Analysis of DC/DC Boost Converter-Full-Bridge Buck Inverter System for AC Generation

This paper presents an analysis and simulation of the mathematical model associated to the DC/DC Boost converter-full-bridge Buck inverter system to regulate the voltage output of the DC/DC Boost converter allowing bipolar voltages higher than the input voltage via the full-bridge Buck inverter. To validate the model, the differential flatness property is applied via the flat outputs of the system (energy for the DC/DC Boost converter and the voltage of the full-bridge Buck inverter) considering the complete dynamics, in conjunction with fixed and time-variant trajectory planning. In the simulation results, it is observed that the error signals of the states versus the reference trajectories are acceptable. Regarding the validation of the model, this is performed with open-loop simulations at the circuit level using the SimPowerSystems Toolbox of Matlab-Simulink. The simulation results validate the good performance of the system under study. In this way, the main contribution of this work is that for the first time in the literature, the analysis of a complete dynamics for a conversion system from DC to AC without the use of a transformer and taking advantage of differential flatness is reported; thus, the system analyzed could be represented as an alternative in applications of renewable energies that require conversion from DC to AC.

Automated summary

This paper presents an analysis and simulation of a mathematical model for a DC/DC Boost converter-full-bridge Buck inverter system. The model is used to regulate voltage output and allow for bipolar voltages higher than the input voltage. The results of the simulation show acceptable error signals and validate the good performance of the system. The main contribution of this work is the analysis of a complete dynamics for a DC to AC conversion system without the use of a transformer, using differential flatness.