Transfer learning for battery smarter state estimation and ageing prognostics: Recent progress, challenges, and prospects

IF 13 Q1 ENERGY & FUELS
Kailong Liu , Qiao Peng , Yunhong Che , Yusheng Zheng , Kang Li , Remus Teodorescu , Dhammika Widanage , Anup Barai
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引用次数: 22

Abstract

With the advent of sustainable and clean energy transitions, lithium-ion batteries have become one of the most important energy storage sources for many applications. Battery management is of utmost importance for the safe, efficient, and long-lasting operation of lithium-ion batteries. However, the frequently changing load and operating conditions, the different cell chemistries and formats, and the complicated degradation patterns pose challenges for traditional battery management. The data-driven solutions that have emerged in recent years offer great opportunities to uncover the underlying data mapping within a battery system. In particular, transfer learning improves the performance of data-driven strategies by transferring existing knowledge from different but related domains, and if properly applied, would be a promising approach for smarter battery management. To this end, this paper presents a systematic review for the applications of transfer learning in the field of battery management for the first time, with particular focuses on battery state estimation and ageing prognostics. Specifically, the general issues faced by conventional battery management are identified and the applications of transfer learning to these issues are summarized. Then, the specific challenges of each topic are identified and the potential solutions based on transfer learning are explained, followed by a discussion of the state of the art in terms of principles, algorithm frameworks, advantages and disadvantages. Finally, future trends of data-driven battery management with transfer learning are discussed in terms of key challenges and promising opportunities.

迁移学习用于电池智能状态估计和老化预测:最新进展、挑战和前景
随着可持续和清洁能源转型的到来,锂离子电池已成为许多应用中最重要的储能来源之一。电池管理对于锂离子电池的安全、高效和持久运行至关重要。然而,频繁变化的负载和工作条件,不同的电池化学成分和形式,以及复杂的退化模式给传统的电池管理带来了挑战。近年来出现的数据驱动解决方案为揭示电池系统内部的底层数据映射提供了很好的机会。特别是,迁移学习通过从不同但相关的领域转移现有知识来提高数据驱动策略的性能,如果应用得当,将是一种很有前途的智能电池管理方法。为此,本文首次对迁移学习在电池管理领域的应用进行了系统回顾,特别关注电池状态估计和老化预测。具体来说,本文确定了传统电池管理面临的一般问题,并总结了迁移学习在这些问题上的应用。然后,确定了每个主题的具体挑战,并解释了基于迁移学习的潜在解决方案,随后讨论了原理、算法框架、优点和缺点方面的最新进展。最后,讨论了基于迁移学习的数据驱动电池管理的未来趋势,包括主要挑战和有希望的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advances in Applied Energy
Advances in Applied Energy Energy-General Energy
CiteScore
23.90
自引率
0.00%
发文量
36
审稿时长
21 days
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