Beam steering device

The invention claimed is: 1. A variable wavefront controlling device comprising: a variable wavefront component and a variable phase compensation component, the variable wavefront component including a two-dimensional array of individually variable wavefront deflection elements that are each arranged to encounter a different portion of a wavefront and to deflect the different portions of the wavefront along a first axis resulting in phase discontinuities between adjacent portions of the wavefront, the variable phase compensation component including a two-dimensional array of individually variable phase delay elements that are respectively arranged to encounter the different portions of the wavefront deflected by the variable wavefront deflection elements and to minimize the phase discontinuities between the adjacent portions of the wavefront. 2. The variable wavefront controlling device of claim 1 in which the two-dimensional array of individually variable wavefront deflection elements is a first two-dimensional array of individually variable wavefront deflection elements, and the variable wavefront component also includes a second two-dimensional array of individually variable wavefront deflection elements that are arranged for deflecting the different portions of the wavefront along a second orthogonally related axis. 3. The variable wavefront controlling device of claim 2 in which the first two-dimensional array of individually variable wavefront deflection elements includes an electrode stack across a physical transparent structure and the physical transparent structure of the first two-dimensional array of individually variable wavefront deflecting elements is filled with a layer of liquid crystal. 4. The variable wavefront controlling device of claim 3 in which the physical transparent structure includes an alignment layer that use anchoring energy to create a pre-tilt to the liquid crystal layer. 5. The variable wavefront controlling device of claim 2 in which the second two-dimensional array of individually variable wavefront deflecting elements includes a two-dimensional array of reflectors that are individually tiltable for deflecting the different portions of the wavefront along the second orthogonal axis by reflection. 6. The variable wavefront controlling device of claim 2 in which the first two-dimensional array of individually variable wavefront deflecting elements and the two-dimensional array of individually variable phase delay elements are arranged in relation to the second two-dimensional array of individually variable wavefront deflecting elements so as to encounter the wavefront en route both to and from the second two-dimensional array of individually variable wavefront deflecting elements. 7. The variable wavefront controlling device of claim 2 in which the individually variable wavefront deflecting elements of both the first and second two-dimensional arrays of individually variable wavefront deflecting elements have optical properties that are individually variable by a controlling influence. 8. The variable wavefront controlling device of claim 7 in which the individually variable wavefront deflecting elements of the first two-dimensional array of individually variable wavefront deflecting elements include individually addressable electrodes and electro-optical media responsive to different electric field strengths imparted by the individually addressable electrodes. 9. The variable wavefront controlling device of claim 8 in which the individually addressable electrodes impart gradient electric fields across the electro-optical media to adjust the relative direction or shape at which the different portions of the wavefront are propagated. 10. The variable wavefront controlling device of claim 7 in which the individually variable wavefront deflecting elements of the first two-dimensional array of variable wavefront deflecting elements include an electro-optical media comprising liquid crystals that are variably pre-tilted within the variable wavefront deflecting elements and subject to realignments by the presence of one or more electric fields. 11. The variable wavefront controlling device of claim 2 in which each of the individually variable wavefront deflecting elements of the first and second two-dimensional arrays of individually variable wavefront deflecting elements is optically aligned with one of the individually variable phase delay elements of the two-dimensional array of individually variable phase delay elements to compensate for phase discontinuities between the different portions of the wavefront that are individually deflected by the individually variable wavefront deflecting elements of the first and second two-dimensional arrays of variable elements. 12. The variable wavefront controlling device of claim 2 in which the individually variable wavefront deflecting elements of at least one of the first and second two-dimensional arrays of individually variable wavefront deflecting elements include at least one of variable-tilt micromirrors, variable-index liquid crystal filled prisms, rotatable diffraction gratings, tiltable diffraction gratings, and variable pitch diffraction gratings. 13. The variable wavefront controlling device of claim 1 in which the individually variable phase delay elements include at least one of deflectable membranes, piezoelectrically driven mirrors, translatable gratings, variable-index liquid crystal layers, electro-optical material layers, magneto-optical layers, and acousto-optical devices. 14. The variable wavefront controlling device of claim 1 in which the individually variable phase delay elements include electro-optical material layers and the electro-optical material layers include at least one of ferroelectric liquid crystals, nematic liquid crystals, electrowetting media, grating light valves, magneto-optical media, Faraday rotation media, photorefractive media, and PZLT. 15. The variable wavefront controlling device of claim 1 in which the variable wavefront component and the variable phase compensation component are arranged to impose an arbitrary spatial modulation onto the wavefront. 16. The variable wavefront controlling device of claim 1 in which the individually variable wavefront deflecting elements of the second two-dimensional array of individually variable wavefront deflecting elements include reflective surfaces so that the wavefront propagates more than once through the first two-dimensional array of individually variable wavefront deflecting elements. 17. The variable wavefront controlling device of claim 1 in which the variable phase compensation component is imaged onto the variable wavefront component. 18. The variable wavefront controlling device of claim 2 in which the second two-dimensional array of individually variable wavefront deflecting elements includes a two-dimensional array of micromirrors. 19. The variable wavefront controlling device of claim 2 in which the first two-dimensional array of individually variable wavefront deflecting elements includes an array of prisms between electrodes. 20. The variable wavefront controlling device of claim 2 in which the second two-dimensional array of individually variable wavefront deflecting elements includes a two-dimensional array of micromirrors and the first two-dimensional array of individually variable wavefront deflecting elements includes an array of prisms between electrodes. 21. The variable wavefront controlling device of claim 2 in which th