摘要:SummaryAccurately evaluating the health status of lithium-ion batteries (LIBs) is significant to enhance the safety, efficiency, and economy of LIBs deployment. However, the complex degradation processes inside the battery make it a thorny challenge. Data-driven methods are widely used to resolve the problem without exploring the complex aging mechanisms; however, random and incomplete charging-discharging processes in actual applications make the existing methods fail to work. Here, we develop three data-driven methods to estimate battery state of health (SOH) using a short random charging segment (RCS). Four types of commercial LIBs (75 cells), cycled under different temperatures and discharging rates, are employed to validate the methods. Trained on a nominal cycling condition, our models can achieve high-precision SOH estimation under other different conditions. We prove that an RCS with a 10mV voltage window can obtain an average error of less than 5%, and the error plunges as the voltage window increases.Graphical abstractDisplay OmittedHighlights•A short random charging segment enables battery health evaluation•Two features with high correlations to battery capacity are extracted•Three typical machine learning methods are compared for battery health estimation•The method is verified by four types of batteries cycled under different conditionsElectrochemistry; Electrochemical energy storage; Engineering
