MUNICH, Germany--(BUSINESS WIRE)--Panasonic Corporation today announced that it will start mass production of a high-speed gate driver (AN34092B) optimized for driving its GaN power transistor X-GaN in November 2016. The company will also start mass production of two types of X-GaN (PGA26E07BA and PGA26E19BA) and provide solutions in combination with high-speed gate drivers.
GaN is one of the next generation semiconductor compounds that can achieve space and energy savings when applied to transistors used in various power units. A gate driver is required to drive a transistor; however, general gate drivers for conventional silicon (Si) transistors cannot exploit the potential of GaN transistors since the gate structure of GaN transistors is different from that of Si transistors.
The new high-speed gate driver (AN34092B) helps our X-GaN easily and safely achieves high-speed switching performance. It can drive transistors at high frequencies of up to 4 MHz and integrates the active miller clamp function[1] that prevents malfunction during high-speed switching. X-GaN achieves a 600 V breakdown enhancement mode[2] through our unique technology and features high-speed switching and low on-resistance[3]. The combination of X-GaN and dedicated high-speed gate drivers will contribute to significant space and energy savings of various power conversion units for industrial and consumer use.
X-GaN and dedicated high-speed gate drivers are suitable for various applications such as 100 W to 5 kW power supply units, inverters, data centers, mobile base stations, consumer electronics, audio-visual equipment, industrial and medical devices.
X-GaN and dedicated high-speed gate drivers will be exhibited at electronica 2016 in Munich, Germany from November 8 (Tuesday) to 11 (Friday) this year.
[Video]
Panasonic Starts Mass Production of Power
transistor, X-GaN
[English] http://channel.panasonic.com/contents/19314/
[German]
http://channel.panasonic.com/contents/19315/
*English
video is available to download at https://vimeo.com/190235768/a7a95b0b72.
[About High-speed gate driver (AN34092B)]
Lineup
AN34092B
Features
•
Driving transistors at high frequencies of up to 4 MHz that provide
space savings
• Achieving a high slew rate that contributes to
energy savings
• Integrating the active miller clamp function that
prevents malfunction during high-speed switching
Learn more about High-speed gate driver (AN34092B) at http://www.semicon.panasonic.co.jp/en/products/powerics/ganpower/#products-document
[About X-GaN]
Lineup
PGA26E07BA
(70 mΩ) and PGA26E19BA (190 mΩ)
Features
X-GaN
achieves a 600 V breakdown enhancement mode through our unique
technology and current collapse free[4]. Its high-speed
operations enable higher power conversion efficiency and further size
reduction.
Learn more about X-GaN at http://www.semicon.panasonic.co.jp/en/products/powerics/ganpower/
[Related information]
[Press release] Panasonic to Launch
Industry's Smallest Enhancement-Mode 600V GaN Power Transistors Package
(May 18, 2015)
http://news.panasonic.com/global/press/data/2015/05/en150518-4/en150518-4.html
[Movie]
Development story: Panasonic’s new generation power device, “X-GaN”
https://channel.panasonic.com/contents/16417/
Panasonic
Semiconductor Solutions Co., Ltd.
http://www.semicon.panasonic.co.jp/en/
[Note]
[1] Active miller clamp
The active miller clamp is a
function that directly fixes the gate voltage to the ground level to
reduce voltage spikes on the gate in noisy environments that may cause
malfunction of the transistor when it is switched off.
[2] Enhancement mode
An enhancement mode is a characteristic of
semiconductor devices that is normally switched off when no voltage is
applied to the gate. This is also called normally-off.
[3] Low on-resistance
On-resistance is the resistance between the
drain and the source electrode of a transistor when the transistor is
switched on. The lower the value is, the smaller the loss of the
transistor is.
[4] Current collapse
Current collapse is a phenomenon in which
electrons in the drain area are trapped by the energy of the high
voltage applied between the drain and the source electrode. Since the
trapped electrons prevent current flow from the drain to the source
electrode when the transistor is switched on, the on-resistance
increases.
About Panasonic
Panasonic
Corporation is a worldwide leader in the development of diverse
electronics technologies and solutions for customers in the consumer
electronics, housing, automotive, enterprise solutions and device
industries. Since its founding in 1918, the company has expanded
globally and now operates 474 subsidiaries and 94 associated companies
worldwide, recording consolidated net sales of 7.553 trillion yen for
the year ended March 31, 2016. Committed to pursuing new value through
innovation across divisional lines, the company uses its technologies to
create a better life and a better world for its customers. To learn more
about Panasonic: http://www.panasonic.com/global.