Dual Purkinje imaging with ellipsoidal lensing structure

What is claimed is: 1. A near-eye optical system for a head mounted artificial reality system comprising: an infrared light source configured to emit infrared illumination light; an ellipsoidal combiner configured to redirect the infrared illumination light to an eyebox location and configured to pass scene light to the eyebox location, the ellipsoidal combiner including a near-eye ellipsoidal lensing structure having a first foci and a second foci, wherein the ellipsoidal combiner is configured to be positioned relative to the eyebox location where the first foci of the near-eye ellipsoidal lensing structure is located approximately at a center of rotation of an eye placed in the eyebox location; a beam-steering element configured to selectively direct the infrared illumination light to the ellipsoidal combiner; a camera configured to capture a tracking image of Purkinje reflections of the infrared illumination light, wherein near-eye ellipsoidal lensing structure is configured to direct the Purkinje reflections of the infrared illumination light to the camera; and a beam splitter positioned to receive the Purkinje reflections from the near-eye ellipsoidal lensing structure and redirect the Purkinje reflections to the camera, wherein the infrared illumination light propagates through the beam splitter prior to encountering the near-eye ellipsoidal lensing structure. 2. The near-eye optical system of claim 1 , wherein an image sensor of the camera is disposed in an image capture plane that is conjugate to a pupil of the eye placed in the eyebox location. 3. The near-eye optical system of claim 1 , further comprising a lens for focusing the Purkinje reflections of the infrared illumination light to the camera. 4. The near-eye optical system of claim 1 , further comprising processing logic coupled to the camera to receive the tracking image. 5. The near-eye optical system of claim 4 , wherein the processing logic determines an eye position of the eye based on the tracking image. 6. The near-eye optical system of claim 5 , wherein the processing logic is configured to determine virtual images presented to the eye based on the eye position. 7. The near-eye optical system of claim 4 , wherein the processing logic is configured to select a scan location of the beam steering element based on the tracking image. 8. The near-eye optical system of claim 4 , wherein the processing logic determines a distance between a first Purkinje reflection and a fourth Purkinje reflection in the tracking image. 9. The near-eye optical system of claim 8 , wherein the processing logic updates an eye position based on the distance. 10. A head mounted artificial reality system comprising: a display for presenting virtual images to an eyebox of the head mounted artificial reality system; an infrared light source configured to emit infrared illumination light; an ellipsoidal combiner configured to redirect the infrared illumination light to the eyebox location and configured to pass scene light to the eyebox, the ellipsoidal combiner including a near-eye ellipsoidal lensing structure having a first foci and a second foci, wherein the ellipsoidal combiner is configured to be positioned relative to the eyebox location where the first foci of the near-eye ellipsoidal lensing structure is located at approximately a center of rotation of an eye placed in the eyebox location, and wherein visible display light including the virtual images propagates through the ellipsoidal combiner prior to entering the eyebox; a beam-steering element configured to selectively direct the infrared illumination light to the ellipsoidal combiner; a camera configured to capture a tracking image of Purkinje reflections of the infrared illumination light, wherein near-eye ellipsoidal lensing structure is configured to direct the Purkinje reflections of the infrared illumination light to the camera; and a beam splitter positioned to receive the Purkinje reflections from the near-eye ellipsoidal lensing structure and redirect the Purkinje reflections to the camera, wherein the infrared illumination light propagates through the beam splitter prior to encountering the near-eye ellipsoidal lensing structure. 11. The head mounted artificial reality system of claim 10 further comprising: processing logic configured to determine an eye position of the eye in the eyebox in response to the tracking image. 12. The head mounted artificial reality system of claim 11 , wherein the processing logic is configured to adjust the virtual images presented to the eyebox based on the eye position. 13. The head mounted artificial reality system of claim 10 , wherein the beam-steering element is configured to selectively redirect the infrared illumination light to the ellipsoidal combiner in response to eye-tracking data. 14. The head mounted artificial reality system of claim 10 , further comprising processing logic coupled to the camera to receive the tracking image. 15. The head mounted artificial reality system of claim 14 , wherein the processing logic determines an eye position of the eye based on the tracking image and adjusts virtual images presented to the eyebox based on the eye position. 16. The head mounted artificial reality system of claim 14 , wherein the processing logic adjusts virtual images by selective application of blurring filters to the virtual images. 17. The head mounted artificial reality system of claim 14 , wherein the processing logic determines a distance between a first Purkinje reflection and a fourth Purkinje reflection in the tracking image. 18. The head mounted artificial reality system of claim 17 , wherein the processing logic updates an eye position based on the distance.