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Predicting Battery Lifetime Under Varying Usage Conditions from Early Aging Data

Published 17 Jul 2023 in cs.LG and stat.ML | (2307.08382v2)

Abstract: Accurate battery lifetime prediction is important for preventative maintenance, warranties, and improved cell design and manufacturing. However, manufacturing variability and usage-dependent degradation make life prediction challenging. Here, we investigate new features derived from capacity-voltage data in early life to predict the lifetime of cells cycled under widely varying charge rates, discharge rates, and depths of discharge. Features were extracted from regularly scheduled reference performance tests (i.e., low rate full cycles) during cycling. The early-life features capture a cell's state of health and the rate of change of component-level degradation modes, some of which correlate strongly with cell lifetime. Using a newly generated dataset from 225 nickel-manganese-cobalt/graphite Li-ion cells aged under a wide range of conditions, we demonstrate a lifetime prediction of in-distribution cells with 15.1% mean absolute percentage error using no more than the first 15% of data, for most cells. Further testing using a hierarchical Bayesian regression model shows improved performance on extrapolation, achieving 21.8% mean absolute percentage error for out-of-distribution cells. Our approach highlights the importance of using domain knowledge of lithium-ion battery degradation modes to inform feature engineering. Further, we provide the community with a new publicly available battery aging dataset with cells cycled beyond 80% of their rated capacity.

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References (56)
  1. Degradation diagnostics for lithium ion cells. Journal of Power Sources, 341:373–386, 2017.
  2. The challenge and opportunity of battery lifetime prediction from field data. Joule, 5(8):1934–1955, 2021.
  3. Integrating physics-based modeling and machine learning for degradation diagnostics of lithium-ion batteries. Energy Storage Materials, 2022.
  4. Early battery performance prediction for mixed use charging profiles using hierarchal machine learning. Batteries & Supercaps, 4(7):1186–1196, 2021.
  5. Data-driven prediction of battery cycle life before capacity degradation. Nature Energy, 4(5):383–391, 2019.
  6. Closed-loop optimization of fast-charging protocols for batteries with machine learning. Nature, 578(7795):397–402, 2020.
  7. Autonomous discovery of battery electrolytes with robotic experimentation and machine learning. Cell Reports Physical Science, 1(12):100264, 2020.
  8. Precision measurements of the coulombic efficiency of lithium-ion batteries and of electrode materials for lithium-ion batteries. Journal of The Electrochemical Society, 157(2):A196, 2009.
  9. Evaluation of effects of additives in wound li-ion cells through high precision coulometry. Journal of The Electrochemical Society, 158(3):A255, 2011.
  10. Predicting and extending the lifetime of li-ion batteries. Journal of The Electrochemical Society, 160(9):A1451, 2013.
  11. Production caused variation in capacity aging trend and correlation to initial cell performance. Journal of Power Sources, 247:332–338, 2014.
  12. Failure statistics for commercial lithium ion batteries: A study of 24 pouch cells. Journal of Power Sources, 342:589–597, 2017.
  13. Automated feature extraction and selection for data-driven models of rapid battery capacity fade and end of life. IEEE Transactions on Industrial Informatics, 18(5):2965–2973, 2021.
  14. Prognostics of battery cycle life in the early-cycle stage based on hybrid model. Energy, 221:119901, 2021.
  15. Lifespan prediction of lithium-ion batteries based on various extracted features and gradient boosting regression tree model. Journal of Power Sources, 476:228654, 2020.
  16. Predicting the impact of formation protocols on battery lifetime immediately after manufacturing. Joule, 5(11):2971–2992, 2021.
  17. A convolutional neural network model for battery capacity fade curve prediction using early life data. Journal of Power Sources, 542:231736, 2022.
  18. Beep: A python library for battery evaluation and early prediction. SoftwareX, 11:100506, 2020.
  19. Early prediction of battery lifetime via a machine learning based framework. Energy, 225:120205, 2021.
  20. Identification and machine learning prediction of knee-point and knee-onset in capacity degradation curves of lithium-ion cells. Energy and AI, 1:100006, 2020.
  21. One-shot battery degradation trajectory prediction with deep learning. Journal of Power Sources, 506:230024, 2021.
  22. Feature engineering for machine learning enabled early prediction of battery lifetime. Journal of Power Sources, 527:231127, 2022.
  23. “knees” in lithium-ion battery aging trajectories. Journal of The Electrochemical Society, 169(6):060517, 2022.
  24. Li plating as unwanted side reaction in commercial li-ion cells–a review. Journal of Power Sources, 384:107–124, 2018.
  25. A review on the key issues of the lithium ion battery degradation among the whole life cycle. ETransportation, 1:100005, 2019.
  26. Lithium-ion battery data and where to find it. Energy and AI, 5:100081, 2021.
  27. Adaptation of an electrochemistry-based li-ion battery model to account for deterioration observed under randomized use. In Annual Conference of the PHM Society, 2014.
  28. Prognostics methods for battery health monitoring using a bayesian framework. IEEE Transactions on instrumentation and measurement, 58(2):291–296, 2008.
  29. Prognostics of lithium-ion batteries based on dempster–shafer theory and the bayesian monte carlo method. Journal of Power Sources, 196(23):10314–10321, 2011.
  30. An ensemble model for predicting the remaining useful performance of lithium-ion batteries. Microelectronics Reliability, 53(6):811–820, 2013.
  31. Degradation of commercial lithium-ion cells as a function of chemistry and cycling conditions. Journal of The Electrochemical Society, 167(12):120532, 2020.
  32. Estimation of li-ion degradation test sample sizes required to understand cell-to-cell variability. Batteries & Supercaps, 4(12):1821–1829, 2021.
  33. A comparison between electrochemical impedance spectroscopy and incremental capacity-differential voltage as li-ion diagnostic techniques to identify and quantify the effects of degradation modes within battery management systems. Journal of Power Sources, 360:301–318, 2017.
  34. Degradation mechanism detection for nmc batteries based on incremental capacity curves. World Electric Vehicle Journal, 8(2):350–361, 2016a.
  35. Degradation mechanisms detection for hp and he nmc cells based on incremental capacity curves. In 2016 IEEE Vehicle Power and Propulsion Conference (VPPC), pages 1–5. IEEE, 2016b.
  36. Lithium-ion battery life model with electrode cracking and early-life break-in processes. Journal of The Electrochemical Society, 168(10):100530, 2021.
  37. Review and performance comparison of mechanical-chemical degradation models for lithium-ion batteries. Journal of The Electrochemical Society, 166(14):A3189–A3200, 2019.
  38. Solid-state diffusion limitations on pulse operation of a lithium ion cell for hybrid electric vehicles. Journal of power sources, 161(1):628–639, 2006.
  39. Machine-learning assisted identification of accurate battery lifetime models with uncertainty. Journal of The Electrochemical Society, 169(8):080518, 2022.
  40. Bayesian learning for rapid prediction of lithium-ion battery-cycling protocols. Joule, 5(12):3187–3203, 2021.
  41. Best practices for incremental capacity analysis. Frontiers in Energy Research, 10, 2022.
  42. Collinearity: a review of methods to deal with it and a simulation study evaluating their performance. Ecography, 36(1):27–46, 2013.
  43. Feature selection in machine learning: A new perspective. Neurocomputing, 300:70–79, 2018. ISSN 0925-2312.
  44. The elements of statistical learning : data mining, inference, and prediction. Springer, New York, NY, 2nd edition, 2013. ISBN 9780387848570.
  45. Human-level concept learning through probabilistic program induction. Science, 350(6266):1332–1338, 2015.
  46. Hierarchical generalized additive models in ecology: an introduction with mgcv. PeerJ, 7:e6876, 2019.
  47. Faster algorithms for the constrained k-means problem. Theory of computing systems, 62(1):93–115, 2018.
  48. Bayesian hierarchical modelling for battery lifetime early prediction. arXiv preprint arXiv:2211.05697, 2022.
  49. Investigation of path-dependent degradation in lithium-ion batteries. Batteries & Supercaps, 3(12):1377–1385, 2020.
  50. User-friendly differential voltage analysis freeware for the analysis of degradation mechanisms in li-ion batteries. Journal of The Electrochemical Society, 159(9):A1405, 2012.
  51. Degradation mechanisms of high capacity 18650 cells containing si-graphite anode and nickel-rich nmc cathode. Electrochimica Acta, 297:1109–1120, 2019.
  52. Calendar aging of nca lithium-ion batteries investigated by differential voltage analysis and coulomb tracking. Journal of The Electrochemical Society, 164(1):A6066, 2016.
  53. Determination of lithium-ion battery state-of-health based on constant-voltage charge phase. Journal of Power Sources, 258:218–227, 2014. ISSN 0378-7753.
  54. Online state-of-health estimation for lithium-ion batteries using constant-voltage charging current analysis. Applied Energy, 212:1589–1600, 2018. ISSN 0306-2619.
  55. State of health estimation of lithium-ion batteries based on the constant voltage charging curve. Energy, 167:661–669, 2019. ISSN 0360-5442.
  56. Research on k-value selection method of k-means clustering algorithm. J, 2(2):226–235, 2019.
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