Abstract: An adjustable antenna positioning system feed is disclosed herein. The adjustable antenna positioning system feed includes a feed base, a splash plate assembly, and a feed insert. The feed base is configured to be coupled to a reflector. The splash plate assembly is configured to be removably coupled to the feed base. The adjustable antenna positioning system feed is in a primary arrangement when directly coupled. The feed insert is positioned between the feed base and the splash plate. The adjustable antenna positioning system feed is in a secondary arrangement when the feed insert is coupled with the feed base and the splash plate.

Abstract: A passive electronically scanned array in a number of phases. Initially, the array system configuration is determined followed by sizing the array, designing, building, and testing a 1D lens, and designing, building, and testing a 1×N switch network. This is followed by building and testing the array with associated 1D lenses, and integrating and testing switch networks connected to each lens in array. This is followed by design, build, test, and integration of the orthogonal switch matrix that connects to all of the lens switch matrixes, and system integration.

Abstract: A dual band horn feed antenna system having a single combined antenna having a plurality of sub apertures in a collocated environment. The sub apertures are individually coupled to a Tx/Rx and dual polarized capable high band circular waveguide realizing a two band realization with separate Tx and Rx channels. The OMT is realized by a plurality of phase and amplitude balanced signals oriented in such a way as to create balanced & symmetric E and H fields within the coaxial guide. A radiating structure is provided to minimize cross coupling of individual bands. An OMT integrated with a coaxial waveguide base structure where the frequency ratio of the center to outer waveguide structures is within the range on excess of 3:1 or more and thereby enabling adjacent frequency band maximized operation. Adjacent frequency bands will typically require center conductor tubes in a coaxial arrangement to be about 2:1 and certainly less than 3:1 in many cases.

Abstract: A passive electronically scanned array in a number of phases. Initially, the array system configuration is determined followed by sizing the array, designing, building, and testing a 1D lens, and designing, building, and testing a 1×N switch network. This is followed by building and testing the array with associated 1D lenses, and integrating and testing switch networks connected to each lens in array. This is followed by design, build, test, and integration of the orthogonal switch matrix that connects to all of the lens switch matrixes, and system integration.

Abstract: A dual band horn feed antenna system having a single combined antenna having a plurality of sub apertures in a collocated environment. The sub apertures are individually coupled to a Tx/Rx and dual polarized capable high band circular waveguide realizing a two band realization with separate Tx and Rx channels. The OMT is realized by a plurality of phase and amplitude balanced signals oriented in such a way as to create balanced & symmetric E and H fields within the coaxial guide. A radiating structure is provided to minimize cross coupling of individual bands. An OMT integrated with a coaxial waveguide base structure where the frequency ratio of the center to outer waveguide structures is within the range on excess of 3:1 or more and thereby enabling adjacent frequency band maximized operation. Adjacent frequency bands will typically require center conductor tubes in a coaxial arrangement to be about 2:1 and certainly less than 3:1 in many cases.

Abstract: Disclosed is a multiband jamming antenna for use with RF jamming systems. An exemplary embodiment of the antenna comprises high-band, medium-band and low-band radiating structures arranged in a collinear manner. The three radiating structures are operable in three respective overlapping frequency bands. In the exemplary embodiment, the high-band radiating structure comprises a hybrid biconical/dipole antenna disposed at an upper end of the antenna. The medium-band radiating structure is collinearly coupled to the high-band radiating structure and comprises upper and lower dipole elements that are tuned using a dual section coaxial transformer. The low-band radiating structure is collinearly coupled to the medium-band radiating structure. The low-band radiating structure comprises a coaxial Ruthroff UNUN transformer that is coupled to the low-band radiating structure, and a feeder cable that connected to the coaxial Ruthroff UNUN transformer, and the high-band, medium-band, and low-band radiating structures.

Abstract: Broadband omnidirectional, vertically polarized communications antenna systems are disclosed. The antenna systems comprises a plurality of center-fed stacked dipole radiating elements disposed along a central axis, a coaxial feed line coupled between each of the stacked radiating elements. In certain embodiments, a two-wire balun is coupled to a feed point of each radiating element and a shunt inductor and capacitor are coupled to each radiating element. Other embodiments do not require the use of the balun. Certain embodiments use a printed-circuit dipole having a flat shape. Other embodiments use a metal dipole having a cylindrical shape. The array antenna systems may be stacked vertically in separate bays each with its independent RF port.

Abstract: A biconical antenna is used to measure the intensity of incident RF electrical fields. The antenna comprises a pair of aligned rods with wires distributed around the rods to define conical cavities around each of the rods. A ferrite choke surrounds each of the rods within the conical cavities to choke off residence within the cavities.

Abstract: In an automatic tuning system for an antenna having a single variable reactance element, the power transmitted to the antenna and the power reflected from the antenna on the feedline are sensed. The variable reactance component of the antenna is adjusted until the ratio between the transmitted and reflected power on the feedline indicates that the standing wave ratio on the feedline is at a minimum, whereupon the antenna will be tuned. The adjustment of the variable reactance component is by a stepping motor controlled by a microprocessor, which is programmed to make calculations to determine when the standing wave ratio reaches a minimum.