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A. P. Freundorfer
Also published under:Alois P. Freundorfer, Al P. Freundorfer, Alois Freundorfer, A. Freundorfer
Affiliation
Queen's University, Kingston, ON, Canada
Topic
Dielectric Constant,Antenna Array,Reflection Coefficient,Axial Ratio,Circularly Polarized,Dielectric Slab,Feed Antenna,Linearly Polarized,3D Printing,Array Configuration,Beam Scanning,Circularly Polarized Antenna,Dielectric Resonator,Dipole Antenna,Frequency Band,Global Navigation Satellite System,Ground Plane,High Gain,Leaky-wave,Leaky-wave Antenna,Left-handed Circularly Polarized,Lens Antenna,Loss Tangent,Low Temperature Co-fired Ceramic,Phase Shift,Planar Antenna,Plane Wave,Radiation Pattern,Reflectarray Antenna,Sidelobe Level,Substrate Integrated Waveguide,Surface Waves,Transmission Coefficient,3D Additive Manufacturing,3D Printing Techniques,Additive Manufacturing,Anechoic Chamber,Angular Position,Antenna Design,Antenna Gain,Antenna Polarization,Aperture,Array Elements,Attenuation Constant,Axial Ratio Bandwidth,Beamforming,Beampattern,Beamwidth,Central Source,Circular Patch,
Biography
Alois P. Freundorfer (SM’90) received the B.A.Sc., M.A.Sc., and Ph.D. degrees from the University of Toronto, Toronto, ON, Canada, in 1981, 1983, and 1989, respectively. In 1990, he joined the Department of Electrical Engineering, Queen’s University, Kingston, ON. Since 1990, he has been involved in the nonlinear optics of organic crystals, coherent optical network analysis, and microwave integrated circuits. He was involved in high speed IC design for use in lightwave systems with bit rates in excess of 40 Gb/s and in millimeter wave integrated circuits used in wireless communications. His current research interests include growing 3-D low temperature ceramics on ICs and printed circuit boards with applications to sensors and low power tunable circuits.