Products
Design & Development
Innovation Centre
At the Toshiba Innovation Centre we constantly strive to inspire you with our technologies and solutions. Discover how to place us at the heart of your innovations.
Knowledge
Highlighted Topics
Further Materials
Other
This webpage doesn't work with Internet Explorer. Please use the latest version of Google Chrome, Microsoft Edge, Mozilla Firefox or Safari.
require 3 characters or more.
The information presented in this cross reference is based on TOSHIBA's selection criteria and should be treated as a suggestion only. Please carefully review the latest versions of all relevant information on the TOSHIBA products, including without limitation data sheets and validate all operating parameters of the TOSHIBA products to ensure that the suggested TOSHIBA products are truly compatible with your design and application.
Please note that this cross reference is based on TOSHIBA's estimate of compatibility with other manufacturers' products, based on other manufacturers' published data, at the time the data was collected.
TOSHIBA is not responsible for any incorrect or incomplete information. Information is subject to change at any time without notice.
require 3 characters or more.
Alongside efficiency, thermal management and size, designers of power conversion applications need to consider switching speeds and EMI-related noise. The good news is that the latest MOSFET technologies not only reduce power consumption and heat dissipation – they also contribute to enhanced switching performance and reduced noise.
MOSFETs based on Toshiba’s latest UMOS VIII-H trench process, for example, offer excellent switching ripple suppression capability, which helps designers to reduce overall EMI noise. Target applications for the new MOSFET technology include automotive motors in 48V systems, DC-DC converters and load switches.
The new MOSFETs delivers a much tighter threshold voltage (Vth) specification – a very important consideration for switching applications - than previous devices. Tighter Vth specification can contribute to a dead time reduction in half-/H-/B6-bridge schemes. This is because the max Vth difference between low-side MOSFET and high-side MOSFET is smaller.
In applications where MOSFETs are connected in parallel, a tighter Vth spec leads to improved synchronous switching among paralleled MOSFETs. As a result, the switching loss will be distributed more evenly among the MOSFETs.
Toshiba's white paper on the latest silicon and package advances for power MOSFETs provides more information on the capabilities of these new technologies.
Click here…