Juri Jatskevich received the Electrical Engineering Degree (B.S.E.E.) from Ukrainian National Agricultural University, Kyiv, in 1994. He received the M.S.E.E. and the Ph.D. degrees in Electrical Engineering from Purdue University, West Lafayette, USA, in 1997 and 1999, respectively. Until 2002, he stayed at Purdue as a Post-Doctoral Research Associate and Research Scientist, and consulted with the P C Krause and Associates, Inc. Since 2002, he has been a faculty member at UBC, where he is now a Professor of Electrical and Computer Engineering and a Coordinator for the Electrical Energy Systems Option.
Dr. Jatskevich is a registered Professional Engineer in British Columbia. Dr. Jatskevich has chaired the IEEE CAS Power Systems & Power Electronic Circuits Technical Committee in 2009-2010 and is an editor of a number of IEEE publications including: IEEE Transactions on Energy Conversion, IEEE Power Engineering Letters, and Associate Editor of IEEE Transactions on Power Electronics Letters. He is also chairing the IEEE Task Force on Dynamic Average Modeling, under Working Group on Modelling and Analysis of System Transients Using Digital Programs. His research interests include power and energy grids, power electronic systems, electrical machines and drives, advanced modeling and simulation.
EECE 549 |
Dynamic Modeling of Electric Machines and Controls Numerical aspects of time-domain simulation are reviewed. Dynamic modeling and analysis of power systems components including transformers, induction and synchronous machines, inverters, electric drives and associated controls. |
ELEC 342 |
Electro-Mechanical Energy Conversion and Transmission Three phase power; transformers and harmonics; magnetic materials and circuits, electromechanical energy conversion; DC machines; rotating magnetic field, AC induction and synchronous machines; variable frequency operation, brushless DC machines; stepper and single-phase motors. Credit will only be given for one of EECE 373 or EECE 374. [3-3*-1] |
ELEC 493 |
Nanotechnology and Microsystems Capstone Design Project Design, analysis, and implementation of solutions in response to a real world nanotechnology and microsystems engineering problem. Projects are provided by industry, research laboratories, or other suitable entities. Includes coverage of topics such as project management. Students must have fourth year standing and be registered in the Nanotechnology and Microsystems Option to take this course. Find out more about Capstones. Prerequisite |
ELEC 343 |
Electromechanics Electromechanical energy conversion; linear actuators; torque/speed of rotating devices; reluctance, stepper, permanent-magnet, induction, brushless-DC motors and DC motors; actuator/motor drive circuits/controllers. Credit will only be given for one of ELEC 344, EECE 370, ELEC 342, EECE 374, or ELEC 343. Course Structure There will be 5 Lab Experiments. Laboratory experiments are an integral part of this course. In order to pass this course all students are required to attend, perform adequately and write reports for all experiments. |
2016 |
Improved Fault-Tolerant Control for Brushless Permanent Magnet Motor Drives With Defective Hall Sensors Journal Article | IEEE Transactions on Energy Conversion |
2016 |
Voltage-behind-reactance model of six-phase synchronous machines considering stator mutual leakage inductance and main flux saturation Journal Article | Electric Power Systems Research |
2016 |
Fault diagnosis and signal reconstruction of Hall sensors in brushless permanent magnet motor drives Journal Article | IEEE Transactions on Energy Conversion |
2016 |
Constant-Parameter Interfacing of Induction Machine Models Considering Main Flux Saturation in EMTP-Type Programs Journal Article | IEEE Transactions on Energy Conversion |
2016 |
Augmented Buck Converter Design using Resonant Circuits for Fast Transient Recovery Journal Article | IEEE Transactions on Power Electronics |
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