Phase front shaping in one and two-dimensional optical phased arrays

The invention claimed is: 1. A optical structure comprising: an optical source that generates light; an array of waveguide-based emitters that emit the generated light; and an optical distribution network optically connecting the optical source to the array of waveguide-based emitters; wherein at least one of the optical distribution network or the waveguide-based emitters include passive optical delay lines having different effective optical path lengths based on effective refractive indices, where the effective optical path lengths are configured to at least partially determine a distribution of delays imposed upon different portions of the generated light, and the distribution of delays is configured such that the emitted light has a phase front that exhibits a substantially focusing or diverging shape. 2. The optical structure of claim 1 wherein the phase front is substantially hyperbolic in shape. 3. The optical structure of claim 2 wherein the hyperbolic phase front exhibits a positive hyperbolic (convex) shape. 4. The optical structure of claim 2 wherein the hyperbolic phase front exhibits a negative hyperbolic (concave) shape. 5. The optical structure of claim 2 wherein the hyperbolic phase front is substantially focused onto a focal point at a distance from the emitter array. 6. The optical structure of claim 5 wherein the waveguide-based emitters comprise an array of grating emitters configured to translate the phase front focused onto the focal point such that the focal point is in a direction out-of-plane relative to the phase front. 7. The optical structure of claim 2 wherein the distribution of delays is configured such that the phase front is substantially hyperbolic in shape. 8. The optical structure of claim 1 wherein the waveguide-based emitters comprise an array of grating emitters configured such that the phase front is translated in an out-of-plane direction relative to the array of waveguide-based emitters. 9. The optical structure of claim 1 wherein the waveguide-based emitters comprise an array of grating emitters configured to generate a perpendicular phase front substantially perpendicular to the phase front, said perpendicular phase front exhibiting a substantially non-linear shape. 10. The optical structure of claim 9 wherein the perpendicular non-linear phase front exhibits a substantially hyperbolic shape. 11. The optical structure of claim 9 wherein a grating period of at least one grating of the grating emitters changes along the grating. 12. The optical structure of claim 1 further comprising an iris positioned after the emitters and configured to spatially filter the phase front. 13. The optical structure of claim 1 wherein the phase front is defined by a function selected from the group consisting of: piecewise, conical, and Bessel functions. 14. The optical structure of claim 1 wherein the array of waveguide-based emitters comprise an array of grating emitters configured to emit the generated light, wherein at least one grating of the grating emitters has a period that changes along the grating. 15. A method of operating an optical structure, the optical structure comprising: an optical source that generates light; an array of waveguide-based emitters that emit the generated light; and an optical distribution network optically connecting the optical source to the array of waveguide-based emitters; wherein at least one of the optical distribution network or the waveguide-based emitters include passive optical delay lines having different effective optical path lengths based on effective refractive indices, where the effective optical path lengths are configured to at least partially determine a distribution of delays; the method comprising: operating the array of waveguide-based emitters such that the distribution of delays is imposed upon different portions of the generated light, wherein the distribution of delays is configured such that the emitted light has a phase front that exhibits a substantially focusing or diverging shape. 16. The method of claim 15 further comprising: operating the array of waveguide-based emitters such that the travel time from the source to a single common focal point is substantially the same for all emitted light. 17. The method of claim 15 further comprising: operating the array of waveguide-based emitters such that the light emitted from the emitters is substantially focused onto a single focal point. 18. The method of claim 15 further comprising: operating the array of waveguide-based emitters such that the light emitted from the emitters is substantially focused onto a plurality of focal points. 19. The method of claim 15 further comprising: operating an array of grating emitters in optical communication with the distribution network and waveguide portions of the waveguide-based emitters, such that the phase front is translated in a direction out of plane. 20. The method of claim 19 further comprising: configuring the array of grating emitters such that a pitch of the grating varies over its length. 21. The method of claim 20 further comprising: configuring the array of grating emitters such that the pitch of the grating is longest at a near end and shortest at a far end. 22. The method of claim 20 wherein the predetermined distribution of delays is configured such that the phase front is substantially hyperbolic in shape. 23. A optical structure comprising: an optical source that generates light; and an array of waveguide-based emitters that emit the generated light, wherein the emitted light has a phase front that exhibits a substantially focusing or diverging shape; an optical distribution network optically connecting the optical source to the array of waveguide-based emitters; and an iris positioned after the emitters and configured to spatially filter the phase front. 24. The optical structure of claim 23 , wherein at least one of the optical distribution network or the waveguide-based emitters include passive optical delay lines having different effective optical path lengths based on effective refractive indices, where the effective optical path lengths are configured to at least partially determine a distribution of delays.