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A physically motivated voltage hysteresis model for lithium-ion batteries using a probability distributed equivalent circuit

Leonard Jahn, Patrick Mößle, Fridolin Röder, Michael A. Danzer

2024Communications Engineering17 citationsDOIOpen Access PDF

Abstract

Abstract The open circuit voltage hysteresis of lithium-ion batteries is a phenomenon that, despite intensive research, is still not fully understood. However, it must be taken into account for accurate state-of-charge estimation in battery management systems. Mechanistic models of the open circuit voltage hysteresis previously published are not suitable for deployment in a battery management system. Phenomenological models on the other hand can only superficially represent the processes taking place. To address this limitation, we propose a probability distributed equivalent circuit model motivated by the physical insights into hysteresis. The model incorporates hysteresis effects that are often disregarded for state estimation, while keeping the computational cost low. Although the parameterization is more demanding, the model has the advantage of providing insight into the internal state of the battery and intrinsically incorporating the effect of path-dependent rate capability.

Topics & Concepts

HysteresisBattery (electricity)VoltageComputer scienceState of chargeEquivalent circuitSoftware deploymentControl theory (sociology)State (computer science)Path (computing)Electrical engineeringControl (management)EngineeringPhysicsAlgorithmPower (physics)Quantum mechanicsProgramming languageArtificial intelligenceOperating systemAdvanced Battery Technologies ResearchAdvancements in Battery MaterialsReliability and Maintenance Optimization
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