Near focus corrective ar glasses

1 . A head-mounted display, comprising: an eye rim section having an aperture, wherein a real-world object within an ambient environment is viewable through the aperture; an image light guide arranged within the aperture, the image light guide including: a transmissive planar waveguide having plane-parallel inner and outer surfaces, an in-coupling optic operable to direct angularly related image-bearing light beams encoding a virtual object into the waveguide from an image source, wherein the image-bearing light beams propagate by total internal reflection, and an out-coupling optic operable to direct the propagating image-bearing light beams from the waveguide toward an eyebox, wherein the virtual object is viewed at a first focusing distance from the eyebox; a multifunction optic located within the aperture between the inner surface of the waveguide and the eyebox, wherein the multifunction optic is formed as a single optical element operable to provide: (a) a negative optical power contribution operable to diverge the image-bearing light beams in advance of the eyebox, wherein the virtual object is operable to be viewed at a second focusing distance from the eyebox and the second focusing distance is closer than the first focusing distance, and (b) a corrective optical contribution operable to reduce optical aberrations associated with viewing both the real-world object and the virtual object at the second focusing distance; and a positive-power optic located within the aperture between the outer surface of the waveguide and the ambient environment, wherein the positive-power optic is operable to compensate for the negative optical power contribution of the multifunction optic without compensating for the corrective optical contribution of the multifunction optic, wherein the real-world object is viewed at its actual distance from the eyebox with corrected vision. 2 . The head-mounted display of claim 1 wherein, the multifunction optic is a single refractive lens element. 3 . The head-mounted display of claim 1 wherein, the first focusing distance is a hyperfocal to near infinite distance and the closer second focusing distance is less than the hyperfocal distance. 4 . The head-mounted display of claim 3 wherein, the closer second focusing distance is between 1.5 meters and 4 meters. 5 . The head-mounted display of claim 3 wherein, the closer second focusing distance is between 0.05 meters and 1.5 meters. 6 . The head-mounted display of claim 3 wherein, the corrective optical contribution is set for reducing the optical aberrations at the closer second focusing distance. 7 . The head-mounted display of claim 1 wherein, the multifunction optic is a first of a plurality of multifunction optics, and the first multifunction optic is removable and replaceable with a second of the multifunction optics to adapt the display to a different optical prescription. 8 . The head-mounted display of claim 1 wherein, the multifunction optic is a first of a plurality of multifunction optics, the positive-power optic is a first of a plurality of positive-power optics, and the first multifunction optic and the first positive-power optic are collectively removable and replaceable with a second of the multifunction optics and a second of the positive-power optics for changing the closer second focusing distance to a different third focusing distance. 9 . The head-mounted display of claim 8 wherein, the second multifunction optic provides a corrective optical contribution to reduce the optical aberrations at the different third focusing distance. 10 . The head-mounted display of claim 1 , further comprising a transmissive protective outer cover located within the aperture between the positive-power optic and the ambient environment. 11 . The head-mounted display of claim 1 wherein, the positive-power optic is a lens having a convex outer surface facing the ambient environment and is treated with a protective coating. 12 . An augmented reality virtual image display system for managing a viewer's view of a virtual object and a real-world object within a common field of view, comprising: an image light guide including inner and outer surfaces, wherein the image light guide is operable to direct angularly related image-bearing light beams encoding the virtual object toward an eyebox, wherein the virtual object is viewed at a first focusing distance from the eyebox; a multifunction optic located between the inner side of the image light guide and the eyebox, wherein the multifunction optic is formed as a single optical element operable to provide: (a) a negative optical power contribution operable to diverge the image-bearing light beams in advance of the eyebox, wherein the virtual object is viewed at a second focusing distance from the eyebox and the second focusing distance is closer than the first focusing distance, and (b) a corrective optical contribution operable to reduce optical aberrations associated with viewing of both the real-world object and the virtual object at the second focusing distance; and a positive-power optic on the outer side of the image light guide, wherein the positive-power optic is operable to compensate for the negative optical power contribution of the multifunction optic without compensating for the corrective optical contribution of the multifunction optic, wherein the real-world object is viewed at its actual distance from the eyebox with corrected vision. 13 . The augmented reality virtual image display system of claim 12 wherein, the multifunction optic is a single refractive lens element. 14 . The augmented reality virtual image display system of claim 12 wherein, the first focusing distance is a hyperfocal to near infinite distance and the closer second focusing distance is less than the hyperfocal distance. 15 . The augmented reality virtual image display system of claim 14 wherein, the closer second focusing distance is between 1.5 meters and 4 meters. 16 . The augmented reality virtual image display system of claim 14 wherein, the closer second focusing distance is between 0.05 meters and 1.5 meters. 17 . The augmented reality virtual image display system of claim 14 wherein, the corrective optical contribution is set for reducing the optical aberrations at the closer second focusing distance. 18 . The augmented reality virtual image display system of claim 12 wherein, the multifunction optic is a first of a plurality of multifunction optics, and the first multifunction optic is removable and replaceable with a second of the multifunction optics to adapt the display system to a different optical prescription. 19 . The augmented reality virtual image display system of claim 18 wherein, a negative-power contribution of the second multifunction optic is the same as the negative power contribution of the first multifunction optic, and a corrective optical contribution of the second multifunction optic is different from the corrective optical contribution of the first multifunction optic. 20 . The augmented reality virtual image display system of claim 12 wherein, the multifunction optic is a first of a plurality of multifunction optics, the positive-power optic is a first of a plurality of positive-power optics, and the first multifunction optic and the first positive-power optic are collectively removable and replaceable with a second of the multifunction optics and a second of the positive-power optics for changing the closer second focusing distance to a