Switch Stacking in Power Management ICs

authored by

Peter Renz, Maik Kaufmann, Michael Lueders, Bernhard Wicht

Abstract

The stacking of low-voltage transistors brings several advantages for the design of power management integrated circuits (PMICs). Process nodes and, thereby, the I/O voltage of the core devices shrink down, while the supply voltages of many applications cannot be reduced at the same rate. The stacking of low-voltage devices is often more area- and energy-efficient compared with using one high-voltage transistor. This work proposes an implementation option for the stacking of three low-voltage transistors, which, as a significant advantage, does not require additional supply rails as required in the prior art. It is independent of the input voltage and can, therefore, be widely used in different PMIC designs. The overall article is set up in a survey and tutorial style. It gives an overview of existing solutions and presents best-practice design guidelines for proper implementation of up to four stacked switches. The efficiency benefit of low-voltage transistor stacking over single high-voltage switches is investigated with a model of the transistor stack. Experimental results for loss energy and area consumption of various switch configurations in 130-nm CMOS confirm the presented design aspects. The advantages are also demonstrated by measurement results of a hybrid dc-dc converter with optimized power switch stacking.

Organisation(s)

Mixed-Signal Circuits Section

Type

Article

Journal

IEEE Journal of Emerging and Selected Topics in Power Electronics

Volume

9

Pages

3735-3743

No. of pages

9

ISSN

2168-6777

Publication date

29.07.2020

Publication status

Published

Peer reviewed

Yes

ASJC Scopus subject areas

Energy Engineering and Power Technology, Electrical and Electronic Engineering

Electronic version(s)

https://doi.org/10.1109/jestpe.2020.3012813 (Access: Closed)