Sensorless Stabilization Technique for Peak Current Mode Controlled Three-Level Flying-Capacitor Converters

Abstract

This article describes a sensorless stabilization technique for peak current mode control of three-level flying-capacitor (3 ${\rm LFC}$ ) buck converters. The technique eliminates the well-known instability associated with the flying-capacitor (FC) voltage runaway, leading to stable and balanced FC voltage. In the proposed technique, the FC voltage imbalance is detected by measuring the duty cycle mismatch $D_{A}-D_{B}$ between two groups of switches of the 3 ${\rm LFC}$ topology, an information already available to the controller without any additional sensing. The resulting compensation leads to a compact solution, which can be easily embedded into an analog or digital integrated controller. Two distinct approaches are developed in this article to implement the required correction on $D_{A}-D_{B}$ , namely a sensorless peak offsetting modulation (PO-MOD) and a sensorless interleaving time modulation (IT-MOD). Operation, implementation challenges, and performances of both are investigated. The proposed solutions are verified through computer simulations and experimentally using a 16.5-to-3.3 V, 500 mA, 500 kHz 3 ${\rm LFC}$ prototype.