Docente
José Miguel Mamede Albuquerque Vieira Alberto

Resume

José Alberto was born in Coimbra, Portugal. In 2011, he obtained his MSc Degree in Electrical Engineering, Energy branch at the University of Coimbra, Portugal. In 2017, he received his PhD degree in Electrical Engineering at the University of Bologna, Italy, during which time he was a visiting scholar at CIRCE - Research Center for Energy Resources and Consumption in Zaragoza, Spain. Afterwards, he became a Post-Doctoral Fellow at the Institute of Systems and Robotics at the University of Coimbra, Portugal, and after an Invited Assistant Professor at University of Beira Interior, Covilhã, Portugal and Invited Assistant at the ISEC - Coimbra Institute of Engineering. He his currently an Assistant Professor at Universidade Lusófona and researcher at COPELABS. His research interests include Wireless Power Transfer, Resonator Arrays, Inductive Charging, Linear Motors and Actuators and Induction Motors.

Graus

• Mestrado
  Integrated Master's in Electrical and Computer Engineering
• Dottorato di Ricerca
  PhD in Electrical Engineering (Dottorato in Ingegneria Elettrotecnica)

Publicações

Journal article

• 2020-07, Inverses of k-Toeplitz matrices with applications to resonator arrays with multiple receivers, Applied Mathematics and Computation
• 2020-04, Study of a linear actuator with a hybrid core using sensorless position control, Sensors and Actuators A: Physical
• 2020-03-26, Fully Untethered Battery-free Biomonitoring Electronic Tattoo with Wireless Energy Harvesting, Scientific Reports
• 2019, Accurate calculation of the power transfer and efficiency in resonator arrays for inductive power transfer, Progress In Electromagnetics Research B
• 2018, Fast calculation and analysis of the equivalent impedance of a wireless power transfer system using an array of magnetically coupled resonators, Progress In Electromagnetics Research B

Book chapter

• 2021, Experimental Study on Three-Phase Induction Motor Performance Under Supply Voltage Unbalance for Star and Delta Connections, Energy Efficiency in Motor Systems, Springer International Publishing
• 2020, Study of the Equivalent Impedance of a Resonator Array Using Difference Equations, Differential and Difference Equations with Applications, Springer International Publishing

Conference paper

• Saturation-Related Losses in Induction Motors for Star and Delta Connection Modes
• Model of Misalignment Tolerant Inductive Power Transfer System for EV Charging
• Induction Motor Shaft-Frame Voltage Analysis
• Experimental Study on the External Shaft Axial Stray Flux in Squirrel-Cage Induction Motors
• 2022-09-05, Induction Motor Tolerance to Supply Voltage Unbalance for Different Dual-Winding Configurations
• 2022-06-15, Maximizing Energy Transfer in Wireless Power Transfer Systems Using Maximum Power Point Tracking for In-Motion EV and PHEV Charging
• 2022-06-14, Center-Fed Resonator Array for Increased Misalignment Tolerance in Automotive Wireless Power Transfer
• 2020-08-23, A Stochastic Optimization Approach to the Estimation of Squirrel-Cage Induction Motor Equivalent Circuit Parameters
• 2020-02, Voltage Unbalance Impact on Coil-Side Temperature Rise in a Delta-Connected, Dual-Winding Induction Motor
• 2019-10, Experimental Analysis of Three-Phase Induction Motors with Multiflux, Dual-Winding Configurations
• 2018-09, Study and Design of a Small-Diameter Tubular Linear Motor for Biomedical Applications, 2018 XIII International Conference on Electrical Machines (ICEM)
• 2018-09, Multilayer Flat Spiral Resonators for Low Frequency Wireless Power Transfer, 2018 IEEE-APS Topical Conference on Antennas and Propagation in Wireless Communications (APWC)
• 2017, Study of the conducted emissions of an IPT system composed of an array of magnetically coupled resonators
• 2016-09, Circuit model of a resonator array for a WPT system by means of a continued fraction
• 2016, Magnetic near field from an inductive power transfer system using an array of coupled resonators
• 2015, Experimental study on the termination impedance effects of a resonator array for inductive power transfer in the hundred kHz range