Collimated transverse electric mode cavity antenna assembly

What is claimed is: 1. An apparatus comprising: an antenna assembly defining an upper cavity with an aperture, the antenna assembly further defining a lower cavity coupled to the upper cavity via a channel along a linear edge of the antenna assembly, wherein the antenna assembly comprises a reflective element within the lower cavity having a concave parabolic contour; and an array assembly positioned in the aperture and comprising an array of passive elements; wherein the reflective element transforms a divergent radio frequency (RF) beam directed toward the concave parabolic contour within the lower cavity into a collimated RF beam propagating within the lower cavity and into the upper cavity via the channel; and wherein the array of passive elements radiates a transmitted RF beam from the aperture in response to the collimated RF beam in the upper cavity. 2. The apparatus of claim 1 , wherein the antenna assembly further comprises: a baseplate having an upper surface; a cover plate having an upper surface and a lower surface, the cover plate being connected to the baseplate so that the upper surface of the baseplate and the lower surface of the cover plate at least partially define the lower cavity, wherein an edge of the baseplate and an edge of the cover plate at least partially define a lower linear orifice of the lower cavity at the linear edge of the antenna assembly; an upper plate having a lower surface and defining the aperture, wherein the lower surface of the upper plate, the array assembly, and the upper surface of the cover plate at least partially define the upper cavity, wherein the edge of the cover plate and an edge of the upper plate at least partially define an upper linear orifice of the upper cavity at the linear edge of the antenna assembly; and an cavity transfer element that couples the lower cavity to the upper cavity at the lower linear orifice and the upper linear orifice, wherein the cavity transfer element at least partially defines the channel. 3. The apparatus of claim 2 , wherein at least one of the baseplate, the cover plate, the upper plate, the cavity transfer element, or the reflective element comprises a conductive material. 4. The apparatus of claim 2 , wherein at least one of the baseplate, the cover plate, the upper plate, the cavity transfer element, or the reflective element comprises plastic at least partially covered with a conductive material. 5. The apparatus of claim 4 , wherein the conductive material comprises aluminum. 6. The apparatus of claim 1 , further comprising a transmitter that emits the divergent RF beam within the lower cavity toward the concave parabolic contour. 7. The apparatus of claim 1 , wherein an orientation of the array of passive elements about a central axis defined by the aperture relative to the antenna assembly determines an elevation angle of the transmitted RF beam relative to the array assembly. 8. The apparatus of claim 7 , further comprising: a bearing assembly that rotatably couples the array assembly to the antenna assembly; and a drive mechanism that rotates the array assembly about the central axis relative to the antenna assembly to alter the elevation angle of the transmitted RF beam relative to the array assembly. 9. The apparatus of claim 8 , wherein the drive mechanism comprises a worm gear to rotate the array assembly. 10. The apparatus of claim 1 , wherein an orientation of the antenna assembly about a central axis defined by the aperture relative to a platform determines an azimuth angle of the transmitted RF beam relative to the platform. 11. The apparatus of claim 10 , further comprising: a bearing assembly that rotatably couples the antenna assembly to the platform; and a drive mechanism that rotates the antenna assembly about the central axis relative to the platform to alter the azimuth angle of the transmitted RF beam relative to the platform. 12. The apparatus of claim 11 , wherein the drive mechanism comprises a worm gear to rotate the antenna assembly. 13. The apparatus of claim 11 , wherein the drive mechanism is mounted on the antenna assembly. 14. The apparatus of claim 1 , wherein the array of passive elements comprises one of an array of aperture-coupled radiators or an array of direct-coupled radiators. 15. The apparatus of claim 1 , wherein the array of passive elements comprises a patch antenna array. 16. The apparatus of claim 1 , wherein at least one of the divergent RF beam or the collimated RF beam comprises transverse electric (TE) mode waves. 17. The apparatus of claim 1 , wherein the array of passive elements generates a second collimated RF beam in the upper cavity directed toward the channel in response to receiving an external RF beam via the aperture, wherein the channel redirects the second collimated RF beam from the upper cavity to the lower cavity toward the concave parabolic contour, and wherein the concave parabolic contour generates, from the second collimated RF beam, a convergent RF beam directed toward a receiver within the lower cavity. 18. A system comprising: an antenna assembly defining an upper cavity with an aperture, the antenna assembly further defining a lower cavity coupled to the upper cavity via a channel along a linear edge of the antenna assembly, wherein the antenna assembly comprises a reflective element within the lower cavity having a concave parabolic contour; an array assembly positioned in the aperture and comprising an array of passive elements; a transmitter that emits a divergent radio frequency (RF) beam within the lower cavity toward the concave parabolic contour, wherein the concave parabolic contour transforms the divergent RF beam into a collimated RF beam propagating within the lower cavity and into the upper cavity via the channel, and wherein the array of passive elements radiates a transmitted RF beam from the aperture in response to the collimated RF beam in the upper cavity; a first drive mechanism that rotates the array assembly about a central axis defined by the aperture relative to the antenna assembly to alter an elevation angle of the transmitted RF beam relative to the array assembly; and a control system that operates the first drive mechanism to control the elevation angle of the transmitted RF beam relative to the array assembly. 19. The system of claim 18 , further comprising a second drive mechanism that rotates the antenna assembly about the central axis to alter an azimuth angle of the transmitted RF beam relative to a platform, wherein the control system operates the second drive mechanism to control the azimuth angle of the transmitted RF beam relative to the platform. 20. A method comprising: receiving, at a concave parabolic contour of a reflective element located within a lower cavity of an antenna assembly, a divergent RF beam; transforming, using the concave parabolic contour, the divergent RF beam into a collimated RF beam for propagation within the lower cavity toward a channel defined along a linear edge of the antenna assembly; redirecting, using the channel, the collimated RF beam into an upper cavity of the antenna assembly; and radiating, using an array of passive elements positioned in an aperture of the upper cavity, a transmitted RF beam from the aperture in response to the collimated RF beam in the upper cavity of the antenna assembly.