Browsing by Author "Werntz, Paul C."

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    Analysis, design, and fabrication of Archimedean spiral antennas
    Werntz, Paul C. (Virginia Tech, 1988-08-05)
    The uses for wideband antennas include wideband measurement systems, spread spectrum communications systems, feeds for reflectors and elements in wideband arrays. Here, wideband antennas are discussed and Archimedean spiral antennas are found to be appropriate elements for use in a new type of wideband array referred to as the wideband switched array. The design of an Archimedean spiral and a necessary wideband balun transformer feed structure are presented. To aid in the design, the Electromagnetic Surface Patch Code (ESP) developed by Ohio State University is used. The spiral and feed structure are constructed and measured results are compared to predictions obtained by ESP.
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    A high gain tri-reflector antenna configuration for beam scanning
    Werntz, Paul C. (Virginia Tech, 1993)
    High resolution earth observation from geostationary orbit offers several advantages compared to traditional low earth orbit systems. Among the advantages are decreased time to scan the visible geo-disk and the ability to stare at a particular event. The following work is concerned with the design of a reflector antenna configuration for passive remote sensing and suitable for use on a geostationary platform; however, the resultant configuration is not limited to this application. The specific goal is the design of a reflector antenna configuration capable of precision beam scanning over a range of several degrees in all directions while minimizing vibration and inertial torque such as to have minimal effect on the other instruments sharing the platform. Desirable characteristics of such a reflector configuration are: a stationary feed consisting of a single element or a small array; simple reflector motions; and high primary aperture utilization for all scan directions (high illumination efficiency). This dissertation documents the development of a novel tri-reflector antenna configuration which addresses the design goals outlined above. The reflector configuration has been named the conjugate tri-reflector. The conjugate tri-reflector consists of a parabolic primary reflector an elliptical secondary reflector and a shaped tertiary reflector. Beam scanning is performed entirely by motion of the relatively small tertiary reflector. The proposed reflector configuration offers substantial improvement in scan performance compared to that achieved by feed displacement with a prime focus parabolic reflector and has a much higher aperture efficiency than comparable spherical reflector configurations.