We stand with Ukraine

We stand with Ukraine

Lifeng Wu

Orcid: 0000-0002-5238-8823

Affiliations:

Capital Normal University, Beijing, China

According to our database¹, Lifeng Wu authored at least 18 papers between 2010 and 2025.

Collaborative distances:

Dijkstra number² of five.
Erdős number³ of five.

Timeline

Legend:

Book

In proceedings

Article

PhD thesis

Dataset

Other

Links

Online presence:

on orcid.org

On csauthors.net:

Bibliography

2025

Running Gear Global Composite Fault Diagnosis Based on Large Model.

[BibT_eX]

[DOI]

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IEEE Trans. Ind. Informatics, May, 2025

2024

FCHG: Fuzzy Cognitive Hypergraph for interpretable fault detection.

[BibT_eX]

[DOI]

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Expert Syst. Appl., 2024

Interpretable predictive modeling of non-stationary long time series.

[BibT_eX]

[DOI]

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Comput. Ind. Eng., 2024

2023

An Efficient and Controllable Capsule Network for Classification of Maritime Moving Targets.

[BibT_eX]

[DOI]

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IEEE Trans. Geosci. Remote. Sens., 2023

Deep attention fuzzy cognitive maps for interpretable multivariate time series prediction.

[BibT_eX]

[DOI]

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Knowl. Based Syst., 2023

2019

RUL Prediction of Lithium-Ion Battery Based on Improved DGWO-ELM Method in a Random Discharge Rates Environment.

[BibT_eX]

[DOI]

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IEEE Access, 2019

State-of-Health Estimation for Lithium-Ion Batteries Based on Wiener Process With Modeling the Relaxation Effect.

[BibT_eX]

[DOI]

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IEEE Access, 2019

Manifold Regularization Graph Structure Auto-Encoder to Detect Loop Closure for Visual SLAM.

[BibT_eX]

[DOI]

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IEEE Access, 2019

Research on Degradation Modeling and Life Prediction Method of Lithium-Ion Battery in Dynamic Environment.

[BibT_eX]

[DOI]

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IEEE Access, 2019

A Virtual Sample Generation Method Based on Differential Evolution Algorithm for Overall Trend of Small Sample Data: Used for Lithium-ion Battery Capacity Degradation Data.

[BibT_eX]

[DOI]

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IEEE Access, 2019

2018

An Equivalent Circuit Model for Lithium Battery of Electric Vehicle considering Self-Healing Characteristic.

[BibT_eX]

[DOI]

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J. Control. Sci. Eng., 2018

Bearing Remaining Useful Life Prediction Based on Naive Bayes and Weibull Distributions.

[BibT_eX]

[DOI]

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Entropy, 2018

Unsupervised Locality-Preserving Robust Latent Low-Rank Recovery-Based Subspace Clustering for Fault Diagnosis.

[BibT_eX]

[DOI]

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Michael G. Pecht

IEEE Access, 2018

2017

Fault Diagnosis from Raw Sensor Data Using Deep Neural Networks Considering Temporal Coherence.

[BibT_eX]

[DOI]

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Sensors, 2017

Transfer Learning With Neural Networks for Bearing Fault Diagnosis in Changing Working Conditions.

[BibT_eX]

[DOI]

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IEEE Access, 2017

Rolling Element Bearing Fault Diagnosis Using Improved Manifold Learning.

[BibT_eX]

[DOI]

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IEEE Access, 2017

2016

A reliability assessment guide for the transition planning to lead-free electronics for companies whose products are RoHS exempted or excluded.

[BibT_eX]

[DOI]

Michael G. Pecht

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Tadahiro Shibutani

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Microelectron. Reliab., 2016

2010

Design and Implementation of a Digital Angular Rate Sensor.

[BibT_eX]

[DOI]

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Sensors, 2010

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