-
Texas Instruments (TI) announced a new family of radiation-hardened and radiation-tolerant half-bridge gallium nitride (GaN) field-effect transistor (FET) gate drivers. This family of gate drivers includes the industry’s first space-grade GaN FET driver that supports up to 200V operation.
The devices are available in pin-to-pin compatible ceramic and plastic packaging options and support three voltage levels. TI’s advancements in space-grade power products enable engineers to design satellite power systems for all types of space missions using just one chip supplier.
Satellite systems are growing increasingly complex to meet the demand for more on-orbit processing and data transmission, higher-resolution imaging, and more precise sensing. To improve mission capabilities, engineers strive to maximize electrical power system efficiency. TI’s new gate drivers are designed to accurately drive GaN FETs with fast rise and fall times, improving power-supply size and density. This allows a satellite to more effectively use the power generated by its solar cells to perform mission functions.
“Satellites perform critical missions, from providing global internet coverage to monitoring climate and shipping activity, enabling humans to better understand and navigate the world,” said Javier Valle, product line manager, Space Power Products at TI. “Our new portfolio enables satellites in low, medium and geosynchronous earth orbits to operate in the harsh environment of space for an extended period of time, all while maintaining high levels of power efficiency.”
For more information, read the technical article, “How you can optimize SWaP for next-generation satellites with electronic power systems.”
Optimizing size, weight and power (SWaP) using GaN technology can:
- Improve electrical system performance.
- Extend mission lifetimes.
- Reduce satellite mass and volume.
- Minimize thermal management overload.
Designers can use the family for applications spanning the entire electrical power system.
- The 200V GaN FET gate driver is suitable for propulsion systems and input power conversion in solar panels.
- The 60V and 22V versions are intended for power distribution and conversion across the satellite.
TI’s family of space-grade GaN FET gate drivers offers different space-qualified packaging options for the three voltage levels, including:
- Radiation-hardened; Qualified Manufacturers List (QML) Class P and QML Class V in plastic and ceramic packages, respectively.
- Radiation-tolerant Space Enhanced Plastic (SEP) products.
John Dorosa, a TI systems engineer, will present “How to easily convert a hard-switched full bridge to a zero-voltage-switched full bridge” on Tuesday, March 18, 2025, at 9:20 a.m. Eastern time at the Applied Power Electronics Conference in Atlanta, Georgia. This industry session will feature TI’s TPS7H6003-SP gate driver.
Production quantities of the TPS7H6003-SP, TPS7H6013-SP, TPS7H6023-SP and TPS7H6005-SEP are available now on TI.com. Preproduction quantities of the TPS7H6015-SEP and TPS7H6025-SEP are also available, with the TPS7H6005-SP, TPS7H6015-SP and TPS7H6025-SP available for purchase by June 2025. Additionally, development resources include evaluation modules for all nine devices, as well as reference designs and simulation models.
Original – Texas Instruments
-
SemiQ Inc has announced a family of three 1200V SiC full-bridge modules, each integrating two of the company’s rugged high-speed switching SiC MOSFETs with reliable body diode. The modules have been developed to simplify the development of photovoltaic inverters, energy storage, battery charging and other high-frequency DC applications.
Available in 18, 38 and 77mΩ (RDSon) variants, the modules have been tested at voltages exceeding 1350V and deliver a continuous drain current of up to 102A, a pulsed drain current of up to 250A and a power dissipation of up to 333W.
Operational with a junction temperature of up to 175oC, the rugged B2 modules have exceptionally low switching losses (EON 0.13mJ, EOFF 0.04mJ at 25oC – 77mΩ module), low zero-gate voltage drain/gate source leakage (0.1µA/1nA – all modules) and low junction to case thermal resistance (0.4oC per watt – 18mΩ module).
“By integrating high-speed SiC MOSFETs with exceptional performance and reliability, our new QSiC 1200V family of full-bridge modules sets a new standard for power density and efficiency in demanding DC applications. This family of modules simplifies system design, and enables faster time-to-market for next-generation solar, storage, and charging solutions,” said Seok Joo Jang, Director of Module Engineering at SemiQ.
Available immediately, the modules can be mounted directly to a heat sink, are housed in a 62.8 x 33.8 x 15.0mm package (including mounting plates) with press fit terminal connections and split DC negative terminals.
Original – SemiQ
-
Gallium Nitride (GaN) technology plays a crucial role in enabling power electronics to reach the highest levels of performance. However, GaN suppliers have thus far taken different approaches to package types and sizes, leading to fragmentation and lack of multiple footprint-compatible sources for customers.
Infineon Technologies AG addresses this challenge by announcing the high-performance gallium nitride CoolGaN™ G3 Transistor 100 V in RQFN 5×6 package (IGD015S10S1) and 80 V in RQFN 3.3×3.3 package (IGE033S08S1).
“The new devices are compatible with industry-standard silicon MOSFET packages, meeting customer demands for a standardized footprint, easier handling and faster-time-to-market,” said, Dr. Antoine Jalabert, Product Line Head for mid-voltage GaN at Infineon.
The CoolGaN G3 100 V Transistor devices will be available in a 5×6 RQFN package with a typical on-resistance of 1.1 mΩ. Additionally, the 80 V transistor in a 3.3×3.3 RQFN package has a typical resistance of 2.3 mΩ. These transistors offer a footprint that, for the first time, allows for easy multi-sourcing strategies and complementary layouts to Silicon-based designs. The new packages in combination with GaN offer a low-resistance connection and low parasitics, enabling high performance transistor output in a familiar footprint.
Moreover, this chip and package combination allows for high level of robustness in terms of thermal cycling, in addition to improved thermal conductivity, as heat is better distributed and dissipated due to the larger exposed surface area and higher copper density.
Samples of the GaN transistors IGE033S08S1 and IGD015S10S1 in RQFN packages will be available in April 2025.
Original – Infineon Technologies
-
Infineon Technologies AG has made significant progress on its 200 mm silicon carbide (SiC) roadmap. The company will already release the first products based on the advanced 200 mm SiC technology to customers in Q1 2025. The products, manufactured in Villach, Austria, provide first-class SiC power technology for high-voltage applications, including renewable energies, trains, and electric vehicles. Additionally, the transition of Infineon’s manufacturing site in Kulim, Malaysia, from 150-millimeter wafers to the larger and more efficient 200-millimeter diameter wafers is fully on track. The newly built Module 3 is poised to commence high-volume production aligned with market demand.
“The implementation of our SiC production is progressing as planned and we are proud of the first product releases to customers,” said Dr. Rutger Wijburg, Chief Operations Officer of Infineon. “By ramping up SiC production in Villach and Kulim in phases, we are improving cost-efficiency and continuing to ensure product quality. At the same time, we are making sure our manufacturing capacities can meet the demand for SiC-based power semiconductors.”
SiC semiconductors have revolutionized high-power applications by switching electricity even more efficiently, demonstrating high reliability and robustness under extreme conditions, and by making even smaller designs possible. Infineon’s SiC products let customers develop energy-efficient solutions for electric vehicles, fast charging stations and trains as well as renewable energy systems and AI data centers.
The release to customers of the first SiC products based on the 200-millimeter wafer technology marks a substantial step forward in Infineon’s SiC roadmap, with a strong focus on providing customers with a comprehensive portfolio of high-performance power semiconductors that promote green energy and contribute to CO 2 reduction.
As “Infineon One Virtual Fab” for highly innovative wide-bandgap (WBG) technologies, Infineon’s production sites in Villach and Kulim share technologies and processes which allow for fast ramping and smooth and highly efficient operations in SiC and gallium nitride (GaN) manufacturing. The 200-millimeter SiC manufacturing activities now add to Infineon’s strong track record of delivering industry-leading semiconductor technology and power system solutions and strengthen the company’s technology leadership across the entire spectrum of power semiconductors, in silicon as well as in SiC and GaN.
Original – Infineon Technologies
-
The electronics industry is experiencing a significant shift towards more compact and powerful systems. To support this trend and further drive innovation at the system level, Infineon Technologies AG is expanding its portfolio of discrete CoolSiC™ MOSFETs 650 V with two new product families housed in Q-DPAK and TOLL packages.
These diverse product families, with top- and bottom-side cooling, are based on the CoolSiC™ Generation 2 (G2) technology and offer significantly improved performance, reliability, and ease of use. The product families target high- and medium-power switched-mode power supplies (SMPS) including AI servers, renewable energy, chargers for electric vehicles, e-mobility and humanoid robots, televisions, drives and solid-state circuit breakers.
The TOLL package offers outstanding Thermal Cycling on Board (TCoB) capability, enabling compact system designs by reducing the printed circuit board (PCB) footprint. When used in SMPS, it can also reduce system-level manufacturing costs. The TOLL package now fits an extended list of target applications, enabling PCB designers to further reduce costs and better meet market demands.
The introduction of the Q-DPAK package complements the ongoing development of Infineon’s new family of Topside Cooled (TSC) products, which includes CoolMOS™ 8, CoolSiC™, CoolGaN™ and OptiMOS™. The TSC family enables customers to achieve excellent robustness with maximum power density and system efficiency at low cost. It also enables direct heat dissipation of 95 percent, allowing the use of both sides of the PCB for better space management and reduction of parasitic effects.
The CoolSiC™ MOSFETs 650 V G2 in TOLL are now available in R DS(on) from 10 to 60 mΩ, while the Q-DPAK variant is available in 7, 10, 15 and 20 mΩ.
Original – Infineon Technologies
-
SemiQ Inc has announced the QSiC 1200V MOSFET, a third-generation SiC device that shrinks the die size while improving switching speeds and efficiency.
The device is 20% smaller versus QSiC’s second-generation SiC MOSFETs and has been developed to increase performance and cut switching losses in high-voltage applications. SemiQ is targeting a diverse range of markets including EV‑charging stations, solar inverters, industrial power supplies and induction heating.
It will be on display for the first time at the Applied Power Electronics Conference (APEC), on March 16-20, 2025.
In addition to having a drain-to-source voltage (VDS) of 1200 V, the MOSFET reduces total switching losses to 1646 µJ and has a low on-resistance (RDS,on) of 16.1 mΩ. It is available as a bare die or in a four-pin TO-247 4L discrete package measuring 31.4 x 16.1 x 4.8 mm, which includes a reliable body diode and a driver-source pin for gate driving.
High-quality Known Good Die (KGD) testing has been conducted using UV tape and Tape & Reels, with all parts undergoing testing and verification at voltages exceeding 1400V, as well as being avalanche tested to 800 mJ. Reliability is further improved through the device’s 100% wafer-level gate oxide burn-in screening and 100% UIL testing of discrete packaged devices.
The device has been developed to have a low reverse recovery charge (QRR 470 nC) and lower capacitance, improving switching speed, switching losses, EMI and overall efficiency; to be easy to parallel; and with a longer creepage distance (9 mm), improving electrical insulation, voltage tolerance and reliability.
Dr. Timothy Han, President at SemiQ said: “The move to Gen3 SiC further increases the benefits of SiC MOSFETs over IGBTs. These devices not only deliver vastly improved performance, but cut die size and cost versus previous generations. As a result, the launch of the QSiC 1200V opens the technology, and its benefits, to a far greater range of applications. The device delivers industry leading performance figures, notably on gate threshold voltage, and we’re delighted to be demonstrating this first at APEC.”
The QSiC 1200V MOSFETs has a continuous operational and storage temperature of -55oC to 175oC. It has a recommended operational gate-source voltage of -4/18 V, with a VGSmax of -8/22 V, and a power dissipation of 484 W (core and junction temperature 25oC).
For static electrical characteristics, the device has a junction-to-case thermal resistance of 0.26oC per watt (40oC per watt junction to ambient). Its Zero gate voltage drain current is 100 nA, with a gate-source voltage current of 10 nA. Its AC characteristics include a turn-on delay time of 21 ns with rise time of 25 ns; its turn-off delay time is 65 ns with a fall time of 20 ns.
An increased range of resistances is available in bare-die and TO-247 4L packages with the following options:
- 16 mΩ: GP3T016A120X / GP3T016A120H
- 20 mΩ: GP3T020A120X / GP3T020A120H
- 40 mΩ: GP3T040A120X / GP3T040A120H
- 80 mΩ: GP3T080A120X / GP3T040A120H
Both the 16 mΩ (AS3T016A120X / AS3T016A120H) and 40 mΩ (AS3T040A120X / AS3T040A120H) options have been qualified for Automotive Applications Product Validation according to AEC-Q101.
The SemiQ QSiC 1200V will be on display at the Georgia World Congress Center in Atlanta, from March 16 to 20, 2025. Visitors to SemiQ’s booth #1348 will have the opportunity to explore the new third-generation MOSFETs.
Original – SemiQ
-
MCC Semi announced four new components in advanced P-channel MOSFET lineup. Supporting -100V applications from battery protection to motor drives and high-side switches, MCAC085P10, MCAC055P10, MCU055P10, and MCU085P10 are made for reliability in challenging environments.
With a maximum on-resistance of 55mΩ or 85mΩ, these MOSFETs improve overall system efficiency while reducing power dissipation. Leveraging trench technology and superior thermal performance, these versatile solutions provide engineers with high power density in a compact DFN5060 or DPAK package.
New P-channel MOSFETs are the obvious choice for unmatched performance and effective power management.
Features & Benefits:
- Trench MOSFET Technology: Enhances current capacity and reduces on-resistance
- Low On-Resistance: A maximum RDS(on) of 55mΩ or 85mΩ minimizes power consumption and boosts efficiency
- Low Conduction Losses: Reduce heat generation while improving overall system operation
- Excellent Thermal Performance: Safeguards device from overheating during use in high-temp scenarios
- High Power Density: Available in compact DFN5060 and DPAK package options
Original – Micro Commercial Components
-
Vincotech announced the release of flow E3BP, an advancement of the company’s widely adopted flow 2 and flow E3 housing. Engineered to meet the increasingly challenging requirements for next-gen systems, the flow E3BP is the next step up the evolutionary ladder in power module technology across applications.
Designed to boost thermal performance and maximize power density, this advanced housing is the go-to option for high-power systems and next-generation applications. Featuring a specially treated surface, its convex baseplate provides a superior thermal contact to better disperse heat and handle more power with a smaller footprint.
The module’s CTI600 housing material holds up well to higher system voltages. Its isolation walls increase creepage and clearance distances. Pre-applied thermal interface material is optionally available, as are Press-fit pins. Rolling efficiency, reliability, and innovation into one exceptionally useful housing, the new flow E3BP meets demand for faster time to market, higher power ratings, and greater power density. An excellent fit for many different applications, it marks another stride towards a more sustainable future.
Developed with the increasingly challenging demands of renewable energy systems in mind, the flow E3BP is a remarkably efficient power module. Among others, it enables customers to design 350+ kW utility string PV inverters with just a single housing per phase, cutting 30% of the cost for a dual-module solution. It also serves to reduce the heatsink area by as much as 34% compared to flow E3, thereby increasing power density to 51%.
Chosen for its low inductivity, the new flow E3BP figures prominently in solar and ESS inverters for the utility and commercial segments. Today’s flow E3BP housing meets tomorrow’s 2000 V systems’ high voltage requirements, and the company aims to extend this product portfolio to address further applications such as motion control, industrial drives, and EV charging stations.
Determined to enable customers to bring their ideas to life, Vincotech continues to develop its range of power module housings, which now encompasses 24 options rated from less than 10 kW up to MW. The flow 2, flow S3, and flow E3 housings see wide use in solar and ESS applications. The latest addition to the line, the leading-edge flow E3BP, supports beyond 350 kW and pushes the envelope for PV and ESS solutions.
Original – Vincotech
-
FORVIA HELLA, an international automotive supplier, has selected the new CoolSiC™ Automotive MOSFET 1200 V from Infineon Technologies AG for its next generation 800 V DCDC charging solution. Designed for on-board charger and DCDC applications in 800 V automotive architectures, Infineon’s CoolSiC MOSFET comes in a Q-DPAK package. The device uses top-side cooling (TSC) technology, which enables excellent thermal performance, easier assembly and lower system costs.
“We are excited to continue our partnership with FORVIA HELLA, leveraging our high-efficiency SiC products based on TSC packages,” said Robert Hermann, Vice President of Automotive High-Voltage Chips and Discretes at Infineon. “We are continuously working to take e-mobility to the next level by providing state-of-the-art SiC solutions that meet the automotive industry’s stringent requirements for performance, quality, and system cost.”
“Our customers are at the center of our efforts. That is why we have chosen Infineon’s CoolSiC Automotive MOSFET 1200 V for our next generation of DCDC converters”, said Guido Schütte, Member of the Electronics Executive Board at FORVIA HELLA. “Together with Infineon, we will continue to offer sustainable and innovative products and comprehensive services that exceed our customers’ expectations and drive the development of advanced mobility.”
Infineon’s new CoolSiC Automotive MOSFET 1200 V in the Q-DPAK package is based on Gen1p technology and offers a drive voltage in the range of V GS(off)= 0 V and V GS(on)= 20 V. The 0 V turn-off enables unipolar gate control, which simplifies design by reducing the number of components in the PCB.
With a creepage distance of 4.8 mm, the package achieves an operating voltage of over 900 V without the need for additional insulation coating. Compared to backside cooling, the TSC technology ensures optimized PCB assembly, reducing parasitic effects and resulting in significantly lower leakage inductances. As a result, customers benefit from lower package parasitics and lower switching losses. Heat dissipation is further improved by diffusion soldering the chip with .XT technology.
Original – Infineon Technologies
-
Vishay Intertechnology, Inc. introduced 16 new 650 V and 1200 V silicon carbide (SiC) Schottky diodes in the industry-standard SOT-227 package. Designed to deliver high speed and efficiency for high frequency applications, the Vishay Semiconductors devices offer the best trade-off between capacitive charge (QC) and forward voltage drop for diodes in their class.
The devices consist of 40 A to 240 A dual diode components in a parallel configuration, and 50 A and 90 A single phase bridge devices. Built on state of the art thin wafer technology, the diodes feature a low forward voltage drop down to 1.36 V that dramatically reduces conduction losses for increased efficiency. Further increasing efficiency, the devices offer better reverse recovery parameters than Si-based diodes and have virtually no recovery tail.
Typical applications for the components will include AC/DC PFC and DC/DC ultra high frequency output rectification in FBPS and LLC converters for photovoltaic systems, charging stations, industrial UPS, and telecom power supplies. In these applications, the diodes’ low QC down to 56 nC allows for high speed switching, while their industry-standard package offers a drop-in replacement for competing solutions.
The diodes deliver high temperature operation to +175 °C and a positive temperature coefficient for easy parallelling. UL-approved to file E78996, the devices feature a large creepage distance between terminals and a simplified mechanical design for rapid assembly.
Original – Vishay Intertechnology
