Diffractive optical elements for large-field image display

What is claimed is: 1. A method, comprising: generating a wavefront modulating element (WME) based on a first image, the WME including a plurality of WME segments, each of the plurality of WME segments corresponding to a respective portion of the first image; generating, by an illumination system, a beam of electromagnetic radiation; and illuminating each of the plurality of WME segments with the beam of electromagnetic radiation at a specified angle of incidence, each of the plurality of WME segments being disposed upon a respective diffraction grating to produce a respective monolithic diffractive stack for that WME segment, the plurality of WME segments producing upon illumination a second image, a difference between the first image and the second image being less than a specified threshold. 2. The method as in claim 1 , wherein illuminating each of the plurality of WME segments includes coupling the beam of electromagnetic radiation into a light guide, the light guide including walls to which the WME is connected. 3. The method as in claim 2 , wherein the respective monolithic diffractive stack for each of the plurality of WME segments is configured to produce an approximation to the respective portion of the first image to which that WME segment corresponds, the respective monolithic diffractive stack for each of the plurality of WME segments being disposed on a wall of the light guide. 4. The method as in claim 3 , wherein the light guide includes walls, and wherein illuminating each of the plurality of WME segments includes: propagating the beam of electromagnetic radiation through the light guide via total internal reflection off the walls of the light guide; and collecting stray light reflected by the respective monolithic diffractive stack back into the light guide to produce illumination having substantially the same brightness when incident on each of the plurality of WME segments of the WME. 5. The method as in claim 2 , wherein generating the beam of electromagnetic radiation includes expanding and homogenizing the beam using a beam expander prior to the coupling of the beam of electromagnetic radiation into the light guide. 6. The method as in claim 1 , wherein generating the WME based on the first image includes: receiving intensity data representing the first image; performing an image decomposition operation to produce a plurality of sub-images of the first image, each of the plurality of sub-images representing a portion of the first image; and for each of the plurality of sub-images of the first image, performing an inverse imaging operation on that sub-image to produce a representation of a respective WME segment of a plurality of representations of WME segments. 7. The method as in claim 6 , wherein performing the inverse imaging operation on each of the plurality of sub-images of the first image includes: applying a Gerchberg-Saxton algorithm to each of the plurality of sub-images. 8. The method as in claim 6 , wherein the WME includes a diffractive optical element (DOE) and each of the plurality of WME segments includes a respective DOE segment of the DOE, and wherein each representation of a DOE segment of the plurality of WME segments includes a respective plurality of pixels, each of the respective plurality of pixels having one of a specified number of phase values. 9. The method as in claim 8 , wherein each of the respective plurality of pixels further includes an intensity value. 10. The method as in claim 6 , wherein generating the WME based on the first image further includes: arranging the plurality of WME segments based on the image decomposition operation to form the WME. 11. A system, comprising: a DOE generation system including controlling circuitry configured to generate a diffractive optical element (DOE) based on a first image, the DOE including a plurality of DOE segments, each of the plurality of DOE segments corresponding with a respective portion of the first image; an illumination system configured to generate a beam of electromagnetic radiation; and an imaging system configured to produce a second image upon illumination with the beam of electromagnetic radiation by illuminating each of the plurality of DOE segments with the beam of electromagnetic radiation, each of the plurality of DOE segments being disposed upon a respective diffraction grating to produce a respective monolithic diffractive stack for that DOE segment, the plurality of DOE segments forming the DOE and producing upon illumination a second image, a difference between the first image and the second image being less than a specified threshold. 12. The system as in claim 11 , wherein the imaging system configured to illuminate each of the plurality of DOE segments is further configured to couple the beam of electromagnetic radiation into a light guide, the light guide including walls to which the DOE is connected. 13. The system as in claim 12 , wherein the respective monolithic diffractive stack for each of the plurality of DOE segments is configured to produce an approximation to the respective portion of the first image to which that DOE segment corresponds, the respective monolithic diffractive stack for each of the plurality of DOE segments being disposed on a wall of the light guide. 14. The system as in claim 11 , wherein the respective diffraction grating has a pitch based on a maximum length of a segment of the DOE. 15. The system as in claim 13 , wherein the respective diffraction grating is configured to reflect illumination back into the light guide, the illumination propagating in the light guide in at least two orthogonal directions. 16. The system as in claim 12 , wherein light guide includes a mirror surface to couple the beam of electromagnetic radiation into the light guide. 17. The system as in claim 12 , wherein light guide includes a diffraction grating to couple the beam of electromagnetic radiation into the light guide. 18. A computer program product comprising a non-transitory storage medium, the computer program product including code that, when executed by processing circuitry of a computing device, causes the processing circuitry to perform a method, the method comprising: receiving intensity data representing an image; performing an image decomposition operation to produce a plurality of sub-images of the image, each of the plurality of sub-images representing a portion of the image; for each of the plurality of sub-images of the image, performing an inverse imaging operation on that sub-image to produce a wavefront modulating element (WME) segment of a plurality of WME segments, each of the plurality of WME segments corresponding to a respective sub-image of the plurality of sub-images; and arranging the plurality of WME segments based on the image decomposition operation to form a WME such that each of the plurality of WME segments is disposed upon a respective diffraction grating to produce a respective monolithic diffractive stack for that WME segment. 19. The computer program product as in claim 18 , wherein performing the inverse imaging operation on each of the plurality of sub-images of the image includes: applying a Gerchberg-Saxton algorithm to each of the plurality of sub-images. 20. The computer program product as in claim 18 , wherein each representation of a WME segment of the plurality of WME segments includes a respective plurality of pixels, each of the respective plurality of pixels having one of a specified number of phase values.