The research in the Power Electronic area at Queen's university covers a broad range of applications, from power transmission (from generator to main distribution transformer), to alternative energy (such as fuel cells, solar power and wind power), to power consumption (such as communication power systems, computer power systems), all the way to power application-specific ICs (PASIC).

With over 20 graduate students working under the supervision of its four members, the Power Electronics group is also home to the most advanced state-of-the-art power electronics lab in Canada; the ePOWER lab.

Our Research
Our Team
ePower Lab

About our research

In the high-power area, the group develops medium- and high-power converter topologies, switching techniques, and control schemes that can significantly improve the performance, simplicity, cost, and controllability of power converters for use in the power system industry for reactive power compensation, and renewable energy. In the alternative energy area, the group is focused on the applications of power electronics in distributed energy generation and in grid-connected distributed energy sources, and investigation of maximum power point tracking for grid-connected inverters, as well as performance monitoring, evaluation and modeling of photovoltaic, wind, and hybrid power systems.

In the communication and computer power system area, the group investigates new technologies to improve efficiency in order to both conserve natural resources as well as to meet stringent dynamic response requirements for the latest digital circuits, such as those encountered in different central processing units or even field-programmable gate arrays (FPGAs). Computer systems, including desktops, laptops, servers, and telecom power systems, use a distributed architecture to power their components. While advances in microprocessors place stringent regulation and transient requirements on the converters that power them, the proliferation of computing equipment necessitates efficiency improvements in all converter stages. Research is presently being conducted to meet these requirements by operating at high frequency with lossless switching, to increase switching frequency by using current-source MOSFET drivers through topological improvements, to develop new analog and digital control methods to achieve optimal dynamic performance, and to overhaul the power distribution system itself to reduce the number of converter stages, for example.

In order to meet the power requirements of microprocessors and other integrated circuits (ICs), power application-specific ICs (PASICs) represent the next generation in power conversion. The elimination of discrete components allows high-frequency operation, improved performance, and high power density to be achieved. Integration of the power architecture frees up precious board space, maximizing the number of computing functions that can be implemented. In the Power Electronics Group, projects are underway to examine the use of PASICs in both isolated and non-isolated converter architectures to achieve the aforementioned merits. In addition, PASIC-based research paves the way for integrated systems with power on-chip to further reduce the cost and complexity of digital systems.