Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules

Jie Kong; Yi Zhang; Yichi Zhang; Lukas Wick; Frederik Lillebak Hansen; Dao Zhou; Huai Wang

doi:10.1109/APEC48143.2025.10977327

Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules

Jie Kong, Yi Zhang, Yichi Zhang, Lukas Wick, Frederik Lillebak Hansen, Dao Zhou, Huai Wang

Research output: Chapter in book / Conference proceeding › Conference article published in proceeding or book › Academic research › peer-review

Abstract

DC power cycling tests in semiconductor modules induces repetitive thermal-mechanical stresses that accumulate as fatigue over time. This paper proposes a physics-informed neural network method to reduce the reliability testing time for power semiconductor modules. The main objective of this study is to reduce the testing time while maintain a satisfactory degradation trajectory prediction accuracy using physics-informed data-driven methods. The impact of testing noise and inconsistencies from device to device is attenuated. On-state saturation voltage temperature-dependence compensation and physics based loss term regularization technique are applied in Long Short-Term Memory (LSTM) architechture, which can enhance the accuracy of degradation curve prediction under early degradation. A total of 18 IGBT devices were tested in the power cycling experiments. The proposed degradation curve prediction model can achieve an average end-of-life (EOL) prediction accuracy of 90% using approximately 40% of the early degradation testing data, which can reduce the testing time by about 60%.

Original language	English
Title of host publication	APEC 2025 - 14th Annual IEEE Applied Power Electronics Conference and Exposition
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	2380-2386
Number of pages	7
ISBN (Electronic)	9798331516116
DOIs	https://doi.org/10.1109/APEC48143.2025.10977327
Publication status	Published - Mar 2025
Event	14th Annual IEEE Applied Power Electronics Conference and Exposition, APEC 2025 - Atlanta, United States Duration: 16 Mar 2025 → 20 Mar 2025

Publication series

Name	Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC
ISSN (Print)	1048-2334
ISSN (Electronic)	2470-6647

Conference

Conference	14th Annual IEEE Applied Power Electronics Conference and Exposition, APEC 2025
Country/Territory	United States
City	Atlanta
Period	16/03/25 → 20/03/25

Keywords

DC power cycling
Degradation trajectory prediction
End-of-life
Neural Network
Reliability

ASJC Scopus subject areas

Electrical and Electronic Engineering

More information

10.1109/APEC48143.2025.10977327

Cite this

Kong, J., Zhang, Y., Zhang, Y., Wick, L., Hansen, F. L., Zhou, D., & Wang, H. (2025). Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules. In APEC 2025 - 14th Annual IEEE Applied Power Electronics Conference and Exposition (pp. 2380-2386). (Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/APEC48143.2025.10977327

Kong, Jie ; Zhang, Yi ; Zhang, Yichi et al. / Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules. APEC 2025 - 14th Annual IEEE Applied Power Electronics Conference and Exposition. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 2380-2386 (Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC).

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title = "Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules",

abstract = "DC power cycling tests in semiconductor modules induces repetitive thermal-mechanical stresses that accumulate as fatigue over time. This paper proposes a physics-informed neural network method to reduce the reliability testing time for power semiconductor modules. The main objective of this study is to reduce the testing time while maintain a satisfactory degradation trajectory prediction accuracy using physics-informed data-driven methods. The impact of testing noise and inconsistencies from device to device is attenuated. On-state saturation voltage temperature-dependence compensation and physics based loss term regularization technique are applied in Long Short-Term Memory (LSTM) architechture, which can enhance the accuracy of degradation curve prediction under early degradation. A total of 18 IGBT devices were tested in the power cycling experiments. The proposed degradation curve prediction model can achieve an average end-of-life (EOL) prediction accuracy of 90\% using approximately 40\% of the early degradation testing data, which can reduce the testing time by about 60\%.",

keywords = "DC power cycling, Degradation trajectory prediction, End-of-life, Neural Network, Reliability",

author = "Jie Kong and Yi Zhang and Yichi Zhang and Lukas Wick and Hansen, \{Frederik Lillebak\} and Dao Zhou and Huai Wang",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 14th Annual IEEE Applied Power Electronics Conference and Exposition, APEC 2025 ; Conference date: 16-03-2025 Through 20-03-2025",

year = "2025",

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language = "English",

series = "Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC",

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Kong, J, Zhang, Y, Zhang, Y, Wick, L, Hansen, FL, Zhou, D & Wang, H 2025, Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules. in APEC 2025 - 14th Annual IEEE Applied Power Electronics Conference and Exposition. Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC, Institute of Electrical and Electronics Engineers Inc., pp. 2380-2386, 14th Annual IEEE Applied Power Electronics Conference and Exposition, APEC 2025, Atlanta, United States, 16/03/25. https://doi.org/10.1109/APEC48143.2025.10977327

Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules. / Kong, Jie; Zhang, Yi; Zhang, Yichi et al.
APEC 2025 - 14th Annual IEEE Applied Power Electronics Conference and Exposition. Institute of Electrical and Electronics Engineers Inc., 2025. p. 2380-2386 (Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC).

Research output: Chapter in book / Conference proceeding › Conference article published in proceeding or book › Academic research › peer-review

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AU - Kong, Jie

AU - Zhang, Yi

AU - Zhang, Yichi

AU - Wick, Lukas

AU - Hansen, Frederik Lillebak

AU - Zhou, Dao

AU - Wang, Huai

PY - 2025/3

Y1 - 2025/3

N2 - DC power cycling tests in semiconductor modules induces repetitive thermal-mechanical stresses that accumulate as fatigue over time. This paper proposes a physics-informed neural network method to reduce the reliability testing time for power semiconductor modules. The main objective of this study is to reduce the testing time while maintain a satisfactory degradation trajectory prediction accuracy using physics-informed data-driven methods. The impact of testing noise and inconsistencies from device to device is attenuated. On-state saturation voltage temperature-dependence compensation and physics based loss term regularization technique are applied in Long Short-Term Memory (LSTM) architechture, which can enhance the accuracy of degradation curve prediction under early degradation. A total of 18 IGBT devices were tested in the power cycling experiments. The proposed degradation curve prediction model can achieve an average end-of-life (EOL) prediction accuracy of 90% using approximately 40% of the early degradation testing data, which can reduce the testing time by about 60%.

AB - DC power cycling tests in semiconductor modules induces repetitive thermal-mechanical stresses that accumulate as fatigue over time. This paper proposes a physics-informed neural network method to reduce the reliability testing time for power semiconductor modules. The main objective of this study is to reduce the testing time while maintain a satisfactory degradation trajectory prediction accuracy using physics-informed data-driven methods. The impact of testing noise and inconsistencies from device to device is attenuated. On-state saturation voltage temperature-dependence compensation and physics based loss term regularization technique are applied in Long Short-Term Memory (LSTM) architechture, which can enhance the accuracy of degradation curve prediction under early degradation. A total of 18 IGBT devices were tested in the power cycling experiments. The proposed degradation curve prediction model can achieve an average end-of-life (EOL) prediction accuracy of 90% using approximately 40% of the early degradation testing data, which can reduce the testing time by about 60%.

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ER -

Kong J, Zhang Y, Zhang Y, Wick L, Hansen FL, Zhou D et al. Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules. In APEC 2025 - 14th Annual IEEE Applied Power Electronics Conference and Exposition. Institute of Electrical and Electronics Engineers Inc. 2025. p. 2380-2386. (Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC). doi: 10.1109/APEC48143.2025.10977327

Physics-informed Neural Network Approach for Early Degradation Trajectory Prediction of Power Semiconductor Modules

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