Dynamic power stabilization model for improved conduction and switching loss using boost rectifiers

Abstract

The power stabilization is the key issue considered in electric circuits in recent days. The growing use of electricity increases the requirement of stabilized power supply to the devices. Towards this, various stabilization models are presented earlier with different converters and rectifiers. However, they suffer to produce high stabilized power supply to the circuits and devices. To improve the performance, an efficient dynamic power stabilization model with reduced conduction/switching loss is presented in this paper. Initially, the converter switches the incoming voltage in the series of conductors and maintains the output voltage. Consider the incoming voltage is IVi, then it has been regulated through a series of diodes and capacitors. At each parallel circuits, there exists a diode and capacitor which is capable of storing incoming voltage and enables to boost of the incoming voltage to step up to produce a higher voltage. A MOSFET is designed to control the output voltage to produce a steady voltage supply. It maintains the incoming and output voltage from different diodes. Based on the required voltage level, it triggers the conditions and triggers the circuits to maintain the voltage stability. As the MOSFET attached to the circuit maintains the conditions of capacitors and inductors in the previous cycle with the voltage available in each component, it performs power stabilization approximation, and according to that, a set of series circuits are switched to produce steady voltage. The parallel circuits are activated only when the input voltage is up to the required output voltage. Otherwise, the series circuit has been triggered to produce output voltage at the required level. Each series circuit has been embedded with a capacitor which is capable of storing incoming voltage and boost them to the higher voltage. The proposed method has increased the efficiency of boost rectifiers and produced efficient results than previous methods.