Illumination assembly for 3D data acquisition

What is claimed is: 1. An illumination assembly operable to generate a patterned illumination that maintains high contrast over a wide temperature range, the illumination assembly comprising: an array of monochromatic light sources positioned on an illumination plane, wherein each monochromatic light source is characterized by a numerical aperture and a chief ray and the illumination plane is characterized by a first diameter; a first optical element having a first aspheric optical surface separated from the array of monochromatic light sources by a first separation and the first optical element having a second aspheric optical surface juxtaposed from the first aspheric optical surface by a first thickness, wherein the first optical element comprises an optical polymer, and wherein the first aspheric optical surface is a convex object-side surface characterized by a second diameter and the second aspheric optical surface is a concave image-side surface characterized by a third diameter; and a second optical element having a third aspheric optical surface separated from the second aspheric optical surface by a second separation and the second optical element having a fourth aspheric optical surface juxtaposed from the third aspheric optical surface by a second thickness, wherein the third aspheric optical surface is a convex object-side surface characterized by a fourth diameter and the fourth aspheric optical surface is a convex image-side surface characterized by a fifth diameter; wherein the array of monochromatic light sources, first and second optical elements define an optical axis substantially parallel to the chief ray of each light source, an on-axis focal length, an aspect ratio defined as a largest of first, second, third, fourth and fifth diameters divided by a sum of first separation, first thickness, second separation and second thickness, the aspect ratio having a value of at least 0.77, and an exit aperture wherein the chief ray of each light source substantially converges, the exit aperture having a sixth diameter and being separated from the fourth aspheric optical surface by a third separation; and wherein the on-axis focal length is a focal length of light rays which propagate along the optical axis and which pass through the first and second optical elements. 2. The illumination assembly of claim 1 , further comprising a focal-length correction layer, the focal-length correction layer having a first focal-length correction layer surface separated from the array of monochromatic light sources by a fourth separation and the focal-length correction layer having a second focal-length correction surface juxtaposed from the first focal-length correction layer surface by a third thickness, wherein the first focal-length correction layer surface is a planar object-side surface and the second focal-length correction layer surface is a planar image-side surface both surfaces being parallel, substantially orthogonal to the optical axis, and characterized by a seventh diameter. 3. The illumination assembly of claim 2 , wherein the ratio of the first diameter to the on-axis focal length is 1.91:1, the ratio of the second diameter to the on-axis focal length is 2.13:1, the ratio of the third diameter to the on-axis focal length is 1.89:1, the ratio of the fourth diameter to the on-axis focal length is 1.80:1, the ratio of the ratio of the fifth diameter to the on-axis focal length is 1.44:1, the ratio of the sixth diameter to the on-axis focal length is 1.01:1, the ratio of the seventh diameter to the on-axis focal length is 2.16:1, the ratio of the first separation to the on-axis focal length is 0.57:1, the ratio of the second separation to the on-axis focal length is 0.21:1, the ratio of the third separation to the on-axis focal length is 0.39:1, the ratio of the fourth separation to the on-axis focal length is 0.26:1, the ratio of the first thickness to the on-axis focal length is 0.88:1, the ratio of the second thickness to the on-axis focal length is 0.73:1, the ratio of the third thickness to the on-axis focal length is 0.24:1. 4. The illumination assembly of claim 2 , wherein the on-axis focal length is 0.89 mm, the first separation is 0.50 mm, the second separation is 0.19 mm, the third separation is 0.35 mm, the fourth separation is 0.23 mm, the first thickness is 0.79 mm, the second thickness is 0.65 mm, the third thickness is 0.21 mm, the first diameter is1.7 mm, the second diameter is 1.9 mm, the third diameter is 1.68 mm, the fourth diameter is 1.6 mm, the fifth diameter is 1.28 mm, the sixth diameter is 0.9 mm, the seventh diameter is 1.92 mm, the focal-length correction layer is comprised of D263T, the first optical element is comprised of OKP-1, the second optical element is comprised of M-BACD 12 . 5. The illumination assembly of claim 2 , wherein the focal-length correction layer comprises an optical glass. 6. The illumination assembly of claim 2 , wherein the focal-length correction layer comprises an optical glass and a photoresist material. 7. The illumination assembly of claim 1 , wherein the ratio of the sixth diameter to the on-axis focal length is no greater than 1.01:1. 8. The illumination assembly of claim 1 , wherein the ratio of the sixth diameter to the first diameter is no greater than 0.53:1. 9. The illumination assembly of claim 1 , wherein the ratio of the sixth diameter to the smallest of second, third, fourth and fifth diameters is no greater than 0.70:1. 10. The illumination assembly of claim 1 , wherein the ratio of the sixth diameter to the sum of the first separation, first thickness, second separation and second thickness is no greater than 0.36:1. 11. The illumination assembly of claim 1 , wherein the ratio of the first diameter to the on-axis focal length is 1.91:1, the ratio of the second diameter to the on-axis focal length is 2.13:1, the ratio of the third diameter to the on-axis focal length is 1.89:1, the ratio of the fourth diameter to the on-axis focal length is 1.80:1, the ratio of the ratio of the fifth diameter to the on-axis focal length is 1.44:1, the ratio of the first separation to the on-axis focal length is 0.57:1, the ratio of the second separation to the on-axis focal length is 0.21:1, the ratio of the third separation to the on-axis focal length is 0.39:1, the ratio of the first thickness to the on-axis focal length is 0.88:1, the ratio of the second thickness to the on-axis focal length is 0.73:1. 12. The illumination assembly of claim 1 , wherein each monochromatic light source of the array of monochromatic light sources comprises a vertical-cavity surface-emitting laser. 13. The illumination assembly of claim 1 , wherein the array of monochromatic light sources comprises a backlit mask having portions of the mask defining an array of holes therethrough. 14. The illumination assembly of claim 1 , wherein the on-axis focal length is 0.89 mm, the first separation is 0.50 mm, the second separation is 0.19 mm, the third separation is 0.35 mm, the first thickness is 0.79 mm, the second thickness is 0.65 mm, the first diameter is 1.7 mm, the second diameter is 1.9 mm, the third diameter is 1.68 mm, the fourth diameter is 1.6 mm, the fifth diameter is 1.28 mm, the sixth diameter is 0.9 mm, the first optical element is comprised of OKP-1, the second optical element is comprised of M-BACD 12 . 15. The illumination assembly of claim 14 , wherein the first, second, third, and fourth aspheric surfaces can be described by the radiuses of curvature 0.41, 0 . 80 , 0 . 97 , - 1 . 39 , respectively, the conic constants (K) - 0 . 85 , - 1 , - 4 . 39 , and - 12 , respectively, and by