Litcius/Paper detail

Health Prediction for Lithium-Ion Batteries Under Unseen Working Conditions

Yunhong Che, Florent Forest, Yusheng Zheng, Le Xu, Remus Teodorescu

2024IEEE Transactions on Industrial Electronics16 citationsDOIOpen Access PDF

Abstract

Battery health prediction is significant while challenging for intelligent battery management. This article proposes a general framework for both short-term and long-term predictions of battery health under unseen dynamic loading and temperature conditions using domain-adaptive multitask learning (MTL) with long-term regularization. First, features extracted from partial charging curves are utilized for short-term state of health predictions. Then, the long-term degradation trajectory is directly predicted by recursively using the predicted features within the multitask framework, enhancing the model integrity and lowering the complexity. Then, domain adaptation (DA) is adopted to reduce the discrepancies between different working conditions. Additionally, a long-term regularization is introduced to address the shortcoming that arises when the model is extrapolated recursively for future health predictions. Thus, the short-term prediction ability is maintained while the long-term prediction performance is enhanced. Finally, predictions are validated through aging experiments under various dynamic loading profiles. By using partial charging capacity–voltage data, the results show that the early-stage long-term predictions are accurate and stable under various working profiles, with root mean square errors below 2% and fitting coefficients surpassing 0.86.

Topics & Concepts

Regularization (linguistics)Term (time)Computer scienceState of healthBattery (electricity)TrajectoryState of chargeOverfittingArtificial intelligenceMachine learningControl theory (sociology)Artificial neural networkPower (physics)AstronomyQuantum mechanicsControl (management)PhysicsAdvanced Battery Technologies ResearchAdvancements in Battery MaterialsElectric Vehicles and Infrastructure