Broadband low-beam-coupling dual-beam phased array

What is claimed: 1. A probe-fed patch radiating element comprising: a first printed circuit board (PCB), wherein a plurality of microstrip feed-lines are printed on the first PCB; a second PCB, wherein a plurality of fan-shaped probes are printed on the second PCB; an antenna reflector positioned in-between the first PCB and the second PCB; a plurality of feed wires extending through the antenna reflector, the plurality of feed wires conductively coupling the microstrip feed-lines to the fan-shaped probes; a radiating patch adapted to radiate during emission of a wireless signal; and one or more non-conductive spacers positioned in-between the radiating patch and the second PCB such that the radiating patch is electromagnetically coupled to, but not in direct physical contact with, the fan-shaped probes, the fan-shaped probes adapted to electromagnetically feed a radio frequency (RF) signal to the radiating patch that causes the radiating patch to radiate during emission of the wireless signal. 2. The probe-fed patch radiating element of claim 1 , wherein the fan-shaped probes have a fixed length. 3. The probe-fed patch radiating element of claim 2 , wherein a width of each of the fan-shaped probes increases across the fixed length. 4. The probe-fed patch radiating element of claim 1 , wherein each of the fan-shaped probes have a substantially identical shape. 5. The probe-fed patch radiating element of claim 1 , wherein each of the fan-shaped probes have substantially identical dimensions. 6. The probe-fed patch radiating element of claim 1 , wherein the fan-shaped probes extend inwardly towards a center of the second PCB. 7. The probe-fed patch radiating element of claim 6 , and wherein a width of each of the fan-shaped probes gradually increases as the fan-shaped probe extends inwardly towards the center of the second PCB. 8. A probe-fed patch radiating element comprising: a first printed circuit board (PCB), wherein a plurality of microstrip feed-lines are printed on the first PCB; a second PCB, wherein a plurality of fan-shaped probes are printed on the second PCB; an antenna reflector positioned in-between the first PCB and the second PCB; a plurality of feed wires extending through the antenna reflector, the plurality of feed wires conductively coupling the microstrip feed-lines to the fan-shaped probes; and a radiating patch adapted to radiate during emission of a wireless signal, the fan-shaped probes adapted to electromagnetically feed a radio frequency (RF) signal to the radiating patch that causes the radiating patch to radiate during emission of the wireless signal. 9. The probe-fed patch radiating element of claim 8 , wherein the fan-shaped probes have a fixed length. 10. The probe-fed patch radiating element of claim 9 , wherein a width of each of the fan-shaped probes increases across the fixed length. 11. The probe-fed patch radiating element of claim 8 , wherein each of the fan-shaped probes have a substantially identical shape. 12. The probe-fed patch radiating element of claim 8 , wherein each of the fan-shaped probes have substantially identical dimensions. 13. The probe-fed patch radiating element of claim 8 , wherein the fan-shaped probes extend inwardly towards a center of the second PCB. 14. The probe-fed patch radiating element of claim 13 , and wherein a width of each of the fan-shaped probes gradually increases as the fan-shaped probe extends inwardly towards the center of the second PCB. 15. A probe-fed patch radiating element comprising: a first printed circuit board (PCB), wherein a plurality of microstrip feed-lines are printed on the first PCB; a second PCB, wherein a plurality of fan-shaped probes are printed on the second PCB; an antenna reflector positioned in-between the first PCB and the second PCB; a plurality of feed wires extending through the antenna reflector, the plurality of feed wires conductively coupling the microstrip feed-lines to the fan-shaped probes; a radiating patch adapted to radiate during emission of a wireless signal; and one or more non-conductive spacers positioned in-between the radiating patch and the second PCB such that the radiating patch is electromagnetically coupled to, but not in direct physical contact with, the fan-shaped probes. 16. The probe-fed patch radiating element of claim 15 , wherein the fan-shaped probes have a fixed length. 17. The probe-fed patch radiating element of claim 16 , wherein a width of each of the fan-shaped probes increases across the fixed length. 18. The probe-fed patch radiating element of claim 15 , wherein each of the fan-shaped probes have a substantially identical shape. 19. The probe-fed patch radiating element of claim 15 , wherein each of the fan-shaped probes have substantially identical dimensions. 20. The probe-fed patch radiating element of claim 15 , wherein the fan-shaped probes extend inwardly towards a center of the second PCB. 21. The probe-fed patch radiating element of claim 20 , and wherein a width of each of the fan-shaped probes gradually increases as the fan-shaped probe extends inwardly towards the center of the second PCB.