Optical system using segmented phase profile liquid crystal lenses

What is claimed is: 1. A system, comprising: an electronic display configured to display a virtual image; an eye tracking device including a sensor configured to obtain eye tracking information for determining a vergence of a user; an adaptive lens assembly optically coupled to the electronic display, the adaptive lens assembly comprising a plurality of adjustable liquid crystal (LC) lenses arranged in an array; and a controller configured to: selectively activate one or more of the plurality of adjustable LC lenses to adjust a focal length of the adaptive lens assembly to reduce a determined discrepancy between the vergence and an accommodation associated with the vergence; determine a lens center shift between a center of the selectively activated one or more of the plurality of adjustable LC lenses and a center of the adaptive lens assembly; and determine an image shift based on the lens center shift, wherein the electronic display is configured to shift the virtual image by the image shift. 2. The system according to claim 1 , wherein at least one of the adjustable LC lenses includes a plurality of segmented phase profile (SPP) LC lenses stacked together, and the adaptive lens assembly includes layers of array of SPP LC lenses. 3. The system according to claim 2 , wherein at least one of the SPP LC lenses is a refractive Fresnel LC lens including a plurality of concentric ring-shaped Fresnel segments of increasing radii. 4. The system according to claim 2 , wherein: at least one of the SPP LC lenses includes a plurality of ring-shaped electrodes corresponding to the concentric ring-shaped Fresnel segments, the ring-shaped electrodes are concentric with an identical area, a phase difference between adjacent electrodes is the same, and a phase profile of the at least one of the SPP LC lenses is a parabolic phase profile. 5. The system according to claim 4 , wherein: the at least one of the plurality of SPP LC lenses further includes a plurality of floating electrodes which are discrete and concentric ring-shaped electrodes; and the floating electrodes are capacitively coupled to the ring-shaped electrodes by an insulating layer, and at least one of the floating electrodes covers a portion of each of the neighboring ring-shaped electrodes. 6. The system according to claim 4 , wherein: within a same layer of array of SPP LC lenses, the plurality of SPP LC lenses are arranged in both of a horizontal direction and a vertical direction; and the ring-shaped electrodes of neighboring SPP LC lenses overlap with each other. 7. The system according to claim 4 , wherein: the ring-shaped electrodes of neighboring SPP LC lenses are arranged in a non-overlapping configuration, and an electric field of an area between the neighboring SPP LC lenses is adjustable to preserve the phase profile of at least one of the neighboring SPP LC lenses. 8. The system according to claim 4 , wherein: the ring-shaped electrodes of neighboring SPP LC lenses are arranged in a non-overlapping configuration, and the adaptive lens assembly further includes a second-level SPP LC lens disposed in an area between the neighboring SPP LC lenses. 9. The system according to claim 2 , wherein: the plurality of SPP LC lenses include two SPP LC lenses stacked together, with a same configuration and opposite alignment directions. 10. The system according to claim 2 , wherein the controller is configured to: determine, based on the vergence information, the one or more of the plurality of adjustable LC lenses to be selectively activated; determine a number of the plurality of SPP LC lenses within the one or more of the plurality of adjustable LC lenses to provide a predetermined optical power of the one or more of the plurality of adjustable LC lenses; and activate the number of the plurality of SPP LC lenses. 11. The system according to claim 10 , wherein, to determine the one or more of the plurality of adjustable LC lenses to be selectively activated, the controller is further configured to: determine gaze lines of the user; and determine, among the plurality of the adjustable LC lenses from the array, one or more of the plurality of adjustable LC lenses intersecting with the gaze lines as the one or more of the plurality of adjustable LC lenses to be selectively activated. 12. The system according to claim 10 , wherein the lens center shift and the image shift are along directions parallel to the electronic display. 13. A varifocal system, comprising: an eye tracking device including a sensor configured to obtain eye tracking information for determining a vergence of a user; and a varifocal block including an adaptive lens assembly having a plurality of adjustable liquid crystal (LC) lenses arranged in an array, wherein the varifocal block is configured to: selectively activate one or more of the plurality of adjustable LC lenses to adjust a focal length of the varifocal block to reduce a determined discrepancy between the vergence and an accommodation associated with the vergence; determine a lens center shift between a center of the selectively activated one or more of the plurality of adjustable LC lenses and a center of the adaptive lens assembly; determine an image shift based on the lens center shift; and cause an electronic display to shift a virtual image displayed thereon by the image shift. 14. The varifocal system according to claim 13 , wherein at least one of the adjustable LC lenses includes a plurality of segmented phase profile (SPP) LC lenses stacked together, and the varifocal block includes layers of array of SPP LC lenses. 15. The varifocal system according to claim 14 , wherein: the plurality of SPP LC lenses include two SPP LC lenses stacked together, with a same configuration and opposite alignment directions. 16. The varifocal system according to claim 14 , wherein at least one of the SPP LC lenses is a refractive Fresnel LC lens including a plurality of concentric ring-shaped Fresnel segments of increasing radii. 17. The varifocal system according to claim 16 , wherein: the at least one of the SPP LC lenses includes a plurality of ring-shaped electrodes corresponding to the concentric ring-shaped Fresnel segments, the ring-shaped electrodes are concentric with an identical area, a phase difference between adjacent electrodes is the same, and a phase profile of the at least one of the SPP LC lenses is a parabolic phase profile. 18. The varifocal system according to claim 17 , wherein: the at least one of the SPP LC lenses further includes a plurality of floating electrodes which are discrete and concentric ring-shaped electrodes; and the floating electrodes are capacitively coupled to the ring-shaped electrodes by an insulating layer, and at least one of the floating electrodes covers a portion of each of neighboring ring-shaped electrodes. 19. The varifocal system according to claim 17 , wherein: within a same layer of array of SPP LC lenses, the plurality of SPP LC lenses are arranged in both of a horizontal direction and a vertical direction; and the ring-shaped electrodes of neighboring SPP LC lenses overlap with each other. 20. The varifocal system according to claim 17 , wherein: the ring-shaped electrodes of neighboring SPP LC lenses are arranged in a non-overlapping configuration, and the varifocal block further includes a second-level SPP LC lens disposed in an area between the neighboring SPP LC lenses.