A General Method to Study Multiple Discontinuous Conduction Modes in DC-DC Converters With One Transistor and Its Application to the Versatile Buck Boost Converter

The discontinuous conduction mode (DCM) is usually studied in single-diode and single-inductor converters, where only one DCM exists. However, multiple DCMs can appear in multidiode and multi-inductor topologies and the methodology to identify and characterize these multiple modes is not evident. In this article, a general method to study multiple DCMs is presented. The first step of the method consists in finding out the number n, which is the number of diodes conducting current passing exclusively through inductors when the transistor turns off. For a given n value, 2(n) possible conduction modes are expected: 1 continuous mode and 2(n)-1 DCMs. The second step is to create an n-dimensional space called k-space. In the k-space, the converter operation describes a straight line when the load changes. This straight line called converter trajectory passes through different n-dimensional enclosures. Each one of these enclosures represents a different conduction mode. The third step is to determine the borders between conduction modes which are subspaces of (n-1) dimensions. This method must be followed for both control strategies (i.e., open- and closed-loop controls). The proposed method is applied to the versatile buck-boost converter. Experimental results verify the theoretical analysis for all the identified conduction modes.

Automated summary

This article presents a general method to study multiple discontinuous conduction modes (DCMs) in multidiode and multi-inductor converters. The method involves determining the number of DCMs and creating an n-dimensional space called k-space to describe the converter operation. It also identifies the borders between conduction modes and provides experimental verification.