Functional Subspace Variational Autoencoder for Domain-Adaptive Fault Diagnosis

Tan Li; Che Heng Fung; Him Ting Wong; Tak Lam Chan; Haibo Hu

doi:10.3390/math11132910

Functional Subspace Variational Autoencoder for Domain-Adaptive Fault Diagnosis

Tan Li
, Che Heng Fung
, Him Ting Wong
, Tak Lam Chan
, Haibo Hu

Research output: Journal article publication › Journal article › Academic research › peer-review

2 Citations (Scopus)

Abstract

This paper presents the functional subspace variational autoencoder, a technique addressing challenges in sensor data analysis in transportation systems, notably the misalignment of time series data and a lack of labeled data. Our technique converts vectorial data into functional data, which captures continuous temporal dynamics instead of discrete data that consist of separate observations. This conversion reduces data dimensions for machine learning tasks in fault diagnosis and facilitates the efficient removal of misalignment. The variational autoencoder identifies trends and anomalies in the data and employs a domain adaptation method to associate learned representations between labeled and unlabeled datasets. We validate the technique’s effectiveness using synthetic and real-world transportation data, providing valuable insights for transportation infrastructure reliability monitoring.

Original language	English
Article number	2910
Journal	Mathematics
Volume	11
Issue number	13
DOIs	https://doi.org/10.3390/math11132910
Publication status	Published - Jul 2023

Keywords

domain adaptation
functional data analysis
reliability
variational autoencoder

ASJC Scopus subject areas

Computer Science (miscellaneous)
General Mathematics
Engineering (miscellaneous)

More information

10.3390/math11132910

http://hdl.handle.net/10397/108676

Cite this

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title = "Functional Subspace Variational Autoencoder for Domain-Adaptive Fault Diagnosis",

abstract = "This paper presents the functional subspace variational autoencoder, a technique addressing challenges in sensor data analysis in transportation systems, notably the misalignment of time series data and a lack of labeled data. Our technique converts vectorial data into functional data, which captures continuous temporal dynamics instead of discrete data that consist of separate observations. This conversion reduces data dimensions for machine learning tasks in fault diagnosis and facilitates the efficient removal of misalignment. The variational autoencoder identifies trends and anomalies in the data and employs a domain adaptation method to associate learned representations between labeled and unlabeled datasets. We validate the technique{\textquoteright}s effectiveness using synthetic and real-world transportation data, providing valuable insights for transportation infrastructure reliability monitoring.",

keywords = "domain adaptation, functional data analysis, reliability, variational autoencoder",

author = "Tan Li and Fung, \{Che Heng\} and Wong, \{Him Ting\} and Chan, \{Tak Lam\} and Haibo Hu",

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AU - Li, Tan

AU - Fung, Che Heng

AU - Wong, Him Ting

AU - Chan, Tak Lam

AU - Hu, Haibo

PY - 2023/7

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N2 - This paper presents the functional subspace variational autoencoder, a technique addressing challenges in sensor data analysis in transportation systems, notably the misalignment of time series data and a lack of labeled data. Our technique converts vectorial data into functional data, which captures continuous temporal dynamics instead of discrete data that consist of separate observations. This conversion reduces data dimensions for machine learning tasks in fault diagnosis and facilitates the efficient removal of misalignment. The variational autoencoder identifies trends and anomalies in the data and employs a domain adaptation method to associate learned representations between labeled and unlabeled datasets. We validate the technique’s effectiveness using synthetic and real-world transportation data, providing valuable insights for transportation infrastructure reliability monitoring.

AB - This paper presents the functional subspace variational autoencoder, a technique addressing challenges in sensor data analysis in transportation systems, notably the misalignment of time series data and a lack of labeled data. Our technique converts vectorial data into functional data, which captures continuous temporal dynamics instead of discrete data that consist of separate observations. This conversion reduces data dimensions for machine learning tasks in fault diagnosis and facilitates the efficient removal of misalignment. The variational autoencoder identifies trends and anomalies in the data and employs a domain adaptation method to associate learned representations between labeled and unlabeled datasets. We validate the technique’s effectiveness using synthetic and real-world transportation data, providing valuable insights for transportation infrastructure reliability monitoring.

KW - domain adaptation

KW - functional data analysis

KW - reliability

KW - variational autoencoder

UR - https://www.scopus.com/pages/publications/85164678169

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DO - 10.3390/math11132910

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AN - SCOPUS:85164678169

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VL - 11

JO - Mathematics

JF - Mathematics

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M1 - 2910

ER -

Functional Subspace Variational Autoencoder for Domain-Adaptive Fault Diagnosis

Abstract

Keywords

ASJC Scopus subject areas

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