Manifold Learning for Latent Variable Inference in Dynamical Systems

Ronen Talmon; Stephane Mallat; Hitten Zaveri; Ronald R. Coifman

doi:10.1109/TSP.2015.2432731

Manifold Learning for Latent Variable Inference in Dynamical Systems

Ronen Talmon, Stephane Mallat, Hitten Zaveri, Ronald R. Coifman

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

We study the inference of latent intrinsic variables of dynamical systems from output signal measurements. The primary focus is the construction of an intrinsic distance between signal measurements, which is independent of the measurement device. This distance enables us to infer the latent intrinsic variables through the solution of an eigenvector problem with a Laplace operator based on a kernel. The signal geometry and its dynamics are represented with nonlinear observers. An analysis of the properties of the observers that allow for accurate recovery of the latent variables is given, and a way to test whether these properties are satisfied from the measurements is proposed. Scattering and window Fourier transform observers are compared. Applications are shown on simulated data, and on real intracranial Electroencephalography (EEG) signals of epileptic patients recorded prior to seizures.

Original language	English
Article number	7105924
Pages (from-to)	3843-3856
Number of pages	14
Journal	IEEE Transactions on Signal Processing
Volume	63
Issue number	15
DOIs	https://doi.org/10.1109/TSP.2015.2432731
State	Published - 1 Aug 2015

Keywords

Intrinsic modeling
kernel methods
manifold learning
nonlinear observers
scattering transform

All Science Journal Classification (ASJC) codes

Signal Processing
Electrical and Electronic Engineering

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10.1109/TSP.2015.2432731

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title = "Manifold Learning for Latent Variable Inference in Dynamical Systems",

abstract = "We study the inference of latent intrinsic variables of dynamical systems from output signal measurements. The primary focus is the construction of an intrinsic distance between signal measurements, which is independent of the measurement device. This distance enables us to infer the latent intrinsic variables through the solution of an eigenvector problem with a Laplace operator based on a kernel. The signal geometry and its dynamics are represented with nonlinear observers. An analysis of the properties of the observers that allow for accurate recovery of the latent variables is given, and a way to test whether these properties are satisfied from the measurements is proposed. Scattering and window Fourier transform observers are compared. Applications are shown on simulated data, and on real intracranial Electroencephalography (EEG) signals of epileptic patients recorded prior to seizures.",

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AU - Mallat, Stephane

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N2 - We study the inference of latent intrinsic variables of dynamical systems from output signal measurements. The primary focus is the construction of an intrinsic distance between signal measurements, which is independent of the measurement device. This distance enables us to infer the latent intrinsic variables through the solution of an eigenvector problem with a Laplace operator based on a kernel. The signal geometry and its dynamics are represented with nonlinear observers. An analysis of the properties of the observers that allow for accurate recovery of the latent variables is given, and a way to test whether these properties are satisfied from the measurements is proposed. Scattering and window Fourier transform observers are compared. Applications are shown on simulated data, and on real intracranial Electroencephalography (EEG) signals of epileptic patients recorded prior to seizures.

AB - We study the inference of latent intrinsic variables of dynamical systems from output signal measurements. The primary focus is the construction of an intrinsic distance between signal measurements, which is independent of the measurement device. This distance enables us to infer the latent intrinsic variables through the solution of an eigenvector problem with a Laplace operator based on a kernel. The signal geometry and its dynamics are represented with nonlinear observers. An analysis of the properties of the observers that allow for accurate recovery of the latent variables is given, and a way to test whether these properties are satisfied from the measurements is proposed. Scattering and window Fourier transform observers are compared. Applications are shown on simulated data, and on real intracranial Electroencephalography (EEG) signals of epileptic patients recorded prior to seizures.

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M3 - مقالة

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JO - IEEE Transactions on Signal Processing

JF - IEEE Transactions on Signal Processing

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Manifold Learning for Latent Variable Inference in Dynamical Systems

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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