Control of variable-focus lenses in a mixed-reality device for presbyopes

The invention claimed is: 1 . A mixed-reality display system that is utilizable by a presbyopic user, comprising: a see-through optical combiner through which real-world objects are viewable by the user, the see-through optical combiner being adapted to display virtual-world images that are superimposed over the real-world objects over an eyebox of the display system, the see-through optical combiner having an eye-side and a real-world side; a first variable-focus lens disposed on the eye-side of the see-through optical combiner; a second variable-focus lens disposed on the real-world side of the see-through optical combiner; an optical power controller operatively coupled to the first and second variable-focus lenses, in which the optical power controller controls a baseline configuration for each of the first and second variable-focus lenses; and an eye tracker operatively coupled to the optical power controller, the eye tracker tracking vergence of the presbyopic user’s eyes or tracking a gaze direction of at least one eye of the presbyopic user to determine whether the presbyopic user is accommodating to a predetermined distance, in which the optical power controller controls the variable-focus positive lens responsively to operations of the eye tracker, wherein the optical power controller is adapted to add positive optical power to the baseline configuration of the second variable-focus lens responsive to the determination that the presbyopic user is accommodating to the predetermined distance or less than the predetermined distance. 2 . The mixed-reality display system of claim 1 in which the baseline configuration for the first variable-focus lens provides negative optical power over the eyebox to display the virtual-world images in a focal plane at a predetermined distance from the user, and the baseline configuration of the second variable-focus lens provides positive optical power to offset the negative power of the first variable-focus lens. 3 . The mixed-reality display system of claim 2 in which the baseline configuration for the first variable-focus lens comprises negative optical power having of a range between -0.20 and -3.0 diopters. 4 . The mixed-reality display system of claim 2 in which the baseline configuration for the second variable-focus lens includes optical power comprising a positive conjugate of the negative optical power of the baseline configuration of the first variable-focus lens. 5 . The mixed-reality display system of claim 1 in which each of the variable-focus lenses comprises technologies using one or more of liquid oil push/pull, liquid crystal, reflective MEMS (micro-electromechanical system), MEMS Fresnel structures, geometric phase holograms, meta-surface optical elements, deformable membranes, Alvarez lenses, or multi-order DOEs (diffractive optical elements). 6 . The mixed-reality display system of claim 1 as configured for use in a head-mounted display (HMD) device wearable by the presbyopic user. 7 . A head-mounted display (HMD) device wearable by a presbyopic user and configured for supporting a mixed-reality experience including viewing, by the presbyopic user, of holographic images from a virtual world that are combined with views of real-world objects in a physical world, comprising: a see-through display system through which the presbyopic user can view the real-world objects and on which the holographic images are displayed within a field of view (FOV) of the see-through display system; a negative lens disposed between the see-through display system and an eye of the presbyopic user, the negative lens acting over the FOV and configured to render the holographic images at a focal plane having a predetermined distance from the presbyopic user; a variable-focus positive lens disposed on an opposite side of the see-through display system from the negative lens, the variable-focus positive lens being controllably configured to cancel effects of the negative lens on the views of the real-world objects responsive to the presbyopic user being engaged in viewing beyond the predetermined distance, and the variable-focus positive lens being controllably configured with increased optical power to optically push real-world objects into sharp focus responsive to a determination that the presbyopic user is accommodating within the predetermined distance; an optical power controller operatively coupled to the variable-focus positive lens; and an eye tracker operatively coupled to the optical power controller, the eye tracker tracking vergence of the presbyopic user’s eyes or tracking a gaze direction of at least one eye of the presbyopic user to determine whether the presbyopic user is accommodating within the predetermined distance, in which the optical power controller controls the variable-focus positive lens responsively to operations of the eye tracker. 8 . The HMD device of claim 7 further comprising one or more illumination sources for producing glints for the eye tracker. 9 . The HMD device of claim 8 further comprising one or more sensors configured to captrue glints from the illumination sources that are reflected from features of an eye of the user for eye tracking. 10 . The HMD device of claim 7 in which the the negative lense comprises a variable-focus lens that is operatively coupled to the optical power controller. 11 . The HMD device of claim 10 in which the the optical power controller is configured to control the negative lens to include a corrective lense prescription for an eye of the presbyopic user. 12 . The HMD device of claim 11 in which the corrective lense prescription provides correction for myopia. 13 . The HMD device of claim 7 in which the see-through display system comprises one or more waveguides that each include an input coupler and an output coupler, in which the input coupler is configured to in-couple one or more optical beams for the holographic images into the waveguide from a virtual image source and the output coupler is configured to out-couple the holgoraphic image beams from the waveguide to an eye of the presbyopic user, in which holographic images associated with the out-coupled beams are rendered with the FOV of the display system. 14 . The HMD device of claim 13 in which the input coupler and output coupler each comprise a diffractive optical element (DOE) and in which each of the one or more display sstem waveguides further comprise an intermediate DOE disposed on a light path between the input coupler and the output coupler, wherein the intermediate DOE provides exit pupil exansion of the display syhstem in a first direction and the output coupler provides exit pupil expansion of the display system in a secon direction. 15 . The HMD device of claim 7 in which the predetermined depth is within arm’s length of the presbyopic user.