Wide-angle depth imaging lens construction

The invention claimed is: 1. A wide-angle lens construction comprising: a first, negative stage configured to collect light and direct rays into diverging bundles, the first, negative stage comprising a first negative lens element, the first negative lens element being an initial negative lens element in the lens construction and comprising an aspheric convex front portion and an aspheric concave rear portion; and a second, positive stage positioned behind the first, negative stage along an optical axis of the lens construction, the second, positive stage comprising: a first positive lens substage; a second positive lens substage a third positive lens substage the second positive lens substage positioned between the first positive lens substage and the third positive lens substage, and a negative lens substage positioned between the first positive lens substage and the second positive lens substage, the negative lens substage comprising a convex front portion facing the first positive lens substage and a concave rear portion facing the second positive lens substage. 2. The wide-angle lens construction of claim 1 , wherein the negative lens substage further comprises an aspheric convex front surface and an aspheric concave rear surface. 3. The wide-angle lens construction of claim 1 , wherein each lens substage comprises one or more lens elements. 4. The wide-angle lens construction of claim 3 , wherein the one or more lens elements comprises a lens element with an aspheric lens surface. 5. The wide-angle lens construction of claim 1 , further comprising a band-pass filter positioned at a rear of the third positive lens substage, and a depth image sensor positioned at a rear of the band-pass filter. 6. The wide-angle lens construction of claim 1 , wherein the second positive lens substage and the third positive lens substage are configured to make the lens construction image-space telecentric. 7. The wide-angle lens construction of claim 1 , wherein an aperture stop is positioned between the first, negative stage and the second, positive stage. 8. The wide-angle lens construction of claim 1 , wherein the first positive lens substage includes a stronger positive lens element than each remaining lens element of the lens construction. 9. The wide-angle lens construction of claim 1 , wherein the lens construction comprises an f-number equal to or less than 1.0 and a field of view equal to or greater than 90 degrees. 10. A wide-angle, high speed infrared camera device comprising: a lens construction comprising: a first, negative stage, comprising a first negative lens element; a second, positive stage, comprising, in order along an optical axis: a first positive lens element, a second negative lens element comprising a front convex portion and a rear concave portion, a second positive lens element comprising a front concave surface facing the second negative lens element and a rear convex surface opposite the front concave surface, and a third positive lens element; a filter element positioned after the third positive lens element; and a sensor positioned after the filter element. 11. The wide-angle, high speed infrared camera device of claim 10 , wherein the second negative lens element comprises an aspheric front concave lens surface and an aspheric rear convex lens surface. 12. The wide-angle, high speed infrared camera device of claim 10 , wherein the filter element comprises an infrared band-pass filter, and the sensor comprises a depth image sensor. 13. The wide-angle, high speed infrared camera device of claim 10 , wherein the second positive lens element and the third positive lens element are configured to make the lens construction image-space telecentric. 14. The wide-angle, high speed infrared camera device of claim 10 , wherein an aperture stop is positioned between the first, negative stage and the second, positive stage. 15. The wide-angle, high speed infrared camera device of claim 10 , wherein the first positive lens element is a stronger positive lens element than each remaining lens element of the lens construction. 16. The wide-angle, high speed infrared camera device of claim 10 , wherein the lens construction comprises an f-number equal to or less than 1.0, and a field of view (FoV) equal to or greater than 90 degrees. 17. A method of collecting light with an infrared camera device comprising a first, negative lens stage comprising a first negative lens element and a second, positive lens stage comprising a first positive lens element, a second negative lens element, a second positive lens element, and a third positive lens element, the method comprising: via the first, negative lens stage, collecting light rays from a light source, bending the light rays to decrease angles between the rays and an optical axis, and diverging the light rays into diverging ray bundles; and via the second, positive lens stage collecting the diverging ray bundles and focusing the diverging bundles into converging ray bundles via the first positive lens element, decreasing the convergence of the converging ray bundles and bending chief rays to increase chief ray angles via the second negative lens element comprising a front aspheric convex portion and a rear aspheric concave portion, and reducing an angle between the chief rays and the optical axis and focusing the ray bundles to tight spots on a sensor element via the second positive lens element and the third positive lens element. 18. The method of claim 17 , further comprising, with a filter element, filtering the ray bundles from the third positive lens element to remove visible light, and passing infrared light through to the sensor element. 19. The method of claim 18 , wherein the infrared camera device comprises an f-number less than or equal to 1.0 and a field of view (FoV) greater than or equal to 90 degrees. 20. The method of claim 17 , further comprising controlling light collection at the second, positive lens stage with an aperture stop positioned between the first, negative lens stage and the second, positive lens stage.