Phased array line feed for reflector antenna

What is claimed is: 1. A reflector antenna, comprising: a balloon with a reflective surface and a transparent surface opposite the reflective surface, the reflective surface creating a line of focus; and a phased array line feed that emits or receives electromagnetic waves along the line of focus, the phased array line feed comprising: a plurality of substantially parallel disks inside the balloon; a plurality of substantially parallel metallic rods, inside the balloon, that extend through the substantially parallel disks substantially perpendicular to the substantially parallel disks; and a phase/power switching matrix, electrically connected to the substantially parallel metallic rods, that steers a beam of the reflector antenna by adjusting a phase or power difference between the metallic rods. 2. The reflector antenna of claim 1 , wherein the phase/power switching matrix steers the beam of the reflector antenna by adjusting the phase difference between the substantially parallel metallic rods. 3. The reflector antenna of claim 1 , wherein the phase/power switching matrix steers the beam of the reflector antenna by adjusting the power difference between the substantially parallel metallic rods. 4. The reflector antenna of claim 1 , wherein: the substantially parallel disks are metallic, and each of the substantially parallel metallic rods extends from a base of the phased array line feed through the substantially parallel metallic disks to a vertex of the phased array line feed. 5. The reflector antenna of claim 4 , wherein the substantially parallel metallic disks are spaced apart by a distance of approximately ½ of a wavelength of interest of the reflector antenna. 6. The reflector antenna of claim 4 , wherein distances between the substantially parallel metallic disks decrease from a maximum at the base of the phased array line feed to a minimum at the vertex of the phased array line feed. 7. The reflector antenna of claim 4 , wherein diameters of the substantially parallel metallic disks decrease from a maximum at the base of the phased array line feed to a minimum at the vertex of the phased array line feed. 8. The reflector antenna of claim 1 , wherein the substantially parallel metallic rods are spaced apart at a base of the phased array line feed by a distance of approximately 1/3.5 of a wavelength of interest of the reflector antenna. 9. The reflector antenna of claim 1 , wherein distances between the substantially parallel metallic rods decrease from a base of the phased array line feed base to a vertex of the phased array line feed. 10. The reflector antenna of claim 1 , wherein the phased array line feed has a length of approximately 12 percent of the diameter of the reflector antenna. 11. The reflector antenna of claim 1 , wherein the balloon is spherical. 12. The reflector antenna of claim 1 , wherein: the phased array line feed is configured to receive electromagnetic waves that pass through the transparent surface and are reflected off the reflective surface; and the phased array line feed is configured to emit electromagnetic waves that reflect off the reflective surface and pass through the transparent surface. 13. A method of making a reflector antenna having a wavelength of interest, the method comprising: providing a balloon with a reflective surface and a transparent surface opposite the reflective surface, the reflective surface creating a line of focus; and providing a phased array line feed that emits or receives electromagnetic waves along the line of focus by: providing a plurality of substantially parallel metallic disks inside the balloon; providing a plurality of substantially parallel metallic rods, inside the balloon, that extend through the substantially parallel disks substantially perpendicular to the substantially parallel disks; and electrically connecting a phase/power switching matrix, which steers a beam of the reflector antenna by adjusting a phase or power difference between the metallic rods, to the substantially parallel metallic rods. 14. The method of claim 13 , wherein the phase/power switching matrix steers the beam of the reflector antenna by adjusting the phase difference between the substantially parallel metallic rods. 15. The method of claim 13 , wherein the phase/power switching matrix steers the beam of the reflector antenna by adjusting the power difference between the substantially parallel metallic rods. 16. The method of claim 13 , wherein: the substantially parallel disks are metallic, and each of the substantially parallel metallic rods extends from a base of the phased array line feed through the substantially parallel metallic disks to a vertex of the phased array line feed. 17. The method of claim 16 , wherein the substantially parallel metallic disks are spaced apart by a distance of approximately ½ the wavelength of interest. 18. The method of claim 16 , wherein distances between the substantially parallel metallic disks decrease from a maximum at the base of the phased array line feed to a minimum at the vertex of the phased array line feed. 19. The method of claim 16 , wherein diameters of the substantially parallel metallic disks decrease from a maximum at the base of the phased array line feed to a minimum at the vertex of the phased array line feed. 20. The method of claim 13 , wherein the substantially parallel metallic rods are spaced apart by a distance of approximately 1/3.5 the wavelength of interest at a base of the phased array line feed. 21. The method of claim 13 , wherein distances between the substantially parallel metallic rods decrease from a base of the phased array line feed base to a vertex of the phased array line feed. 22. The method of claim 13 , wherein the phased array line feed has a length of approximately 12 percent of the diameter of the reflector antenna. 23. The method of claim 13 , wherein the balloon is spherical. 24. The method of claim 13 , wherein: the phased array line feed is configured to receive electromagnetic waves that pass through the transparent surface and are reflected off the reflective surface; and the phased array line feed is configured to emit electromagnetic waves that reflect off the reflective surface and pass through the transparent surface.