Multizone illumination for optical face identification

What is claimed is: 1. An electronic device capable of detecting a person's face by optical sensing, comprising: a face illumination source that includes: a periodic array of face illumination light sources arranged at different locations from one another, each operable to produce a face illumination light beam of a plurality of face illumination light beams and including an optical projection device that projects the face illumination light beam along a face illumination direction that is different from a face illumination direction of an adjacent face illumination light source; and a diffractive optical element structured to include an array of different regions with designated optical thickness values that transmit light to convert each face illumination light beam into a patterned face illumination light beam that includes a pattern of illumination light spots, such that the different face illumination light beams from the periodic array of face illumination light sources are converted by the diffractive optical element into different patterned face illumination light beams along different illumination directions each including the pattern of illumination light spots to illuminate the person's face for optically detecting the person's face, wherein the diffractive optical element is located in optical paths of the plurality of face illumination light beams. 2. The device as in claim 1 , wherein: the periodic array of face illumination light sources is structured to render the different patterned face illumination light beams along different illumination directions to illuminate different adjacent regions of the person's face without spatial overlap between adjacent regions. 3. The device as in claim 1 , wherein: the periodic array of face illumination light sources is structured to render the different patterned face illumination light beams along different illumination directions to illuminate different adjacent regions of the person's face with partial spatial overlap between adjacent regions. 4. The device as in claim 1 , wherein: the array of different regions of varying optical thickness values of the diffractive optical element is structured to cause the illumination light spots to be spatially distributed to have a unique local pattern of illumination light spots in each local region in the spatial pattern that is different from other local regions in the spatial pattern. 5. The device as in claim 4 , comprising: a face imaging device located relative to the face illumination source to receive illumination light from the person's face illuminated by the different patterned face illumination light beams along different illumination directions that carries a person's facial topographical information, wherein the face imaging device captures the spatial optical pattern in each image that is associated with a location on the face based on the spatial optical pattern. 6. The device as in claim 1 , wherein: in the periodic array of face illumination light sources, the optical projection device in each face illumination light source includes one or more collimation lenses. 7. The device as in claim 1 , wherein: in the periodic array of face illumination light sources, each face illumination light source includes a semiconductor laser to emit a face illumination light beam. 8. The device as in claim 1 , wherein: in the periodic array of face illumination light sources, each face illumination light source includes a vertical-cavity surface-emitting laser to emit a face illumination light beam. 9. The device as in claim 1 , further comprising: a face imaging device located relative to the face illumination source to receive illumination light from the person's face illuminated by the different patterned face illumination light beams along different illumination directions that carries a person's facial topographical information; and a face imaging processing device coupled to receive output of the face imaging device and to extract the person's facial topographical information for face identification. 10. The device as in claim 1 , wherein: the face illumination source includes an illumination controller coupled to control the face illumination light sources, respectively, to operate in a pulse mode to produce high power light pulses in each face illumination light beam; and the device further includes an imaging device to capture images in reflected light from the face illuminated by the pattern of illumination light spots in synchronization with the pulse mode. 11. The device as in claim 1 , wherein the face illumination light sources include light emitting diodes. 12. The device as in claim 1 , wherein the face illumination light sources include laser diodes. 13. The device as in claim 1 , wherein the face illumination light sources include vertical-cavity surface-emitting lasers (VCSELs). 14. A method for detecting a person's face by optical sensing, comprising: operating a periodic array of face illumination light sources arranged at different locations from one another to cause each face illumination light source to produce a face illumination light beam; projecting each face illumination light beam along a designated face illumination direction that is different from a face illumination direction of an adjacent face illumination light source; operating a diffractive optical element in optical paths of the face illumination light beams to convert each face illumination light beam into a patterned face illumination light beam that includes a pattern of illumination light spots so that different patterned face illumination light beams along different illumination directions from the face illumination light sources to illuminate the person's face for optically detecting the person's face, wherein the diffractive optical element is structured to include an array of different regions of varying optical thickness values to cause the pattern of illumination light spots to have a unique local pattern of illumination light spots in each local region that is different from other local regions; capturing images in reflected light from the person's face that are sequentially generated by sequentially turning on one face illumination light source at a time and different face illumination light sources at different times; and processing the captured images to extract 3-dimensional facial features of the person's face for face identification. 15. The method as in claim 14 , further comprising: controlling the face illumination light sources, respectively, to operate in a pulse mode to produce high power light pulses in each face illumination light beam; and synchronizing capturing of the images and a timing of the pulse mode to improve a signal-to-noise ratio in the captured images. 16. The method as in claim 14 , wherein: the method includes using the spatial pattern to determine the location on the face from which an image is generated by optical reflection. 17. The method as in claim 14 , wherein: in the periodic array of face illumination light sources, the optical projection device in each face illumination light source includes one or more collimation lenses. 18. A system, comprising: a periodic array of face illumination light sources arranged at different locations from one another, each operable to produce a face illumination light beam and including an optical projection device that projects the face illumination light beam along a face illumination direction that is different from a face illumination direction of an adjacen