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

What is claimed: 1. A method for operating an electronic device that includes an eye tracker and a mixed-reality see-through optical display system for showing scenes comprising virtual images that are rendered over views of real-world objects, the method comprising: calibrating the electronic device for utilization by a presbyopic user; operating the mixed-reality see-through optical display system to support a near field and a far field, the near field being closer to the presbyopic user relative to the far field, and the mixed-reality see-through optical display system having an eye side and a real-world side; operating a conjugate pair of variable-focus lenses in matched configurations to provide for setting rendered virtual images within the near field without perturbing the views of the real-world objects in the far field; using the eye tracker to determine a depth of the presbyopic user's gaze in the scene; and responsively to a depth determination by the eye tracker, operating the conjugate pair of variable-focus lenses in mismatched configurations to enable the presbyopic user to simultaneously accommodate rendered virtual images and real-world objects in the near field. 2. The method of claim 1 in which the variable-focus lenses in the conjugate pair are located on opposite sides of the mixed-reality see-through optical display system, and in which the matched configurations comprise the conjugate pair of variable-focus lenses providing zero net optical power to the views of the real-world objects, and in which the mismatched configurations comprise optical power being added to the variable-focus lens disposed on the real-world side. 3. The method of claim 1 further comprising adding optical power to the variable-focus lens on the eye side to incorporate a corrective prescription of the presbyopic user for distance vision. 4. The method of claim 1 further comprising operatively coupling an optical power controller to the conjugate pair of variable-focus lenses. 5. The method of claim 4 further comprising operating the optical power controller to add optical power to the variable-focus lens on the eye side. 6. The method of claim 4 further comprising operating the optical power controller to add optical power to the variable-focus lens on the real-world side. 7. The method of claim 4 further comprising operatively coupling the eye tracker to the optical power controller, the eye tracker being configured for tracking vergence of the presbyopic user's eyes or tracking a gaze direction of at least one eye of the presbyopic user, in which the optical power controller controls the conjugate pair of variable-focus lenses responsively to operations of the eye tracker. 8. 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 virtual images from a virtual world that are combined with views of real-world objects in a physical world, comprising: an eye tracker; and a mixed-reality see-through optical display system for showing scenes comprising virtual images that are rendered over views of real-world objects, wherein the HMD device is configured for being calibrated for utilization by the presbyopic user; operating the mixed-reality see-through optical display system to support a near field and a far field, the near field being closer to the presbyopic user relative to the far field, and the mixed-reality see-through optical display system having an eye side and a real-world side, operating a conjugate pair of variable-focus lenses in matched configurations to provide for setting rendered virtual images within the near field without perturbing the views of the real-world objects in the far field, using the eye tracker to determine a depth of the presbyopic user's gaze in the scene, and responsively to a depth determination by the eye tracker, operating the conjugate pair of variable-focus lenses in mismatched configurations to enable the presbyopic user to simultaneously accommodate rendered virtual images and real-world objects in the near field. 9. The HMD device of claim 8 in which the variable-focus lenses in the conjugate pair are located on opposite sides of the mixed-reality see-through optical display system, and in which the matched configurations comprise the conjugate pair of variable-focus lenses providing zero net optical power to the views of the real-world objects, and in which the mismatched configurations comprise optical power being added to the variable-focus lens disposed on the real-world side. 10. The HMD device of claim 8 further comprising adding optical power to the variable-focus lens on the eye side to incorporate a corrective prescription of the presbyopic user for distance vision. 11. The HMD device of claim 8 further comprising operatively coupling an optical power controller to the conjugate pair of variable-focus lenses. 12. The HMD device of claim 8 further comprising operating the optical power controller to add optical power to the variable-focus lens on the eye side. 13. The HMD device of claim 11 further comprising operating the optical power controller to add optical power to the variable-focus lens on the real-world side. 14. A mixed-reality display system that is utilizable by a presbyopic user, the mixed-reality display system being operated to implement a method, comprising: calibrating the mixed-reality display system for utilization by a presbyopic user, in which the mixed-reality display system is configured for showing scenes comprising virtual images that are rendered over views of real-world objects; operating the mixed-reality display system to support a near field and a far field, the near field being closer to the presbyopic user relative to the far field, and the mixed-reality display system having an eye side and a real-world side; operating a conjugate pair of variable-focus lenses in matched configurations to provide for setting rendered virtual images within the near field without perturbing the views of the real-world objects in the far field; using an eye tracker to determine a depth of the presbyopic user's gaze in the scene; and responsively to a depth determination by the eye tracker, operating the conjugate pair of variable-focus lenses in mismatched configurations to enable the presbyopic user to simultaneously accommodate rendered virtual images and real-world objects in the near field. 15. The mixed-reality display system of claim 14 in which variable-focus lenses in the conjugate pair are located on opposite sides of the mixed-reality see-through optical display system, and in which the matched configurations comprise the conjugate pair of variable-focus lenses providing zero net optical power to the views of the real-world objects, and in which the mismatched configurations comprise optical power being added to the variable-focus lens disposed on the real-world side. 16. The mixed-reality display system of claim 14 further comprising adding optical power to the variable-focus lens on the eye side to incorporate a corrective prescription of the presbyopic user for distance vision. 17. The mixed-reality display system of claim 14 further comprising operatively coupling an optical power controller to the conjugate pair of variable-focus lenses. 18. The mixed-reality display system of claim 17 further comprising operating the optical power controller to add optical power to the variable-focus lens on the eye side. 19. The mixed-reality disp