Leveraging Adaptive Model Predictive Controller for Active Cell Balancing in Li-ion Battery
For electric vehicle battery management, this work addresses cell balancing to extend battery life, but the results are simulation-only and incremental.
This paper proposes an adaptive model predictive controller (AMPC) for active cell balancing in Li-ion battery strings, using Recursive Least Square to predict future voltages. Simulation results show more uniform voltage distribution among cells.
Automotive industry is moving toward fully electric and hybrid electric vehicles. Accordingly, energy storage unit is one of the most important blocks in these electric drives. Battery stacks which contain a number of cells are being used for supplying the vehicles' energy. Charge equalization for series connected battery strings has a significant effect on battery life. In this paper, an adaptive model predictive controller (AMPC) is proposed to manage the cell equalizing process. The series connected cells' voltages and currents are collected, then leveraging Recursive Least Square (RLS) method, the future voltage samples for all of the cells are predicted. MPC controller specifies a sequence which results in the optimum balancing performance of the proposed circuit. Simulation results prove that using the suggested algorithm, the voltage set of the series cells has moved more uniformly.