This page partially uses JavaScript. This page may not operate normally when these functions are not supported by your browser or the setting is disabled.
Please look for the information you need from the following pages:

Asia-Pacific - English

Asia-Pacific - 简体中文

Asia-Pacific - 繁體中文

Asia-Pacific - 한국어

Asia-Pacific - 日本語

Americas - English

Europe (EMEA) - English

What are RC-IGBTs and IEGTs?

Download "Chapter III : Transistors" (PDF:2.0MB)

Reverse conductive IGBT : RC-IGBT

The structure of the RC-IGBT is shown in Fig. 3-16 (a). A diode is formed by making a part of the p-type layer, which is the collector of the IGBT, n-type. This diode has the same function as FWD * 1, which is generally inserted in the IGBT.
With the introduction of thin wafer technology, it became possible to commercialize this configuration. Since the diode and the IGBT are one chip, it is easy to assemble. Because it is difficult to control the performance of the diode and the IGBT separately, the RC-IGBT is unsuitable for certain applications.

*1: FWD—Free-Wheeling Diode. Generally, it is used to send reflux current generated by a reactor.

Injection-enhanced gate transistor : IEGT

Generally, in the high-voltage IGBT, it is difficult to obtain low V_{CE (sat)} characteristics because the carrier concentration of the drift layer (n-type layer) on the emitter side is low.
The IEGT was developed to obtain low V_{CE (sat)}performance at high withstand voltage (generally 1200 V or higher).
Fig. 3-16(b) shows the IEGT’s structure and principle.
It has a trench gate structure. Drawing out of the gate electrode is thinned out. As a result, carriers are accumulated just under the thinned gate electrode, increasing the carrier concentration on the emitter side.
This high carrier density decreases resistance of drift layer, and makes V_{CE (sat)} low.