Title
Battery aging-aware adaptive model predictive control based on coupled semi-empirical electro-thermal and aging modelsOther institutions
https://ror.org/00d9ah105https://ror.org/041kmwe10
Version
Published versionDocument type
Journal ArticleEmbargo end date
2027-12-15Language
EnglishRights
© 2025 ElsevierAccess
Embargoed accessPublisher’s version
https://doi.org/10.1016/j.apenergy.2025.126494Published at
Applied Energy 2025 Vol. 401, Part B. N. art. 126494Publisher
ElsevierKeywords
Cost
Derating
Lifetime extension
Lithium-ion battery ... [+]
Derating
Lifetime extension
Lithium-ion battery ... [+]
Cost
Derating
Lifetime extension
Lithium-ion battery
Model predictive control
Optimization [-]
Derating
Lifetime extension
Lithium-ion battery
Model predictive control
Optimization [-]
Subject (UNESCO Thesaurus)
Electric energyUNESCO Classification
Energy technologyAbstract
This paper presents an aging-rate aware nonlinear model predictive control (MPC) strategy for battery energy storage systems, integrating a semi-empirical, experimentally validated electro-thermal and ... [+]
This paper presents an aging-rate aware nonlinear model predictive control (MPC) strategy for battery energy storage systems, integrating a semi-empirical, experimentally validated electro-thermal and degradation model to account for both calendar and cycle aging factors, often neglected in conventional energy management approaches. A key contribution is the introduction of a adaptive weighting method that dynamically adjusts the weights of the MPC cost function according to the battery's aging state, primarily driven by time-dependent degradation factors. This adaptive mechanism improves control decisions across varying prediction horizons, leading to reductions in both battery degradation and total operating costs by up to 262.7 % and 44.51 %, respectively, when compared to a standard MPC. [-]
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