Waveguide optics focus elements

The invention claimed is: 1. An imaging structure, comprising: a waveguide configured for viewing of an environment that is viewable, by a user, with the imaging structure, the waveguide further configured to transmit light of a virtual image that is generated by an image microdisplay to appear as part of the environment; and two or more focus elements integrated within the waveguide such that the environment is viewable by the user through the two or more focus elements, wherein individual focus elements are configured to be electronically switchable to an on state where the individual focus elements focus the light of the virtual image while the light of the virtual image is within the waveguide or an off state where the individual focus elements do not focus the light of the virtual image within the waveguide, wherein electronic switching of the two or more focus elements is effective to variably focus the light of the virtual image at a plurality of virtual image focus depths while the light of the virtual image is within the waveguide, wherein the plurality of virtual image focus depths approximately correlate to environment focus depths as perceived by the user, the environment focus depths determined by information from one or more sensors. 2. An imaging structure as recited in claim 1 , wherein one of: the waveguide is configured for see-through viewing of the environment for augmented-reality viewing of the light of the virtual image in the environment; or the waveguide is configured for display viewing of the light of the virtual image and the environment that are generated for virtual-reality viewing. 3. An imaging structure as recited in claim 1 , wherein the two or more focus elements are each configured for a different virtual image focus depth, and the two or more focus elements are electronically switchable without changing position relative to the waveguide. 4. An imaging structure as recited in claim 1 , wherein different virtual image focus depths are provided when different combinations of the two or more focus elements are switched-on or switched-off. 5. An imaging structure as recited in claim 1 , wherein the two or more focus elements are arranged so that the light of the virtual image travels through all of the two or more focus elements irrespective of whether the two or more focus elements are in the on state or the off state. 6. An imaging structure as recited in claim 1 , wherein the two or more focus elements comprise at least one of: switchable output diffractive devices; switchable output reflective devices; or Switchable Bragg Gratings. 7. An imaging structure as recited in claim 1 , wherein the two or more focus elements comprise: a first switchable output diffractive device configured to focus the light of the virtual image traveling in the waveguide at infinity when switched-on, and propagate the light of the virtual image down the waveguide when switched-off; a second switchable output diffractive device configured to focus the light of the virtual image traveling in the waveguide an intermediate virtual image focus depth when switched-on, and propagate the light of the virtual image down the waveguide when switched-off; and a third switchable output diffractive device configured to focus the light of the virtual image traveling in the waveguide at a near virtual image focus depth when switched-on, and propagate the light of the virtual image down the waveguide when switched-off. 8. A method, comprising: transmitting light of a virtual image in a waveguide, the virtual image generated by an image microdisplay to appear as part of an environment that is viewable by a user through the waveguide; and variably focusing the light of the virtual image to a plurality of different virtual image focus depths as the light of the virtual image travels through the waveguide, the variably focusing comprising controlling two or more focus elements that are contained within the waveguide and sequentially in a path of the light of the virtual image. 9. A method as recited in claim 8 , further comprising: determining a particular focal distance of the environment based at least on focus adjust data that indicates an eye accommodation distance of the user; and based at least on the particular focal distance of the environment, selecting a particular focus distance at which to focus the light of the virtual image via the two or more focus elements that are contained within the waveguide. 10. A method as recited in claim 8 , wherein the variably focusing comprises: selectively controlling different combinations of the two or more focus elements to be switched-on or switched-off, each combination corresponding to a particular virtual image focus depth. 11. A method as recited in claim 8 , wherein the two or more focus elements comprise one of switchable output diffractive devices or switchable output reflective devices. 12. A method as recited in claim 8 , wherein the two or more focus elements comprise Switchable Bragg Gratings. 13. A wearable display device, comprising: left and right display lens systems configured for augmented reality imaging; left and right imaging units of the respective left and right display lens systems configured to generate an augmented reality image; and a processor or controller, each of the left and right imaging units comprising: a waveguide configured for see-through viewing of an environment that is viewable by a user through the waveguide, the waveguide further configured to transmit light of a virtual image that is generated by an image microdisplay to appear as part of the environment; and two or more focus elements that are: integrated within the waveguide such that the environment is viewable by the user through the two or more focus elements; and each electronically switchable as on to focus the light of the virtual image or off so as not to focus the light of the virtual image, the two or more focus elements being switchable effective to variably focus the light of the virtual image while the light of the virtual image is travelling through the waveguide at a plurality of virtual image focus depths, wherein the processor or controller is configured to control the two or more focus elements so that the variable focus of the light of the virtual image approximately correlates to focal distances of the environment perceived by the user. 14. A wearable display device as recited in claim 13 , wherein the two or more focus elements are each configured for a different virtual image focus depth, and the two or more focus elements are electronically switchable without changing position relative to the waveguide. 15. A wearable display device as recited in claim 13 , wherein individual virtual image focus depths of the plurality of virtual image focus depths are achieved based on different combinations of the two or more focus elements being switched-on or switched-off. 16. A wearable display device as recited in claim 13 , embodied as glasses or a head-mounted display. 17. A wearable display device as recited in claim 13 , wherein the two or more focus elements comprise one of switchable output diffractive devices or switchable output reflective devices. 18. A wearable display device as recited in claim 13 , wherein the two or more focus elements comprise Switchable Bragg Gratings. 19. A wearable display device as recited in claim 13 , wherein the two or more focus elements comprise: a first switchable output diffractive device configured to focus the light of