Quietening ultra-low-loss SiC & GaN waveforms

Completed

Energy Efficiency(Other)
Not Energy Related

Basic and strategic applied research

ENGINEERING AND TECHNOLOGY (Electrical and Electronic Engineering)

Not Cross-cutting

Dr BH Stark
Electrical and Electronic Engineering
University of Bristol

Standard

EPSRC

17 June 2018

16 June 2023

60 months

£1,980,066

Electrical engineering

South West

NC : Engineering

Dr BH Stark, Electrical and Electronic Engineering, University of Bristol

Dr S Djokic, Energy Systems, University of Edinburgh
Dr SJ Finney, Institute for Energy and Environment, University of Strathclyde
Dr D Holliday, Electronic and Electrical Engineering, University of Strathclyde
Dr P Judge, Sch of Engineering and Electronics, University of Edinburgh
Dr N McNeill, Electrical and Electronic Engineering, University of Bristol
Dr PD Mitcheson, Department of Electrical and Electronic Engineering, Imperial College London
Dr D Yates, Department of Electrical and Electronic Engineering, Imperial College London

Project Contact, TDK Lambda (UK)
Project Contact, Supply Design Limited
Project Contact, GaN Systems Inc, Canada
Project Contact, Sevcon Ltd
Project Contact, Ricardo AEA Limited
Project Contact, Delta Electronics Europe Ltd (UK)
Project Contact, Dynex Semiconductor Ltd
Project Contact, Cummins Power Generation Limited

Power electronics reduces our carbon footprint and contributes nearly 50bn per year to the UK economy and supports 82,000 skilled jobs in over 400 UK-based companies. Power electronic converters regulate the flow of power in most electrical devices, in electric vehicles etc. They do so by switching currents on and off, 10s of thousands of times per second, and the ratio of on-time to off-time determines the power flow. The efficiency, size, and weight of these converters are determined by the amount of waste heat generated. For example, the size of laptop power adapters has shrunk over the years, due to their increase in efficiency. In an electric car, waste heat causes power converters to be typically larger than the motors they are feeding. This heat is mostly produced in the instances when the transistors are switching.The power electronics industry is about to undergo significant change, as ultra-fast-transition transistors made from silicon carbide (SiC) or gallium nitride (GaN) have recently emerged. Their switching transitions are so short (below 10 nanoseconds) that, in principle, efficiency can be pushed to levels never achieved before. This could lead to a ten-fold miniaturisation, leading to converters that are much smaller than the motor being driven, or credit-card-sized laptop power adapters.The fast switching, however, comes with the downside of extreme electromagnetic noise, and industry is struggling to adopt these new technologies. Our project will provide answers to key uncertainties for adoption of these new technologies, namely how to drive the SiC and GaN power devices quickly, safely and quietly.The electromagnetic noise (EMI) is seen on an oscilloscope as sharp corners, rapid oscillations, and overshoot spikes, during the switching transitions.In this project, we are developing solutions to achieve clean switching, without these undesirable features, to quieten the EMI. These features are countered by feeding specially-shaped signal into the transistors' gates.The switching transition is too fast for any known signal generators and closed-loop control methods, or passive switching-aid (filtering) circuits to provide the required shaping of gate signals. Therefore, an alternative approach is adopted.We recently developed a chip that can adjust its current output every 100 picoseconds, i.e. the time it takes light to travel 3 cm. It is the only known driver chip that can interact frequently enough with a gate signal to shape these short sub-10 nanosecond switching transitions. We will create improved versions of this driver to drive gallium nitride and silicon carbide transistor gates with signals that are designed to soften the switching and cancel out unwanted high-frequency effects. The signals need to be changed automatically as the converter temperature changes, and when changes to its output power are requested. Also, each type of circuit requires slightly different signals. Therefore, automatic adaptation will be developed to simplify the use of this technology by industry. An interesting challenge is the safe generation of optimised gate signals, as the wrong signal can cause a power converter to fail. Another challenge is the regeneration of energy put into the gate, so that it can be used for the next switching event.The project develops microelectronics (high-speed, EMI-quietening gate drivers) and power electronics (converters and control systems). Industry advisors from 8 partner companies will steer the development for three years. In Year 4, the research is scaled down, and trials in UK-based industry set up to transfer knowhow, test the research, and provide new avenues for fundamental research.This research will help maintain the compatibility between emerging high-efficiency power electronics and modern ultra-low-power microelectronics that is increasingly susceptible to electromagnetic noise, and simplify and expedite industry adoption of SiC & GaN.

07/02/19