Single RGB combiner with large field of view

The invention claimed is: 1. An optical combiner, comprising: an optical substrate having characteristics to guide light by total internal reflection; an in-coupler grating positioned to receive an incident light with a field of view (FOV), the in-coupler grating tuned to couple a first light portion of the incident light with a first part of the FOV (first light portion) into a first propagation path within the optical substrate and a second light portion of the incident light with a second part of the FOV (second light portion) into a second propagation path within the optical substrate, the first light portion including light of a first color, the second light portion excluding light of the first color; a first fold grating in optical communication with the first propagation path, the first fold grating tuned to expand the first light portion by splitting the first light portion into a plurality of first sub-beams and further tuned to change a beam propagation direction of the first sub-beams from the propagation direction of the first light portion; a second fold grating in optical communication with the second propagation path, the second fold grating tuned to expand the second light portion by splitting the second light portion into a plurality of second sub-beams and further tuned to change a beam propagation direction of the second sub-beams from the propagation direction of the second light portion; and an out-coupler grating positioned to receive the first sub-beams from the first fold grating and the second sub-beams from the second fold grating, the out-coupler grating having one or more diffraction gratings tuned to couple the first sub-beams and the second sub-beams out of the optical substrate at a plurality of exit pupils. 2. The optical combiner of claim 1 , wherein the in-coupler grating is a two-dimensional surface relief grating having a first grating periodicity tuned to diffract and couple the first light portion into the first propagation path and a second grating periodicity tuned to diffract and couple the second light portion into the second propagation path. 3. The optical combiner of claim 1 , wherein the in-coupler grating includes a first surface relief grating tuned to diffract and couple the first light portion into the first propagation path and a second surface relief grating tuned to diffract and couple the second light portion into the second propagation path. 4. The optical combiner of claim 3 , wherein the optical substrate has a first major surface and a second major surface, the first major surface spaced apart from the second major surface along an axial thickness of the optical substrate, and wherein the first surface relief grating and the second surface relief grating are arranged side by side on or proximate one of the major surfaces. 5. The optical combiner of claim 3 , wherein the optical substrate has a first major surface and a second major surface, the first major surface spaced apart from the second major surface by an axial thickness of the optical substrate, and wherein the first surface relief grating is arranged on or proximate the first major surface and the second surface relief grating is arranged on or proximate the second major surface. 6. The optical combiner of claim 1 , wherein the incident light includes light of the first color, light of a second color, and light of a third color. 7. The optical combiner of claim 6 , wherein the first light portion further includes a first portion of the light of the second color and a first portion of the light of the third color, and wherein the second light portion includes a second portion of the light of the second color and a second portion of the light of the third color. 8. The optical combiner of claim 6 , wherein the second light portion includes the light of the second color and the light of the third color. 9. The optical combiner of claim 6 , wherein the in-coupler grating comprises a first volume hologram that is responsive only to light of the first color, the first volume hologram to diffract and couple the light of the first color in a direction towards the first propagation path. 10. The optical combiner of claim 9 , wherein the in-coupler grating further includes: a first set of multiplexed holograms comprising: a second volume hologram that is responsive only to the light of the second color over a first range of incidence angles, the second volume hologram to diffract and couple a first portion of the light of the second color in a direction towards the first propagation path; and a third volume hologram that is responsive only to the light of the third color over the first range of incidence angles, the third volume volume hologram to diffract and couple a first portion of the light of the third color in a direction towards the first propagation path; and a second set of multiplexed holograms comprising: a fourth volume hologram that is responsive only to the light of the second color over a second range of incidence angles, the fourth volume hologram to diffract and couple a second portion of the light of the second color in a direction towards the second propagation path; and a fifth volume hologram that is responsive only to the light of the third color over the second range of incidence angles, the fifth volume hologram to diffract and couple a second portion of the light of the third color in a direction towards the second propagation path. 11. The optical combiner of claim 10 , wherein the in-coupler grating further includes: a second volume hologram that is responsive only to the light of the second color, the second volume hologram to diffract and couple the light of the second color in a direction towards the second propagation path; and a third volume hologram that is responsive only to the light of the third color, the third volume hologram to diffract and couple the light having the third color in a direction towards the second propagation path. 12. The optical combiner of claim 6 , wherein the out-coupler grating comprises a first holographic grating positioned and oriented to receive the plurality of first sub-beams from the first fold grating and redirect the plurality of first sub-beams to a plurality of exit pupils and a second holographic grating positioned and oriented to receive the plurality of second sub-beams from the second fold grating and redirect the plurality of second sub-beams to the plurality of exit pupils. 13. The optical combiner of claim 12 , wherein the first holographic grating comprises a plurality of first holographic regions corresponding to the plurality of exit pupils, wherein the second holographic grating comprises a plurality of second holographic regions corresponding to the plurality of exit pupils, and wherein each of the first holographic regions and second holographic regions is tuned to diffract light to the respective exit pupil. 14. The optical combiner of claim 13 , wherein the first holographic grating includes a first holographic sub-grating that is responsive only to a portion of the first sub-beams having the first color, a second holographic sub-grating that is responsive only to a portion of the first sub-beams having the second color, and a third holographic sub-grating that is responsive only to a portion of the first sub-beams having the third color, and wherein each of the first holographic sub-grating, the second holographic sub-grating, and the third holographic sub-grating includes a plurality of holographic regions corresponding to the plurality of exit pupils, each of the holographic regions tuned to diffract light to the respective exit pupil.