Discrete Modeling and Period-Adding Bifurcation of DC-DC Converter Feeding Constant Power Load

In this work, an including the switched evolution process discrete model of a DC-DC converter feeding a switched constant power load is proposed based on the Poincare mapping rule and matrix exponent method. Numerical simulations of the bifurcation scheme based on the proposed discrete model reveal the period-adding bifurcation structures of the system as multiple devils' staircases. Further, the calculation of the stable regions of the multiple-period orbits of the nested period-adding bifurcation structures are illustrated. The experimental results verify the validity of the discrete model and analytical accuracy of the period-adding bifurcation characteristics of the system. The proposed model solves the difficulties associated with discrete modeling for power electronic nonlinear switched systems. The introduction of the switched evolution process in the proposed discrete model provides a specific mathematical model for studying the influence of the switched evolution process on the dynamics of power electronic nonlinear switched systems. This study is expected to be a foundation for the theory and further research on such power electronic nonlinear switched systems.

Automated summary

This study proposes a discrete model that addresses the challenges of discrete modeling for power electronic nonlinear switched systems. Experimental results confirm the effectiveness of the model and the accuracy of the bifurcation characteristics. The research lays a foundation for theory and further studies in this field.