Eye tracking apparatus, method and system

What is claimed is: 1. An apparatus for use in tracking an eye that is illuminated by infrared light, the apparatus comprising: a waveguide that is transparent and includes an input-coupler and an output-coupler that are spatially separated from one another; and a light source adapted to illuminate an eye with infrared light so that at least a portion of the infrared light is reflected from the eye and is incident on the input-coupler; wherein the input-coupler comprises a plurality of curved grating lines that are configured to diffract infrared light beams incident on the input-coupler into the waveguide and towards a common region at which is located the output-coupler by way of total internal reflections; wherein the plurality of curved grating lines of the input-coupler have a radially varying pitch that decreases with increases in distances between the curved grating lines and the output-coupler; wherein the plurality of curved grating lines of the input-coupler each have a respective center of curvature and a respective point of convergence that are located within the region of the waveguide at which is located the output-coupler; and wherein the radially varying pitch of the plurality of curved grating lines of the input-coupler are configured to cause different infrared light beams that are incident on different horizontal and vertical positions of the input-coupler to propagate through the waveguide at respective different angles of reflection and exit the waveguide at respective different angles of incidence relative to a surface of the waveguide through which the infrared light beams exit. 2. The apparatus of claim 1 , wherein for each point on each of the plurality of curved grating lines of the input-coupler the respective center of curvature is within the region of the waveguide at which is located the output-coupler. 3. The apparatus of claim 1 , wherein the input-coupler is configured to cause ray bundles of infrared light reflected from a same field point on the eye that enter the waveguide through the input-coupler to become collimated inside of the waveguide and exit the waveguide with a same angle of incidence relative to a surface of the waveguide through which the infrared light exits, when the input-coupler is at a nominal eye relief distance, which is a focal distance of the input-coupler. 4. The apparatus of claim 1 , wherein the input-coupler is configured to cause ray bundles of infrared light reflected from different field points on the eye to propagate through the waveguide at respective different angles of reflection and exit the waveguide with respective different angles of incidence relative to a surface of the waveguide through which the infrared light exits to thereby provide for angular encoding of infrared light that is reflected off different field points on the eye, when the input-coupler is at a nominal eye relief distance, which is a focal distance of the input-coupler. 5. The apparatus of claim 1 , wherein when the input-coupler is positioned in front of an eye that is illuminated with infrared light, infrared light beams reflected from the eye and incident on the input-coupler enter the waveguide at the input-coupler, propagate through the waveguide from the input-coupler to the output-coupler by way of total internal reflections, and exit the waveguide proximate the output-coupler. 6. The apparatus of claim 1 , wherein: the radially varying pitch of the curved grating lines of the input-coupler varies within a range that is between about 500 nm and 1000 nm, with the radially varying pitch being greatest closest to the output coupler and decreasing with increases in distances between the curved grating lines and the output-coupler. 7. The apparatus of claim 1 , wherein the input-coupler and the output-coupler are positioned relative to one another to substantially achieve telecentricity. 8. The apparatus of claim 1 , wherein the plurality of curved grating lines of the input-coupler are substantially concentric, each have substantially the same center of curvature that is located within the region of the waveguide at which is located the output-coupler, and each have substantially the same point of convergence that is located within the region of the waveguide at which is located the output-coupler. 9. The apparatus of claim 1 , wherein the center of curvature and the point of convergence for each of the plurality of curved grating lines of the input-coupler are the same point, which is located at or near a center of the output-coupler. 10. The apparatus of claim 1 , wherein an optical transfer function of the input-coupler is substantially equivalent to an optical transfer function of an on-axis holographic lens combined with an optical transfer function of a linear diffraction grating. 11. A method for use in tracking an eye, the method comprising: illuminating an eye with infrared light while an input-coupler of a waveguide is generally axially aligned with the eye, which will result in infrared light beams reflected from the eye being incident on the input-coupler of the waveguide; diffracting the infrared light beams that are incident on the input-coupler of the waveguide towards a common region of the waveguide at which is located an output-coupler that is spatially separated from the input-coupler, the diffracting performed using curved grating lines of the input-coupler, wherein the curved grating lines of the input-coupler each have a respective center of curvature and a respective point of convergence that are located within a region of the waveguide at which is located the output-coupler; using the output-coupler of the waveguide, causing the infrared light beams to exit the waveguide; and causing ray bundles of the infrared light beams reflected from different field points on the eye to propagate through the waveguide at respective different angles of reflection and exit the waveguide with respective different angles of incidence relative to a surface of the waveguide through which the infrared light exits. 12. The method of claim 11 , further comprising: angularly encoding the infrared light beams that are reflected from the eye by causing ray bundles of infrared light reflected from a same field point on the eye that enter the waveguide through the input-coupler to become collimated inside of the waveguide and exit the waveguide with a same angle of incidence relative to a surface of the waveguide through which the infrared light exits. 13. The method of claim 11 , further comprising: converting the infrared light beams that exit the waveguide from angularly encoded infrared light beams to two-dimensional spatially encoded infrared light beams. 14. The method of claim 13 , further comprising: generating, in dependence on the two-dimensional spatially encoded infrared light beams, eye tracking data that can be used to track the eye; and at least one of controlling or modifying an aspect of an application based on the eye tracking data. 15. The method of claim 11 , further comprising: using the radially varying pitch of the plurality of curved grating lines of the input-coupler to cause different infrared light beams that are incident on different horizontal and vertical positions of the input-coupler to propagate through the waveguide at respective different angles of reflection and exit the waveguide at respective different angles of incidence relative to a surface of the waveguide through which the infrared light beams exit. 16. A system for use in tracking an eye, comprising: a waveguide that is transparent and includes an input-c