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Hauptverfasser: Lu, Hong, Chen, Jiali, Zhang, Jingzhao, He, Guannan, Han, Xuebing, Ouyang, Minggao
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2509.01323
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author Lu, Hong
Chen, Jiali
Zhang, Jingzhao
He, Guannan
Han, Xuebing
Ouyang, Minggao
author_facet Lu, Hong
Chen, Jiali
Zhang, Jingzhao
He, Guannan
Han, Xuebing
Ouyang, Minggao
contents Industrial-scale battery management involves various types of tasks, such as estimation, prediction, and system-level diagnostics. Each task employs distinct data across temporal scales, sensor resolutions, and data channels. Building task-specific methods requires a great deal of data and engineering effort, which limits the scalability of intelligent battery management. Here we present the Flexible Masked Autoencoder (FMAE), a flexible pretraining framework that can learn with missing battery data channels and capture inter-correlations across data snippets. FMAE learns unified battery representations from heterogeneous data and can be adopted by different tasks with minimal data and engineering efforts. Experimentally, FMAE consistently outperforms all task-specific methods across five battery management tasks with eleven battery datasets. On remaining life prediction tasks, FMAE uses 50 times less inference data while maintaining state-of-the-art results. Moreover, when real-world data lack certain information, such as system voltage, FMAE can still be applied with marginal performance impact, achieving comparable results with the best hand-crafted features. FMAE demonstrates a practical route to a flexible, data-efficient model that simplifies real-world multi-task management of dynamical systems.
format Preprint
id arxiv_https___arxiv_org_abs_2509_01323
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Multitask Battery Management with Flexible Pretraining
Lu, Hong
Chen, Jiali
Zhang, Jingzhao
He, Guannan
Han, Xuebing
Ouyang, Minggao
Machine Learning
Artificial Intelligence
Industrial-scale battery management involves various types of tasks, such as estimation, prediction, and system-level diagnostics. Each task employs distinct data across temporal scales, sensor resolutions, and data channels. Building task-specific methods requires a great deal of data and engineering effort, which limits the scalability of intelligent battery management. Here we present the Flexible Masked Autoencoder (FMAE), a flexible pretraining framework that can learn with missing battery data channels and capture inter-correlations across data snippets. FMAE learns unified battery representations from heterogeneous data and can be adopted by different tasks with minimal data and engineering efforts. Experimentally, FMAE consistently outperforms all task-specific methods across five battery management tasks with eleven battery datasets. On remaining life prediction tasks, FMAE uses 50 times less inference data while maintaining state-of-the-art results. Moreover, when real-world data lack certain information, such as system voltage, FMAE can still be applied with marginal performance impact, achieving comparable results with the best hand-crafted features. FMAE demonstrates a practical route to a flexible, data-efficient model that simplifies real-world multi-task management of dynamical systems.
title Multitask Battery Management with Flexible Pretraining
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2509.01323