A physics-based equivalent circuit model (ECM) is derived by applying the finite volume method to... more A physics-based equivalent circuit model (ECM) is derived by applying the finite volume method to a pseudotwo-dimensional (P2D) model of lithium-ion (Li-ion) batteries. Only standard passive components are used to construct the equivalent circuit, which reflects the fact that a Li-ion battery is an energy storage device. Voltages across and currents through the circuit elements in the ECM are identified with the respective internal electrochemical processes in the battery, thus allowing the parametric values of circuit elements to be expressed as functions of the Li-ion concentrations and temperature. Variations in the parametric values across the thickness of the battery lead to a distributed-parameter ECM amenable for a wide range of applications. Furthermore, in contrast to existing reduced-order models of Li-ion battery which are described by differential-algebraic equations, the ECM is governed by ordinary differential equations wherein all the circuit components are expressed as explicit functions of the state and input variables. Hence, the developed model allows the solution to be found directly using matrix algebra, resulting in rapid simulation study suitable for the development of computationally efficient real-time battery control algorithms. Results of simulation based on the developed distributed-parameter ECM show close agreement with those obtained from a partial differential equation based P2D model under a wide range of applied current rates, but at a much reduced computational burden.
We present a reduced order model for a lithium ion battery in which Padé approximants are used to... more We present a reduced order model for a lithium ion battery in which Padé approximants are used to simplify complex, transcendental, transfer functions associated with the linearized, pseudo 2-dimensional (P2D) electrochemical model of the battery. The resulting transfer functions take the form of simple, rational polynomial functions, which can be used to compute any variable at any location within a one-dimensional representation of the battery domain. Corrections for nonlinear behavior are also incorporated into the reduced model. The results obtained using the reduced model compare favorably to those from the full (nonlinear) P2D model and the computational time required to produce these results is significantly reduced. Importantly, the form of the reduced model means that variables can be evaluated at specific discrete locations within the cell domain, without the need to compute all values of the variable at all discrete locations, as is the case with the spatial discretization methods most commonly used to implement the P2D model. We show that this results in further significant time savings and enhances the suitability of the model for variety of applications.
A physics-based equivalent circuit model (ECM) is derived by applying the finite volume method to... more A physics-based equivalent circuit model (ECM) is derived by applying the finite volume method to a pseudotwo-dimensional (P2D) model of lithium-ion (Li-ion) batteries. Only standard passive components are used to construct the equivalent circuit, which reflects the fact that a Li-ion battery is an energy storage device. Voltages across and currents through the circuit elements in the ECM are identified with the respective internal electrochemical processes in the battery, thus allowing the parametric values of circuit elements to be expressed as functions of the Li-ion concentrations and temperature. Variations in the parametric values across the thickness of the battery lead to a distributed-parameter ECM amenable for a wide range of applications. Furthermore, in contrast to existing reduced-order models of Li-ion battery which are described by differential-algebraic equations, the ECM is governed by ordinary differential equations wherein all the circuit components are expressed as explicit functions of the state and input variables. Hence, the developed model allows the solution to be found directly using matrix algebra, resulting in rapid simulation study suitable for the development of computationally efficient real-time battery control algorithms. Results of simulation based on the developed distributed-parameter ECM show close agreement with those obtained from a partial differential equation based P2D model under a wide range of applied current rates, but at a much reduced computational burden.
We present a reduced order model for a lithium ion battery in which Padé approximants are used to... more We present a reduced order model for a lithium ion battery in which Padé approximants are used to simplify complex, transcendental, transfer functions associated with the linearized, pseudo 2-dimensional (P2D) electrochemical model of the battery. The resulting transfer functions take the form of simple, rational polynomial functions, which can be used to compute any variable at any location within a one-dimensional representation of the battery domain. Corrections for nonlinear behavior are also incorporated into the reduced model. The results obtained using the reduced model compare favorably to those from the full (nonlinear) P2D model and the computational time required to produce these results is significantly reduced. Importantly, the form of the reduced model means that variables can be evaluated at specific discrete locations within the cell domain, without the need to compute all values of the variable at all discrete locations, as is the case with the spatial discretization methods most commonly used to implement the P2D model. We show that this results in further significant time savings and enhances the suitability of the model for variety of applications.
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