Wentworth Institute of Technology, Massachusetts
April 22, 2022
April 22, 2022
April 23, 2022
2
10.18260/1-2--42193
https://peer.asee.org/42193
373
Paul Crilly is a Professor of Electrical Engineering at the United States Coast Guard Academy. He is also Chief/Department Chair of the Electrical Engineering and Cyber Systems Section. He received his Ph.D. from New Mexico State University, his M. S. and B.S. degrees at Rensselaer Polytechnic Institute, all in Electrical Engineering. He was previously an Associate Professor of Electrical and Computer Engineering at the University of Tennessee and was a Development Engineer at the Hewlett Packard Company. His areas of interest include laboratory development, antennas, wireless communications, signal processing, and instrumentation.
Abstract – In this paper, we describe the theory, practical construction, and experiments of a plasma antenna to radiate a VHF signal. The primary goal is to provide an introduction to plasma antennas to undergraduate electrical engineering students and eliminate some of the mystery surrounding this antenna type. In our experiment, we implement a half-wave dipole whereby the conductor is a ionized gas or plasma that radiates a 120 MHz signal and is created using a 20 kHz source and mercury vapor gas contained in a florescent tube. We characterized the antenna’s voltage standing wave ratio (VSWR), input impedance, radiation characteristics, bandwidth and then compare these to a similar half-wave metallic dipole antenna. Our learning objectives of this project are how to practically implement a plasma antenna using easily obtainable, low-cost components, and experience how ionized gas, acts like any other metallic antenna element, and thus can be an effective RF radiator. Furthermore, by doing the experiments, undergraduates will better understand dielectric breakdown, how dielectric breakdown in a gas forms a conductor, quantum mechanics associated with how color or spectrum of the discharge is a function of the elements in a gas. We consider the practical advantages and disadvantages of plasma antennas as compared to their metal counterparts which include how a plasma antenna when de-energized, is stealthy, how multiple plasma antennas can be configured for spatial multiplexing and how other plasma structures can be added to form reflectors, directors, etc.
Crilly, P. B., & Blanco, J. (2022, April), Plasma antennas – a gentle introduction Paper presented at ASEE-NE 2022, Wentworth Institute of Technology, Massachusetts. 10.18260/1-2--42193
ASEE holds the copyright on this document. It may be read by the public free of charge. Authors may archive their work on personal websites or in institutional repositories with the following citation: © 2022 American Society for Engineering Education. Other scholars may excerpt or quote from these materials with the same citation. When excerpting or quoting from Conference Proceedings, authors should, in addition to noting the ASEE copyright, list all the original authors and their institutions and name the host city of the conference. - Last updated April 1, 2015