Antenna aperture with clamping mechanism

We claim: 1. An antenna comprising: a radial waveguide; an aperture operable to radiate radio frequency (RF) signals in response to an RF feed wave fed by the radial waveguide; and one or more clamping devices to apply a compressive force between the waveguide and the aperture while allowing lateral movement between the aperture and the waveguide. 2. The antenna defined in claim 1 wherein the one or more clamping devices comprises a spring clamp. 3. The antenna defined in claim 2 wherein the waveguide comprises metal and the aperture comprises a layer, and the coefficient of thermal expansion of the waveguide and the aperture are different. 4. The antenna defined in claim 3 further comprising a radio frequency (RF) choke operable to block RF energy from exiting through a gap between outer portions of the waveguide and the aperture, and wherein the layer is glass and the compressive force holds the layer against the RF choke while allowing lateral movement between the layer and the RF choke due to temperature variation. 5. The antenna defined in claim 4 wherein the RF choke comprises one or more slots in the outer portion of the waveguide in the gap with each of the one or more slots being used to block RF energy of a frequency band. 6. An antenna comprising: a radial waveguide; an aperture operable to radiate radio frequency (RF) signals in response to an RF feed wave fed by the radial waveguide; one or more clamping devices to apply a compressive force between the waveguide and the aperture; and a material between the waveguide and the aperture to provide a surface for the layer to slip across the waveguide. 7. The antenna defined in claim 6 wherein the material comprises one selected from a group consisting of: polyethylene terephthalate, PTFE, Polyethylene, and a Urethane-based material. 8. The antenna defined in claim 6 wherein the material is attached to an RF choke via pressure sensitive adhesive (PSA). 9. The antenna defined in claim 1 wherein no electrically conductive connection exists between the waveguide and the aperture. 10. The antenna defined in claim 1 wherein the aperture has an array of antenna elements, wherein the array comprises: a plurality of slots; and a plurality of patches, wherein each of the patches is co-located over and separated from a slot in the plurality of slots, forming a patch/slot pair, each patch/slot pair being controlled based on application of a voltage to the patch in the pair. 11. An antenna comprising: a radial waveguide; an aperture operable to radiate radio frequency (RF) signals in response to an RF feed wave fed by the radial waveguide, wherein the aperture has an array of antenna elements, wherein the array comprises: a plurality of slots and a plurality of patches, wherein each of the patches is co-located over and separated from a slot in the plurality of slots, forming a patch/slot pair, each patch/slot pair being controlled based on application of a voltage to the patch in the pair, wherein liquid crystal is between each slot of the plurality of slots and its associated patch in the plurality of patches; and one or more clamping devices to apply a compressive force between the waveguide and the aperture. 12. The antenna defined in claim 11 further comprising a controller operable to apply a control pattern that controls patch/slot pairs to cause generation of a beam for a frequency band for use in holographic beam steering. 13. An antenna comprising: a radial waveguide; an aperture operable to radiate radio frequency (RF) signals in response to an RF feed wave fed by the radial waveguide, wherein the coefficient of thermal expansion of the waveguide and the aperture are different; a layer between the waveguide and the aperture around which the feed wave travels to feed the plurality of antenna elements from outer edges of the layer; a radio frequency (RF) choke operable to block RF energy from exiting through a gap between outer portions of the waveguide and the aperture; and one or more clamping devices to apply a compressive force between the waveguide and the aperture. 14. The antenna defined in claim 13 wherein the one or more clamping devices comprise a spring clamp. 15. The antenna defined in claim 14 wherein the waveguide comprises metal and the aperture comprises a layer, and the coefficient of thermal expansion of the waveguide and the aperture are different. 16. The antenna defined in claim 15 wherein the layer is glass and the compressive force holds the layer against the RF choke while allowing lateral movement between the layer and the RF choke due to temperature variation. 17. The antenna defined in claim 13 wherein the RF choke comprises one or more slots in the outer portion of the waveguide in the gap with each of the one or more slots being used to block RF energy of a frequency band. 18. The antenna defined in claim 13 wherein no electrically conductive connection exists between the waveguide and the aperture. 19. The antenna defined in claim 13 wherein the aperture has an array of antenna elements, wherein the array comprises: a plurality of slots; a plurality of patches, wherein each of the patches is co-located over and separated from a slot in the plurality of slots, forming a patch/slot pair, each patch/slot pair being controlled based on application of a voltage to the patch in the pair. 20. The antenna defined in claim 19 wherein liquid crystal is between each slot of the plurality of slots and its associated patch in the plurality of patches. 21. The antenna defined in claim 20 further comprising a controller operable to apply a control pattern that controls patch/slot pairs to cause generation of a beam for a frequency band for use in holographic beam steering. 22. The antenna defined in claim 21 wherein the layer comprises at least one of a group consisting of a ground layer and a dielectric layer. 23. An antenna comprising: a radial waveguide; an aperture operable to radiate radio frequency (RF) signals in response to an RF feed wave fed by the radial waveguide, wherein the coefficient of thermal expansion of the waveguide and the aperture are different; a layer between the waveguide and the aperture around which the feed wave travels to feed the plurality of antenna elements from outer edges of the layer; a radio frequency (RF) choke operable to block RF energy from exiting through a gap between outer portions of the waveguide and the aperture; a material between the waveguide and the aperture and attached to the choke to provide a surface for an aperture layer to slip across the waveguide; and one or more spring clamps to apply a compressive force between the waveguide and the aperture, wherein the compressive force holds the aperture layer against the RF choke while allowing lateral movement between the aperture layer and the RF choke due to temperature variation. 24. The antenna defined in claim 23 wherein the material comprises one selected from a group consisting of: polyethylene terephthalate, PTFE, Polyethylene, and a Urethane-based material. 25. The antenna defined in claim 23 wherein the waveguide comprises metal and the aperture comprises an aperture layer, and the coefficient of thermal expansion of the waveguide and the aperture are different.