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A controllable deep transfer learning network with multiple domain adaptation for battery state-of-charge estimation

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  • Oyewole, Isaiah
  • Chehade, Abdallah
  • Kim, Youngki

Abstract

Deep learning models have been drawing significant attention in the literature of state-of-charge (SOC) estimation because of their capabilities to capture non-trivial temporal patterns. However, most of such models ignore cell-to-cell variations or focus on short-term estimations that are not practical for battery cells with limited charging-discharging history. We propose a Controllable Deep Transfer Learning (CDTL) network for short and long-term SOC estimations at early stages of degradation. The CDTL utilizes shared knowledge between the target cells of interest and historical source cellswith rich SOC data usingcontrollable Multiple Domain Adaptation (MDA). Specifically,the CDTL consists of two long-short term memory (LSTM) networks, the source LSTM, and the target LSTM.The source LSTM istrained onSOC data from historical battery cells.The target LSTMis then trained using limited available SOC data from the target cell and thetransferredknowledge from the source LSTM usingcontrollable MDAwith adaptive regularization. The contributions of the CDTL are two-folded. First, it reducesthe likelihood of negative transfer learning using controllable MDA with adaptive regularization, whichenhances the target LSTMgeneralizability for long-term SOC estimation. Second, the CDTL offers theoretical guarantees on the controllability and convergenceof transferred knowledge from the source cell to target cell. The experimental results demonstrate that the proposed CDTL outperforms existing deepand transfer learning benchmarkswith1) amaximum improvement of 60% in root-mean-squared error (RMSE) for battery cells with the same chemistry,2) an averageimprovement of 50% in RMSE across different battery chemistries, and3) about39% reduction in computational time.

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  • Oyewole, Isaiah & Chehade, Abdallah & Kim, Youngki, 2022. "A controllable deep transfer learning network with multiple domain adaptation for battery state-of-charge estimation," Applied Energy, Elsevier, vol. 312(C).
    • Handle: RePEc:eee:appene:v:312:y:2022:i:c:s0306261922001842
    DOI: 10.1016/j.apenergy.2022.118726
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    2. Takyi-Aninakwa, Paul & Wang, Shunli & Zhang, Hongying & Yang, Xiaoyong & Fernandez, Carlos, 2022. "An optimized long short-term memory-weighted fading extended Kalman filtering model with wide temperature adaptation for the state of charge estimation of lithium-ion batteries," Applied Energy, Elsevier, vol. 326(C).
    3. Fan, Tian-E & Liu, Song-Ming & Yang, Hao & Li, Peng-Hua & Qu, Baihua, 2023. "A fast active balancing strategy based on model predictive control for lithium-ion battery packs," Energy, Elsevier, vol. 279(C).
    4. Chen, Junxiong & Zhang, Yu & Wu, Ji & Cheng, Weisong & Zhu, Qiao, 2023. "SOC estimation for lithium-ion battery using the LSTM-RNN with extended input and constrained output," Energy, Elsevier, vol. 262(PA).
    5. Takyi-Aninakwa, Paul & Wang, Shunli & Zhang, Hongying & Li, Huan & Xu, Wenhua & Fernandez, Carlos, 2022. "An optimized relevant long short-term memory-squared gain extended Kalman filter for the state of charge estimation of lithium-ion batteries," Energy, Elsevier, vol. 260(C).
    6. Molla Shahadat Hossain Lipu & Tahia F. Karim & Shaheer Ansari & Md. Sazal Miah & Md. Siddikur Rahman & Sheikh T. Meraj & Rajvikram Madurai Elavarasan & Raghavendra Rajan Vijayaraghavan, 2022. "Intelligent SOX Estimation for Automotive Battery Management Systems: State-of-the-Art Deep Learning Approaches, Open Issues, and Future Research Opportunities," Energies, MDPI, vol. 16(1), pages 1-31, December.

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