Dual polarized array antenna with modular multi-balun board and associated methods

What is claimed is: 1. An array antenna comprising: a plurality of dual polarized radiating elements on a first dielectric layer, the plurality of dual polarized radiating elements having a first dual polarized radiating element; and a modular, multi-layer, dual-balun board structure coupled directly to the first dual polarized radiating element, the modular, multi-layer, dual-balun board structure having a first balun to feed a first polarization orientation of the first dual polarized radiating element and a second balun to feed a second, orthogonal polarization orientation of the first dual polarized radiating element, the dual-balun board structure being held substantially perpendicular to the first dielectric layer and extending at least partially through an opening in the first dielectric layer; and the first dual polarized radiating element has first and second conductive members associated with the first polarization orientation and third and fourth conductive members associated with the second polarization orientation, wherein the first and third conductive members are coupled to first and third external contacts, respectively, located on a first surface of the modular, multi-layer, dual-balun board structure and the second and fourth conductive members are coupled to second and fourth external contacts, respectively, located on a second, opposite surface of the modular, multi-layer, dual-balun board structure. 2. The array antenna of claim 1 , wherein: a subset of the plurality of dual polarized radiating elements each have a corresponding modular, multi-layer, dual-balun board structure coupled thereto. 3. The array antenna of claim 1 , wherein: the plurality of dual polarized radiating elements define a plurality of unit cells on the first dielectric layer, wherein the modular, multi-layer, dual-balun board structure fits within an extension of the unit cell associated with the first dual polarized radiating element. 4. The array antenna of claim 1 , wherein: the modular, multi-layer, dual-balun board structure includes the first and second external contacts to carry a balanced signal associated with the first polarization orientation of the first dual polarized radiating element and the third and fourth external contacts to carry a balanced signal associated with the second polarization orientation of the first dual polarized radiating element. 5. The array antenna of claim 4 , wherein: the modular, multi-layer, dual-balun board structure includes a crossover network coupled between the first, second, third, and fourth external contacts and the balanced ports of the first and second baluns. 6. The array antenna of claim 1 , wherein: the opening in the first dielectric layer through which the dual-balun board structure passes cuts through a central portion of the first dual polarized radiating element. 7. The array antenna of claim 5 , wherein: the opening in the first dielectric layer through which the dual-balun board structure passes is diagonally oriented with respect to the first dual polarized radiating element. 8. The array antenna of claim 1 , wherein: the first dual polarized radiating element is a dual polarized dipole element. 9. The array antenna of claim 1 , wherein: the dual-balun board structure includes a ground plane separating the first balun and the second balun. 10. The array antenna of claim 1 , wherein: the dual-balun board structure includes a first coaxial connector coupled to a single-ended input port of the first balun and a second coaxial connector coupled to a single-ended input port of the second balun. 11. The array antenna of claim 1 , wherein: the plurality of dual polarized radiating elements includes a plurality of coincident-phase center, dual polarized radiating elements. 12. A method for use in fabricating an array antenna, the method comprising: providing an aperture board having a plurality of dual polarized radiating elements disposed thereon, the aperture board having openings through central regions of at least some of the dual polarized radiating elements; providing a modular, multi-layer, dual-balun board having a first balun to feed a first polarization orientation of a dual polarized radiating element and a second balun to feed a second, orthogonal polarization orientation of the dual polarized radiating element; inserting the modular, multi-layer, dual-balun board through an opening in the aperture board associated with a first dual polarized radiating element; and securing contacts on the modular, multi-layer, dual-balun board directly to corresponding conductive portions of the first dual polarized radiating element using a conductive coupling agent; and wherein the first dual polarized radiating element includes first and second conductive members associated with the first polarization orientation and third and fourth conductive members associated with the second polarization orientation, and wherein securing contacts includes securing the first and third conductive members to first and third contacts located on a first surface of the dual-balun board structure and securing the second and fourth conductive members to second and fourth contacts located on a second, opposite surface of the dual-balun board structure. 13. The method of claim 12 , wherein: the conductive coupling agent includes at least one of solder and conductive epoxy. 14. The method of claim 12 , wherein: the first and third conductive members are located on one side of the opening associated with the first dual polarized radiating element and the second and fourth conductive members are located on an opposite side of the opening. 15. The method of claim 14 , wherein: the contacts on the modular, multi-layer, dual-balun board structure include the first and second contacts conductively coupled to a balanced port of the first balun and the third and fourth contacts coupled to a balanced port of the second balun. 16. The method of claim 12 , further comprising: providing other modular, multi-layer, dual-balun boards having the same characteristics as the first board; inserting the other dual-balun boards through openings in the aperture board associated with other dual polarized radiating elements; and securing contacts on the other dual-balun boards directly to corresponding conductive portions of the other dual polarized radiating elements using a conductive coupling agent. 17. A multi-layer printed circuit board (PCB) comprising: a first balun having a single ended port and a balanced port, the first balun being implemented on one or more first layers of the PCB; a second balun having a single ended port and a balanced port, the second balun being implemented on one or more second layers of the PCB; first, second, third, and fourth external contacts, the first and third contacts located on a first exterior surface of the PCB and the second and fourth contacts located on a second exterior surface of the PCB opposite the first surface; and a crossover network to conductively couple the first and second exterior contacts to the balanced port of the first balun in a phase matched manner and to conductively couple the third and fourth exterior contacts to the balanced port of the second balun in a phase matched manner; and wherein a balun end of the crossover network includes first and second terminals on a first layer and third and fourth terminals on a second layer, and an antenna end of the crossover network includes the first and third terminals on the first layer and the second and fourth terminals on the s