Shared antenna arrays with multiple independent tilt

What is claimed is: 1. A feed network for use with an antenna array, comprising: a. a first RF input for a first sub-band signal coupled to a first sub-band parameter control; b. a second RF input for a second sub-band signal coupled to a second sub-band parameter control; c. a combiner network having a first diplexer coupled to first outputs of the first and second sub-band parameter controls and a second diplexer coupled to second outputs of the first and second sub-band parameter controls, the combiner network also having a branchline hybrid having a first input coupled to the first sub-band parameter control and a second input coupled to the second sub-band parameter control, the combiner network also having at least one output comprising a combination of the first sub-band signal and the second sub-band signal; and d. a beamforming network, the beamforming network coupled to outputs of the branchline hybrid of the combiner network and having a plurality of RF outputs; wherein the first and second sub-band parameter controls are independently adjustable and wherein adjustment of the first and second sub-band parameter controls independently adjusts a down-tilt of first and second sub-band beams. 2. The feed network of claim 1 , wherein the first sub-band parameter control comprises a first differential phase shifter and the second sub-band parameter control comprises a second differential phase shifter. 3. The feed network of claim 2 , wherein adjusting the first differential phase shifter results in the first RF sub-band to have a first set of phase relationships on the plurality of RF outputs, and wherein adjusting the second differential phase shifter results in the second RF sub-band to have a second set of phase relationships on the plurality of RF outputs. 4. The feed network of claim 1 , further comprising a plurality of secondary beam tilt phase shifters, wherein the plurality of RF outputs are coupled to the plurality of secondary beam tilt phase shifters. 5. The feed network of claim 1 , further comprising at least one bypass path that provides at least one additional RF output that does not pass through the beamforming network. 6. The feed network of claim 1 , wherein the first sub-band parameter control divides the first sub-band signal into two equal amplitude, variable phase signals which are coupled to first and second inputs of the combiner network, and the second sub-band parameter control divides the second sub-band signal into two equal amplitude, variable phase signals which are coupled to third and fourth inputs of the combiner network. 7. The feed network of claim 6 , wherein the at least one output of the combiner network comprises a first output comprising a first portion of the first sub-band signal and a first portion of the second sub-band signal, and second output comprising a second portion of the first sub-band signal and a second portion of the second sub-band signal, wherein a power division of the first and second portions of the first sub-band signal is controlled by the first sub-band parameter control and a power division of the first and second portions of the second sub-band signal is controlled by the second sub-band parameter control. 8. The feed network of claim 7 , wherein the beamforming network comprises a Butler matrix. 9. The feed network of claim 1 , further comprising a third RF input for a third sub-band signal coupled to a third sub-band parameter control, wherein the combiner network is further coupled to the third sub-band parameter control and the at least one output of the combiner network further comprises a combination of the first, second and third sub-band signals. 10. An antenna, comprising: a. a feed network, having: 1. a first RF input for a first sub-band coupled to a first sub-band tilt control; 2. a second RF input for a second sub-band coupled to a second sub-band tilt control, the second sub-band tilt control being controllable independently with respect to the first sub-band tilt control; 3. a combiner network having a first branchline hybrid coupled to the first sub-band tilt control and a second branchline hybrid coupled to the second sub-band tilt control, the combiner network including a first diplexer coupled to first outputs of the first and second branchline hybrids and a second diplexer coupled to second outputs of the first and second branchline hybrids, the combiner network also having at least one output comprising a combination of the first sub-band signal and the second sub-band signal; and 4. a beamforming network, the beamforming network coupled to at least one output of the first and second diplexers of the combiner network and having a plurality of RF outputs; and b. an array of radiating elements, the radiating elements being coupled to the RF outputs. 11. The antenna of claim 10 , wherein the array of radiating elements further comprises a plurality of sub-arrays, each sub-array being coupled to one of the plurality of RF outputs and having a plurality of radiating elements. 12. The antenna of claim 10 , wherein secondary tilt devices couple the array of radiating elements to the RF outputs. 13. The antenna of claim 12 , wherein at least a portion of the array of radiating elements receive a signal that bypasses the secondary tilt devices. 14. The antenna of claim 12 , wherein the at least one output of the combiner network comprises a first output comprising a first portion of the first sub-band signal and a first portion of the second sub-band signal, and second output comprising a second portion of the first sub-band signal and a second portion of the second sub-band signal, wherein a power division of the first and second portions of the first sub-band signal is controlled by the first sub-band tilt control and a power division of the first and second portions of the second sub-band signal is controlled by the second sub-band tilt control. 15. The antenna of claim 14 , wherein the beamforming network comprises a Butler matrix. 16. The antenna of claim 10 further comprises at least one bypass path configured to provide an additional RF output that passes through a fixed phase delay element but does not pass through the combiner network and the beamforming network. 17. The antenna of claim 10 further comprises at least one bypass path configured to provide at least one additional RF output that does not pass through the beamforming network.