部落格:氮化鎵技術如何擊敗矽技術
Term: GaN FET
15 post(s) found

GaN + Digital Control + High-Performance Magnetics
Designing an Ultra-thin, Highly Efficient (>97%), Multilevel DC-to-DC Converter

GaN + Digital Control + High-Performance Magnetics<br>Designing an Ultra-thin, Highly Efficient (>97%), Multilevel DC-to-DC Converter
四月 07 2021

GaN-based solutions coupled with digital control and high-performance magnetics can increase efficiency, shrink the size, and reduce system costs for high density computing applications like ultra-thin laptops and high-end gaming systems.

As computers, displays, smart phones and other consumer electronics systems have become thinner and more powerful over the past decade, there is increasing demand for addressing the challenge of thinner solutions while extracting more power out of limited space.

The multilevel converter is an exceptional candidate to shrink the size of the magnetic components and achieve high efficiency in a compact solution. Leveraging the advantages of eGaN® FETs, such as small size and low loss, further enhances the performance of a multilevel solution. This blog will evaluate the EPC9148, a 48 V to 20 V, 250 W three-level converter using eGaN FETs and digital control which achieves a peak total system efficiency of 97.8% and only 4.1 mm component height.

How to Design a Bi-Directional 1/16th Brick 48 V-12 V Converter Using Monolithic GaN ePower™ Stage

How to Design a Bi-Directional 1/16th Brick 48 V-12 V Converter Using Monolithic GaN ePower™ Stage
十二月 15 2020

Brick DC-DC converters are widely used in data center, telecommunication and automotive applications, converting a nominal 48 V bus to (or from) a nominal 12 V bus. Advances in GaN integrated circuit (IC) technology have enabled the integration of the half bridge and gate drivers, resulting in a single chip solution that simplifies layout, minimizes area, and reduces cost.

This application note discusses the design of a digitally controlled bi-directional 1/16th brick converter using the integrated GaN power stage for 48 V-to-12 V application, with up to 300 W output power, and peak efficiency of 95%.

The standard dimension of the 1/16th brick converter is 33 x 22.9 mm (1.3 x 0.9 inch). The height limit for this design is set to 10 mm (0.4 inch).

How to Design a Highly Efficient, 2.5 kW, Universal Input Voltage Range, Power Factor Correction (PFC) 400 V Rectifier Using 200 V eGaN® FETs

How to Design a Highly Efficient, 2.5 kW, Universal Input Voltage Range, Power Factor Correction (PFC) 400 V Rectifier Using 200 V eGaN<sup>®</sup> FETs
十一月 03 2020

Acknowledgement - This application note and associated hardware was developed in collaboration with Semiconductor Power Electronics Center (SPEC) at University of Texas at Austin.

Motivation

The expansion of applications such as cloud computing, wearables, machine learning, autonomous driving, and IoT drive us towards an even more data-intensive world, increasing demands on data centers and power consumption [1, 2]. The importance of efficiency, power density, and cost of the AC to DC switching power supply is driving innovative solutions that eGaN FETs can solve to yield ultra-high efficiency power factor correction (PFC) front-end rectifier solutions that are the focus of this how-to-application note.

New 200 V eGaN Devices Double the Performance Edge Over the Aging Silicon Power MOSFET.

New 200 V eGaN Devices Double the Performance Edge Over the Aging Silicon Power MOSFET.
八月 21 2020

Efficient Power Conversion (EPC) is doubling the performance distance between the aging silicon power MOSFET and eGaN® transistors with 200 V ratings.  The new fifth-generation devices are about half the size of the prior generation.  This performance boost comes from two main design differences, as shown in figure 1.  On the left is a cross-section of the fourth generation 200 V enhancement-mode GaN-on-Si process.  The cross-section on the right is the fifth-generation structure with reduced distance between gate and source electrodes and an added thick metal layer. These improvements, plus many others not shown, have doubled the performance of the new-generation FETs.

eGaN FETs Are Low EMI Solutions!

eGaN FETs Are Low EMI Solutions!
五月 19 2020

GaN FETs can switch significantly faster than Si MOSFETs causing many system designers to ask − how does higher switching speeds impact EMI?

This blog discusses simple mitigation techniques for consideration when designing switching converter systems using eGaN® FETs and will show why GaN FETs generate less EMI than MOSFETs, despite their fast-switching speeds.

ePower™ Stage – Redefining Power Conversion

ePower™ Stage – Redefining Power Conversion
三月 16 2020

Beyond just performance and cost improvement, the most significant opportunity for GaN technology to impact the power conversion market comes from its intrinsic ability to integrate multiple devices on the same substrate. GaN technology, as opposed to standard silicon IC technology, allows designers to implement monolithic power systems on a single chip in a more straightforward and cost-effective way.

Today, the most common building block used in power conversion is the half bridge. In 2014, EPC introduced a family of integrated half-bridge devices which became the starting point for the journey towards a power system-on-a-chip. This trend was expanded with the introduction of the EPC2107 and EPC2108, which integrated half bridges with integrated synchronous bootstrap. In 2018 we further continued the integration path with the introduction of eGaN ICs combining gate drivers with high-frequency GaN FETs in a single chip for improved efficiency, reduced size, and lower cost. Now, the ePower™ Stage IC family redefines power conversion by integrating all functions in a single GaN-on-Si integrated circuit at higher voltages and higher frequency levels beyond the reach of silicon.

eGaN vs. Silicon

eGaN vs. Silicon
一月 23 2020

This post was originally published by Dr. John Glaser & Dr. David Reusch on June 13, 2016 on the Power Systems Design web site.

Comparing Dead-time Losses for eGaN FETs and Silicon MOSFETs in Synchronous Rectifiers

There have been several comparisons of eGaN FETs with silicon MOSFETs in a variety of applications, including hard-switched, soft-switched, and high-frequency power conversion. These studies have shown that eGaN FETs have large efficiency and power density advantages over silicon MOSFETs. Here we’ll focus on the use of eGaN FETs in synchronous rectifier (SR) applications and the importance of dead-time management. We show that eGaN FETs can dramatically reduce loss due to dead-time in synchronous rectifiers above and beyond the benefits of low RDS(on)and charge.

eGaN FETs and ICs Bring Precision Control to Surgical Robots

eGaN FETs and ICs Bring Precision Control to Surgical Robots
十一月 14 2018

Minimal invasive surgery using surgical robots gives unprecedented control to surgeons looking to achieve the next level of precision, thereby reducing risk and trauma to the patient and speeding recovery. Many motors are required to control the various robotic appendages, such as arms, joints, and tool control, that give the surgical robot the required degrees of freedom (DOF) and dexterity to perform extremely delicate tasks. Weight and size of motor control circuitry are thus important factors in the design of such robots as they directly impact the size of the motor that manipulates the robot’s appendages during surgery.

The motor of choice for robotic surgery is the 3-phase brushless DC (BLDC) motor These motors are compact for their power rating, can be precisely controlled, offer high electro-mechanical efficiency, and can operate with minimal vibration when properly controlled. The choice of motor voltage lies in the range of 24 V to 48 V with balancing power conductor thickness and weight with insulation thickness and stiffness for optimum performance and dexterity being the determining factors.

What Customers Are Asking About An Amazing New Technology – GaN-based Power System Solutions

What Customers Are Asking About An Amazing New Technology – GaN-based Power System Solutions
七月 24 2018

Enhancement-mode GaN power devices, (eGaN® FETs and ICs) provide the path for users to differentiate their end products. This new technology gives significantly higher efficiencies in the ever-present power supply and delivery circuits that fuel our gadgets and electronic equipment.

As the sales manager for the Americas, I am in the enviable position of working with customers to create a new vision of excellence so they continue to lead in their market space and contribute optimizing power consumption by reducing energy consumption.

Power systems designs introducing new technologies and approaches is always met with curiosity and evaluation. Customers always ask the most fundamental and far-reaching questions about the attributes and implementation of new technologies. Therefore, I thought documenting the most common questions I have received will help others considering the use of GaN technology pave the way to their confident adoption of this transitional technology.

Driving GaN Into The Fast Lane

Driving GaN Into The Fast Lane
六月 12 2018

Ask EPC's chief executive, Alex Lidow, what the future holds for his GaN power device business, and automotive certification features prominently.

Recently delivering AEC Q101-qualified 80 V discrete transistors for LiDAR, 48V power distribution systems and other applications, the company's latest enhancement-mode FETs deliver higher switching frequencies and efficiencies than silicon MOSFETs, in a smaller footprint. And this is just the beginning.

"We have more transistors as well as integrated circuits designed for LiDAR [sensors] and are proceeding with automotive certification here," highlights Lidow. "LiDAR is under intense cost and performance pressure so integrating components and improving performance while lowering the cost is a big deal."