell, Matthew D. Vesely, Smita Krishnaswamy, Michael Perlmutter

Mathematics Department

Research output: Contribution to journal › Conference article › peer-review

4 Scopus citations

Abstract

The manifold scattering transform is a deep feature extractor for data defined on a Riemannian manifold. It is one of the first examples of extending convolutional neural network-like operators to general manifolds. The initial work on this model focused primarily on its theoretical stability and invariance properties but did not provide methods for its numerical implementation except in the case of two-dimensional surfaces with predefined meshes. In this work, we present practical schemes, based on the theory of diffusion maps, for implementing the manifold scattering transform to datasets arising in naturalistic systems, such as single cell genetics, where the data is a high-dimensional point cloud modeled as lying on a low-dimensional manifold. We show that our methods are effective for signal classification and manifold classification tasks.

Original language	English
Pages (from-to)	67-78
Number of pages	12
Journal	Proceedings of Machine Learning Research
Volume	196
State	Published - 2022
Event	ICML Workshop on Topology, Algebra, and Geometry in Machine Learning, TAG:ML 2022 - Virtual, Online, United States Duration: 20 Jul 2022 → …

Cite this

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title = "THE MANIFOLD SCATTERING TRANSFORM FOR HIGH-DIMENSIONAL POINT CLOUD DATA",

abstract = "The manifold scattering transform is a deep feature extractor for data defined on a Riemannian manifold. It is one of the first examples of extending convolutional neural network-like operators to general manifolds. The initial work on this model focused primarily on its theoretical stability and invariance properties but did not provide methods for its numerical implementation except in the case of two-dimensional surfaces with predefined meshes. In this work, we present practical schemes, based on the theory of diffusion maps, for implementing the manifold scattering transform to datasets arising in naturalistic systems, such as single cell genetics, where the data is a high-dimensional point cloud modeled as lying on a low-dimensional manifold. We show that our methods are effective for signal classification and manifold classification tasks.",

author = "Joyce Chew and Holly Steach and Siddharth Viswanath and Wu, {Hau Tieng} and Matthew Hirn and Deanna Needell and Vesely, {Matthew D.} and Smita Krishnaswamy and Michael Perlmutter",

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AU - Chew, Joyce

AU - Steach, Holly

AU - Viswanath, Siddharth

AU - Wu, Hau Tieng

AU - Hirn, Matthew

AU - Needell, Deanna

AU - Vesely, Matthew D.

AU - Krishnaswamy, Smita

AU - Perlmutter, Michael

PY - 2022

Y1 - 2022

N2 - The manifold scattering transform is a deep feature extractor for data defined on a Riemannian manifold. It is one of the first examples of extending convolutional neural network-like operators to general manifolds. The initial work on this model focused primarily on its theoretical stability and invariance properties but did not provide methods for its numerical implementation except in the case of two-dimensional surfaces with predefined meshes. In this work, we present practical schemes, based on the theory of diffusion maps, for implementing the manifold scattering transform to datasets arising in naturalistic systems, such as single cell genetics, where the data is a high-dimensional point cloud modeled as lying on a low-dimensional manifold. We show that our methods are effective for signal classification and manifold classification tasks.

AB - The manifold scattering transform is a deep feature extractor for data defined on a Riemannian manifold. It is one of the first examples of extending convolutional neural network-like operators to general manifolds. The initial work on this model focused primarily on its theoretical stability and invariance properties but did not provide methods for its numerical implementation except in the case of two-dimensional surfaces with predefined meshes. In this work, we present practical schemes, based on the theory of diffusion maps, for implementing the manifold scattering transform to datasets arising in naturalistic systems, such as single cell genetics, where the data is a high-dimensional point cloud modeled as lying on a low-dimensional manifold. We show that our methods are effective for signal classification and manifold classification tasks.

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M3 - Conference article

AN - SCOPUS:85163614169

VL - 196

SP - 67

EP - 78

JO - Proceedings of Machine Learning Research

JF - Proceedings of Machine Learning Research

T2 - ICML Workshop on Topology, Algebra, and Geometry in Machine Learning, TAG:ML 2022

Y2 - 20 July 2022

ER -

THE MANIFOLD SCATTERING TRANSFORM FOR HIGH-DIMENSIONAL POINT CLOUD DATA

Abstract

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