Angular light sensor and eye-tracking

What is claimed is: 1. An eye-tracking system comprising: a plurality of infrared light sources configured to emit infrared illumination light to an eyebox region; and a plurality of angular light sensors configured to receive returning infrared light that is the infrared illumination light reflecting from the eyebox region, wherein the angular light sensors in the plurality are configured to output angular signals representing an angle of incidence of the returning infrared light with respect to positions of the angular light sensors, wherein each infrared light source is paired with an angular light sensor and separated by less than 500 microns. 2. The eye-tracking system of claim 1 , wherein the angular light sensors have an angular detection range between 1 degree and 85 degrees with respect to a photodetector surface of the angular light sensors. 3. The eye-tracking system of claim 1 , wherein the angular light sensors have a sensor area of less than 150 microns×150 microns. 4. The eye-tracking system of claim 1 , wherein the angular light sensors include: a first photodiode configured to receive the returning infrared light; a second photodiode configured to receive the returning infrared light; and a tilted light barrier disposed between the first photodiode and the second photodiode, the tilted light barrier being angled with respect to a surface-normal of a sensing plane common to both the first photodiode and the second photodiode, wherein a ratio of a first signal generated by the first photodiode and a second signal generated by the second photodiode indicates the angle of incidence of the returning infrared light. 5. The eye-tracking system of claim 1 , wherein the angular light sensors include: a light barrier; a first photodiode configured to receive the returning infrared light; a second photodiode configured to receive the returning infrared light, wherein the first photodiode is disposed between the light barrier and the second photodiode; and processing logic configured to receive a first signal generated by the first photodiode and a second signal generated by the second photodiode, wherein the processing logic generates a Center of Mass value based on the first signal and the second signal, wherein the first signal is assigned a first weighting factor that is less a second weighting factor assigned to the second signal in generating the Center of Mass value. 6. The eye-tracking system of claim 1 , wherein a field of view (FOV) of an angular detection range of the angular light sensors is tilted with respect to a surface-normal of photodetectors of the angular light sensors. 7. The eye-tracking system of claim 1 further comprising: a tilting mechanism configured to dynamically tilt a field of view (FOV) of an angular detection range of the angular light sensors. 8. The eye-tracking system of claim 7 , wherein the tilting mechanism includes a micro-electro-mechanical system (MEMS) device. 9. A head mounted device comprising: a frame for securing the head mounted device on a head of a user; and an eye-tracking system including: a plurality of infrared light sources configured to emit infrared illumination light to an eyebox region; and a plurality of angular light sensors configured to receive returning infrared light that is the infrared illumination light reflecting from the eyebox region, wherein the angular light sensors in the plurality are configured to output angular signals representing an angle of incidence of the returning infrared light with respect to positions of the angular light sensors, wherein the angular light sensors include: a first photodiode configured to receive the returning infrared light; a second photodiode configured to receive the returning infrared light; and a tilted light barrier disposed between the first photodiode and the second photodiode, the tilted light barrier being angled with respect to a surface-normal of a sensing plane common to both the first photodiode and the second photodiode, wherein a ratio of a first signal generated by the first photodiode and a second signal generated by the second photodiode indicates the angle of incidence of the returning infrared light. 10. The head mounted device of claim 9 , wherein the plurality of infrared light sources and the plurality of angular light sensors are mounted to the frame of the head mounted device. 11. The head mounted device of claim 9 further comprising: a lens held by the frame, wherein the lens passes visible scene light from an external environment to the eyebox region, and wherein the plurality of infrared light sources and the plurality of angular light sensors are disposed on the lens. 12. An angular light sensor comprising: a first light detector including a first photodiode, a first high-grating, and a first low-grating, wherein the first low-grating is disposed between the first high-grating and the first photodiode; and a second light detector including a second photodiode, a second high-grating, and a second low-grating, wherein the second low-grating is disposed between the second high-grating and the second photodiode, wherein the second low-grating is decentered with respect to the second high-grating, and wherein the first low-grating is centered with respect to the first high-grating; a third light detector including a third photodiode, a third high-grating, and a third low-grating, wherein the third low-grating is disposed between the third high-grating and the third photodiode; a fourth light detector configured as the first light detector; a fifth light detector configured as the second light detector; and a sixth light detector configured as the third light detector, wherein the fourth light detector, the fifth light detector, and the sixth light detector are rotated 90 degrees with respect to the first light detector, the second light detector, and the third light detector. 13. The angular light sensor of claim 12 , wherein the second low-grating is decentered with respect to the second high-grating by a shifting factor of d/4, where d is the pitch of the second high-grating, the second low-grating, the first low-grating, and the first high-grating. 14. The angular light sensor of claim 13 , wherein the pitch has a 50% duty cycle. 15. The angular light sensor of claim 12 , wherein a grating material is chromium or copper for the second high-grating, the second low-grating, the first low-grating, and the first high-grating. 16. The angular light sensor of claim 12 , wherein the angular light sensor is configured to measure an angle of incidence of light having a wavelength λ, and wherein the first low-grating is spaced from first high-grating by distance z, where z is 2d 2 /λ, where d is the pitch of the second high-grating, the second low-grating, the first low-grating, and the first high-grating, and further wherein the second low-grating is also spaced from second high-grating by the distance z. 17. The angular light sensor of claim 12 , wherein an optically transparent substrate is disposed between the first high-grating and the first low-grating, and wherein the optically transparent substrate is also disposed between the second high-grating and the second low-grating. 18. The angular light sensor of claim 12 , wherein the third low-grating is decentered with respect to the third high-grating by a shifting factor of 3d/8, where d is the pitch of the third high-grating and the third low-grating.