Geometric phase lens alignment in an augmented reality head mounted display

What is claimed is: 1. A head-mounted display comprises: a display block configured to combine light from a local area with image light to form an augmented scene, and provide the augmented scene to an eyebox corresponding a location of a user's eye, the display block comprising: a waveguide display configured to emit the image light, a focusing assembly having a first optical power, the focusing assembly configured to present the augmented scene at a first focal distance, wherein the focusing assembly includes a first focusing geometric phase lens that has a first axis of orientation, and a compensation assembly having a second optical power that compensates for the first optical power, and the compensation assembly includes a first compensation geometric phase lens that has a second axis of orientation that is orthogonal to the first axis of orientation. 2. The head-mounted display of claim 1 , wherein the first focusing geometric phase lens and the first compensation geometric phase lens have the same focal length. 3. The head-mounted display of claim 1 , wherein the first focusing geometric phase lens and the first compensation geometric phase lens each has a half-wave retardance for light at a first design wavelength and has a one-wave retardance for light at a second wavelength that is different than the first design wavelength. 4. The head-mounted display of claim 3 , wherein the focusing assembly includes a second focusing geometric phase lens and the compensation assembly includes a second compensation geometric phase lens that both have a half-wave retardance for light at a second design wavelength and have a one-wave retardance for light at the first design wavelength. 5. The head-mounted display of claim 1 , wherein the focusing assembly further includes a first switchable half-wave plate and the compensation assembly further includes a second switchable half-wave plate, the first switchable half-wave plate and second switchable half-wave plate each having a zero-retardation state and a half-wave retardation state that affect which focal plane image light is presented, and are configured to change state in accordance with multi-focal instructions. 6. The head-mounted display of claim 5 , wherein an axis of orientation of the first switchable half-wave plate is orthogonal to an axis of orientation of the second switchable half-wave plate. 7. The head-mounted display of claim 5 , further comprising an eye tracking system that determines eye tracking information of a user's eye. 8. The head-mounted display of claim 7 , further comprising a controller that generates the multi-focal instruction based in part on the eye tracking information, and provides the multi-focal instruction to the focusing assembly and compensation assembly. 9. A head-mounted display comprises: a display block configured to combine light from a local area with image light to form an augmented scene, and provide the augmented scene to an eyebox corresponding a location of a user's eye, the display block comprising: a waveguide display configured to emit the image light, a focusing assembly having a first optical power, the focusing assembly configured to present the augmented scene at a first focal distance, wherein the focusing assembly includes a plurality of focusing geometric phase lenses, each focusing geometric phase lens having a respective axis of orientation, and a compensation assembly having a second optical power that compensates for the first optical power, and the compensation assembly includes a plurality of compensation geometric phase lenses, each compensation geometric phase lens having a respective corresponding focusing geometric phase lens of the plurality of focusing geometric phases lenses, and each compensation geometric phase lens having a respective axis of orientation that is orthogonal to the axis of orientation of a corresponding focusing geometric phase lens. 10. The head-mounted display of claim 9 , wherein each focusing geometric phase lens has a same focal length as its respective corresponding compensation geometric phase lens. 11. The head-mounted display of claim 9 , wherein the focusing assembly further includes a first switchable half-wave plate and the compensation assembly further includes a second switchable half-wave plate, the first switchable half-wave plate and second switchable half-wave plate each having a zero-retardation state and a half-wave retardation state that affect which focal plane image light is presented, and are configured to change state in accordance with multi-focal instructions. 12. The head-mounted display of claim 11 , wherein an axis of orientation of the first switchable half-wave plate is orthogonal to an axis of orientation of the second switchable half-wave plate. 13. The head-mounted display of claim 11 , further comprising a controller that generates a multi-focal instruction and provides the multi-focal instruction to the focusing assembly and compensation assembly. 14. The head-mounted display of claim 11 , further comprising an eye tracking system that determines eye tracking information of a user's eye, wherein the multi-focal is generated based at least in part on the eye tracking information. 15. The head-mounted display of claim 14 , wherein a focal distance of the user's eye is selected based on the eye tracking information. 16. The head-mounted display of claim 9 , wherein a first focusing geometric phase lens of the focusing assembly and a first compensation geometric phase lens of the compensation assembly each has a half-wave retardance for light at a first design wavelength and has a one-wave retardance for light at a second wavelength that is different than the second design wavelength. 17. The head-mounted display of claim 16 , wherein the first design wavelength is red light, and the second design wavelength is green light. 18. A head-mounted display comprises: a display block configured to combine light from a local area with image light to form an augmented scene, and provide the augmented scene to an eyebox corresponding a location of a user's eye, the display block comprising: a waveguide display configured to emit the image light, a focusing assembly having a first optical power, the focusing assembly configured to combine compensated light from the local area with the image light to present the augmented scene at a first focal distance, wherein the focusing assembly includes a first geometric phase lens that has a first axis of orientation, and a compensation assembly having a second optical power that compensates for the first optical power to generate the compensated light that is provided to the focusing assembly, and the compensation assembly includes a second geometric phase lens that has a second axis of orientation that is orthogonal to the first axis of orientation.