GaN Talk a blog dedicated to crushing silicon
Term: Gate Drivers
4 post(s) found

Making a Fast, Efficient, Small 350 V Half Bridge Module with eGaN FETs

Making a Fast, Efficient, Small 350 V Half Bridge Module with eGaN FETs
Aug 02 2022

Submitted by Richard Locarni, Director of New Business Development, Sensitron and Brian Miller, Field Application Engineer, EPC

The basic building block used in many power systems is the half bridge which consists of two power FETs in series and their respective gate drivers. While discrete FETs and gate drivers can be used to make this function on a board, often it is advantageous to use a half-bridge module.  There are many benefits of using a half-bridge module including the use of a single pre-qualified part, shorter lead times, and higher performance.  Sensitron (sensitron.com) has been a supplier of power modules for over fifty years, and their latest product is even more attractive due to the use of EPC’s eGaN FETs.  Sensitron collaborated with Efficient Power Corporation to use the recently released EPC2050 GaN FET to develop a 350 V half bridge module. Designed for commercial, industrial, and aerospace applications, the SPG025N035P1B half bridge intelligent power module is rated at 20 A and can be used to control over 5 kW.  Shown in Figure 1 is the significant package size reduction which was achieved by upgrading from Si and SiC to GaN:

The Growing Ecosystem for eGaN FET Power Conversion

The Growing Ecosystem for eGaN FET Power Conversion
May 18 2019

eGaN® FET-based power conversion systems offer higher efficiency, increased power density, and lower overall system cost than Si-based alternatives. These advantageous characteristics have spurred the presence of an ever increasing ecosystem of power electronics components such as gate drivers, controllers, and passive components that specifically enhance eGaN FET performance. Some examples of eGaN FETs are shown in figure 1.

The Growing Ecosystem for GaN Power Conversion

The Growing Ecosystem for GaN Power Conversion
Mar 21 2018

There are many reasons to increase frequency of power conversion.  Fundamentally, these reasons boil down to size/weight reduction, and cost reduction.  There are several components in the design of a power system that must perform efficiently at the targeted increased switching frequencies.  These include power switches, power switch drivers, controllers, magnetics, and capacitors. Taken collectively, these components represent the high frequency power conversion ecosystem.  Without any of these elements, the benefits of increased frequency cannot be fully realized.

More Data, More Apps, More Mobile…

More Data, More Apps, More Mobile…
Oct 18 2017

I don’t know about you, but in my house the number of mobile devices seems to multiply overnight, along with the ways they are used.  On any given night, you may find me on a GoToMeeting conference on my laptop, my husband on a video Skype chat from his phone with his dad in Florida, my oldest son turning in an assignment on Google Classroom from his laptop, my younger son streaming videos on his tablet, and my second grader recording and posting a music.ly on her phablet.  And when we travel, these devices come with us so they need to be small and lightweight enough to come along for ride! 

This all translates into ever-increasing power demands for computing and telecom systems and the conflicting desire for small, lightweight form factors, and extended battery life. To meet these demands, point-of-load (POL) DC-DC converters (the power engines) need to be designed to be small sized and as efficient as possible. These demands translate to ever faster switching frequencies of the transistors used in the power conversion running these devices. Notebook PCs, tablets, and phablets are especially sensitive to this need as our dependency on these devices and the demands we make on them continues to grow.