Accurate Modeling of the VHF Resonant Boost Converter Considering Multiple Parasitic Parameters

In recent years, very high frequency (VHF) converter has attracted much attention. However, with rich parasitic parameters and complex resonance links, there are some great difficulties to the modeling of such systems. Taking the on-off controlled VHF resonant boost converter as an example, this paper presents an accurate modeling and analysis method that considers multiple parasitic parameters. First, the closed-loop VHF converter system is divided into a main network and a parasitic oscillation network. Then, based on the operation analysis, an equivalent circuit model characterized by a time-varying input voltage source and two variable duty-cycle controlled switches is proposed. It worth noting that both the time-varying input and the controlled switches take into account the influences of the parameters. Furthermore, the periodic approximate analytical solution of the output voltage in the on stage is obtained by using the equivalent small parameter method to the proposed circuit model. And then combining the solution of the parasitic oscillation network and on-off state switching conditions, the steady-state waveform of output voltage can be obtained quickly. Finally, a prototype with operating frequency of 21.44 MHz is built to verify the effectiveness of the proposed method.

Automated summary

This paper presents an accurate modeling and analysis method for on-off controlled VHF resonant boost converter considering multiple parasitic parameters. By dividing the system into a main network and a parasitic oscillation network, and taking into account the influences of the parameters, an equivalent circuit model is proposed. The periodic approximate analytical solution of the output voltage is obtained by using the equivalent small parameter method, and the steady-state waveform of the output voltage can be quickly obtained by combining the solution of the parasitic oscillation network and on-off state switching conditions.