Transparent antenna

The invention claimed is: 1. A transparent antenna, comprising: a non-opaque substrate; a conductive material disposed on a surface of the substrate in one or more conductive regions, wherein a geometry of the conductive regions defines an antenna pattern; a non-conductive material disposed on the surface of the substrate in a fill pattern including one or more non-conductive regions, wherein the non-conductive material is a non-conductive ink, and wherein the fill pattern is an inverse of the antenna pattern within a defined region of interest; and wherein an average optical transparency in the conductive regions is at least 50%, wherein an average optical transparency in the non-conductive regions is at least 50%, and wherein the average optical transparency in the conductive regions differs from the average optical transparency in the non-conductive regions by no more than 10%. 2. The transparent antenna of claim 1 , wherein the non-conductive region shares one or more boundaries with the conductive region. 3. The transparent antenna of claim 1 , wherein the conductive material in the conductive region includes a pattern of interconnected microwires. 4. The transparent antenna of claim 3 , wherein the pattern of interconnected microwires is a mesh pattern. 5. The transparent antenna of claim 3 , wherein the non-conductive material in the non-conductive region includes a pattern of lines having a pattern geometry which matches that of the pattern of interconnected microwires in the conductive region. 6. The transparent antenna of claim 1 , wherein the non-conductive material in the non-conductive region includes a pattern of lines. 7. The transparent antenna of claim 6 , wherein the pattern of lines is a mesh pattern. 8. The transparent antenna of claim 1 , wherein the non-conductive material in the non-conductive region includes a pattern of halftone dots. 9. The transparent antenna of claim 1 , wherein the conductive material is a metal. 10. The transparent antenna of claim 1 , further including a protective layer of transparent material disposed over the conductive material and the non-conductive material on the surface of the substrate. 11. The transparent antenna of claim 1 , wherein the substrate is polyester, glass, polycarbonate or acrylic. 12. The transparent antenna of claim 1 , wherein the antenna pattern is visually indistinguishable from the fill pattern to a human observer. 13. The transparent antenna of claim 1 , wherein the transparent antenna is laminated onto a rigid window. 14. The transparent antenna of claim 13 , wherein the window is an automobile window, a building window or a helmet visor. 15. The transparent antenna of claim 13 , wherein the transparent antenna is positioned within a tinted portion of the window. 16. The transparent antenna of claim 15 , wherein the average optical transparency in the conductive region and the average optical transparency in the non-conductive region match an average optical transparency of the tinted portion of the window to within 10%. 17. The transparent antenna of claim 1 , wherein the transparent antenna is configured to operate at one of RF, microwave and millimeter-wave frequencies. 18. The transparent antenna of claim 1 , wherein the conductive region has a resistance of no more than 1 ohm/square. 19. The transparent antenna of claim 1 , wherein the average optical transparency in the conductive region is at least 80%, and wherein the average optical transparency in the non-conductive region is at least 80%. 20. The transparent antenna of claim 1 , wherein the average optical transparency in the conductive region differs from the average optical transparency in the non-conductive region by no more than 3%. 21. The transparent antenna of claim 1 , further including a transition region adjacent to the region of interest, wherein the transition region has an outer boundary and an inner boundary, the inner boundary corresponding to an outer boundary of the region of interest, wherein the non-conductive material is disposed on the surface of the substrate in the transition region, and wherein an average optical transparency in the transition region transitions from a first average optical transparency at the inner boundary to a higher second average optical transparency at the outer boundary.