Enabling Efficient Optimal Control of Reconfigurable Battery Systems by Unifying System Modeling and Narrowing Search Space

Reconfigurable battery systems (RBSs) are emerging as a promising solution to improving fault tolerance, charge and thermal balance, energy delivery, etc. To optimize these performance metrics, high-dimensional nonlinear integer programming problems need to be formulated and solved. During this process, it is necessary to address multiple challenges stemming from nonlinear battery characteristics, discrete switch states, dynamic system configurations, as well as the curse of dimensionality inherent in large-scale systems. Thus, we propose a unified modeling framework to accommodate various potential configurations of an RBS and even to cover different RBS designs, significantly facilitating the topology design and optimization problem formulation for RBSs. Moreover, to solve the formulated RBS problems, the search space is tailored to encompass only feasible SSVs, thereby ensuring safe system operation while substantially curtailing search efforts. These proposed methods, focusing on unifying the system modeling and narrowing the search space, lay a solid foundation for effectively formulating and efficiently solving RBS optimal control problems. The accuracy and effectiveness of the proposed methods are demonstrated by simulation and experimental tests.