Brian Petted
Adjunct Associate Professor
- Milwaukee WI UNITED STATES
- Electrical Engineering and Computer Science
Brian Petted is an expert in RF and microwave engineering, RF system design, and electromagnetic fields.
Multimedia
Education, Licensure and Certification
B.S.
Electrical Engineering
Milwaukee School of Engineering
1985
Associate
Electronics Communication Engineering Technology
Milwaukee School of Engineering
1983
M.S.
Electrical Engineering
Marquette University
1987
Areas of Expertise
Accomplishments
Rockwell Engineering Pioneer Award
1994
Advanced Circuits and Processes Department
Social
Media Appearances
Interview with Brian Petted
EEWeb online
2013-01-09
How did you get into engineering?
My father and grandfather were both mechanical engineers, so basically I became interested in it because my father left his old textbooks lying around in the attic. I would snoop around, open them up and thought it looked interesting.
Event and Speaking Appearances
MIMO Channel Capacity: Part 1: SISO Channel Foundation
Seminar in Microwave Engineering Marquette University
2019-03-22
MIMO Channel Capacity: Part 2: Maximization of Mutual Information for SISO Channel
Seminar in Microwave Engineering Marquette University
2018-11-02
MIMO Antenna System Considerations: Antenna Correlation E ects
Seminar in Microwave Engineering Marquette University
2018-11-02
MIMO Simultaneous Beamforming and Null Steering in Linear Arrays: Eigen- mode Selection
Seminar in Microwave Engineering Marquette University
2018-04-27
MIMO Beamforming and Null-Steering
IEEE Joint Meeting Antennas and Propagation Society-Milwaukee MSOE
2017-12-11
Patents
Dual band multiple-input multiple-output antennas
US10763578B2
2020
Exemplary embodiments are disclosed of dual-band multiple-input multiple-output (MIMO) antennas. In an exemplary embodiment, an antenna generally includes a circuit board, a first antenna radiating element positioned on the circuit board, a second antenna radiating element positioned on the circuit board, and at least two antenna feeding elements extending from the circuit board.
Flexible planar inverted F antenna
US9450307B2
2016
A flexible inverted “F” antenna (PIFA) is shown. The flexible PIFA is not only applicable to flat surfaces, but it can be applied to curved surfaces, both convex and concave, without degrading performance. The flexible PIFA can also be used close to living bodies or to a metal surface without detuning. The flexible PIFA is formed from a flexible printed circuit board (PCB) having a metal layer on one side and over which a cover layer is positioned.
Di-pole wide bandwidth antenna
US6078298A
2000
A wideband receiver antenna that utilizes a right-circular cylinder-based reflector which is positioned one arc segment away from a di-pole receiving element for use with high definition television signal reception as well as FM receiver reception.
Biasing network for use with field effect transistor ring mixer
US5153469A
1992
A biasing network for use in conjunction with a mixer employing field effect transistors which provides for minimum conversion loss over a range of process and temperature conditions. The biasing circuit includes a first field effect transistor having a small gate periphery which is configured as a current source, a second or reference field effect transistor having a gate periphery substantially equal to the gate peripheries of the transistors in the mixer to which the biasing circuit is providing DC biasing voltages and a voltage divider which is functional in defining operating conditions for the reference transistor.
Selected Publications
Oscillator computer-aided design process utilizes s-parameter and time-domain techniques
Microwave Journal1990
S-parameter design has been the accepted method of designing MESFET oscillators. [1-3] The S-parameter theory describes the initial small signal conditions in which oscillations within a circuit may begin. When the oscillation signal amplitude grows to a high level, the operation of the MESFET becomes nonlinear and continued oscillation is unpredictable by S-parameter techniques.
An octave band GaAs analog phase shifter
IEEE1989
A GaAs variable-gain analog phase shifter, which operates with high phase and amplitude resolution over an octave band, has been demonstrated. An all-pass approach to the phase shifter design eliminated the need for bulky hybrid couplers and allowed better than 0.5 degrees phase resolution over an octave band.
