GaN Talk a blog dedicated to crushing silicon
Term: 窒化ガリウム
11 post(s) found

High-Quality, Low-Cost Audio Achieved with GaN

High-Quality, Low-Cost Audio Achieved with GaN
Jul 29 2021

Until recently, to achieve high-quality sound from an audio amplifier cost thousands of dollars and relied on a large, heavy, power-hungry class-A amplifier. Now, the advent of gallium nitride FETs and ICs is ushering the age of high quality, lower cost class-D audio amplifiers. 

Distortion Performance Issues Lowered with GaN

Historically, meeting the required distortion performance targets (THD+N, TIM and IM) for high-quality audio, class-D amplifiers had to resort to incorporating large amounts of feedback circuitry to compensate for poor open-loop performance. The source of this distortion was the silicon power MOSFET.

Intelligent Power Amplifier Module based on GaN FETs

Intelligent Power Amplifier Module based on GaN FETs
May 10 2021

Guest GaN Talk Blog by: Pavel Gurev, Sinftech Rus LLC

This article originally appeared in Bodo’s Power Systems April 2021

In the past few years, gallium-nitride (GaN) FETs have become more widespread in power electronics. Due to their outstanding characteristics, GaN FETs play an increasingly important role in miniaturization of the switching converters with very high-power densities exceeding 100 W / cm3 and more. The efficiency of converters based on GaN transistors can reach 99.5%. Due to the extension of the conversion frequency towards the MHz range, the magnetic components (chokes, transformers) also decrease in size significantly. However, designers face numerous challenges in implementing practical GaN transistor designs. The best family members are presented in wafer-level chip-scale package; the drivers are also quite miniature.

eToF™ Laser Driver ICs for Advanced Autonomy Lidar

eToF™ Laser Driver ICs for Advanced Autonomy Lidar
Mar 22 2021

Co-written by Steve Colino

Laser drivers for light distancing and ranging (lidar) are used in a pulsed-power mode. What are the basic requirements for these laser drivers?

A new family of integrated laser driver ICs meets all these requirements.  The first release, the EPC21601 laser driver IC, integrates a 40 V, 10 A FET with integrated gate driver and 3.3 V logic level input in a single chip for time-of-flight (ToF) lidar systems used in robotics, surveillance systems, drones, autonomous cars, and vacuum cleaners. This chip offers frequency capability up to 200 MHz in a low inductance, economical, 1 mm x 1.5 mm BGA package.

Why GaN for DC-DC Space Designs

Why GaN for DC-DC Space Designs
Mar 03 2021

Power electronics engineers are constantly working towards designs with higher efficiency and higher power density while maintaining high reliability and minimizing cost. Advances in design techniques and improved component technologies enable engineers to consistently achieve these goals. Power semiconductors are at the heart of these designs and their improvements are vital to better performance. In this EPC space blog, we will demonstrate how GaN power semiconductors allow for innovation in the harsh radiation environments of space applications.

GaN power semiconductors offer designers in the high reliability market a sudden and significant improvement in electrical performance over their silicon power MOSFET predecessors. Table 1 compares radiation hardened GaN and Si power semiconductor device characteristics important for circuit designers to increase efficiency and power density in their converter.

How GaN is Revolutionizing Motor Drive Applications

How GaN is Revolutionizing Motor Drive Applications
Feb 09 2021

Rethinking the Ordinary and Overcoming Mental Biases

Motor drive applications span several markets: industrial, appliance, and automotive. A commonality that occurs regardless of market is that when a new technology is proposed, it faces resistance to its adoption; after all, it is human nature to stick with what is known and resist change.

Reduce Audible Noise in Motor Drive Designs Using eGaN FETs and ICs

Reduce Audible Noise in Motor Drive Designs Using eGaN FETs and ICs
Jan 15 2021

Brushless DC (BLDC) motors are popular and finding increasing application in robotics, e-mobility, and drones. Such applications have special requirements such as lightweight, small size, low torque ripple, low audible noise, and extreme precision control.  To address these needs, the inverters powering the motors need to operate at higher frequency but require advanced techniques to reduce the resultant higher power loss. Enhancement-mode gallium nitride (eGaN ®) transistors and integrated circuits offer the ability to operate at much higher frequencies without incurring significant losses. 

New 100 V eGaN Devices Increase Benchmark Performance Over the Aging Silicon Power MOSFET

New 100 V eGaN Devices Increase Benchmark Performance Over the Aging Silicon Power MOSFET
Sep 22 2020

Efficient Power Conversion (EPC) is increasing the performance distance between the aging silicon power MOSFET and eGaN transistors with 100 V ratings.  The new fifth-generation “plus” devices have about 20% lower RDS(on) and increased DC ratings compared with the prior fifth-generation products.  This performance boost comes from the addition of a thick metal layer and a conversion from solder balls to solder bars.

Why GaN in Space?

Why GaN in Space?
Jun 28 2020

Packaged SEE Immune and Radiation Hardened enhancement mode gallium nitride (eGaN) devices offer dramatically improved performance over the aging Rad Hard silicon MOSFET, enabling a new generation of power converters in space operating at higher frequencies, higher efficiencies, and greater power densities than ever achievable before.

ePower™ Stage – Redefining Power Conversion

ePower™ Stage – Redefining Power Conversion
Mar 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.

How to Design an eGaN FET-Based Power Stage with an Optimal Layout

How to Design an eGaN FET-Based Power Stage with an Optimal Layout
Oct 24 2018

Motivation

eGaN FETs are capable of switching much faster than Si MOSFETs, requiring more careful consideration of PCB layout design to minimize parasitic inductances. Parasitic inductances cause higher overshoot voltages and slower switching transitions. This application note reviews the key steps to design an optimal power stage layout with eGaN FETs, to avoid these unwanted effects and maximize the converter performance.

Impact of parasitic inductance on switching behavior

As shown in figure 1, three parasitic inductances can limit switching performance 1) power loop inductance (Lloop), 2) gate loop inductance (Lg), and 3) common-source inductance (Ls). The chip-scale package of eGaN FETs eliminates any significant inductance within the transistor itself, leaving the printed circuit board (PCB) as the main contributor. Each parasitic inductance is a consequence of the total area encompassed by the dynamic current path and its return loop. (See WP009: Impact of Parasitics on Performance).