Waveguide display with a small form factor, a large field of view, and a large eyebox

What is claimed is: 1 . A waveguide system comprising: a coupling element for in-coupling light into a waveguide, the coupling element changing the direction of the wavevector by a first amount; a first one-dimensional decoupling grating configured to receive light from the waveguide and to change the direction of the wavevector by a second amount by diffracting at least a first portion of the in-coupled light; a second one-dimensional decoupling grating configured to change the direction of the wavevector by a third amount by diffracting at least a second portion of the in-coupled light and to output the redirected light to an eyebox, the second one-dimensional decoupling grating facing opposite the first one-dimensional decoupling grating, a total amount of the first amount, second amount, and third amount being predetermined based on a location of the eyebox, wherein the first one-dimensional decoupling grating and the second one-dimensional decoupling grating substantially overlaps along a direction parallel to a surface of the waveguide. 2 . The waveguide system of claim 1 , wherein the total amount is substantially zero. 3 . The waveguide system of claim 1 , wherein the first one-dimensional decoupling grating is a diffraction grating and wherein the first portion of the in-coupled light is based on an incident location of the in-coupled light. 4 . The waveguide system of claim 3 , wherein the first one-dimensional decoupling grating is configured to adjust the first portion of the in-coupled light based on an output angle of inclination of the diffracted first portion of the in-coupled light. 5 . The waveguide system of claim 1 , wherein the second one-dimensional decoupling grating is a diffraction grating and wherein the second portion of the in-coupled light is based on a location of an incident location of the in-coupled light. 6 . The waveguide system of claim 5 , wherein the second one-dimensional decoupling grating is configured to adjust the second portion of the in-coupled light based on an output angle of inclination of the diffracted second portion of the in-coupled light. 7 . The waveguide system of claim 1 , wherein a pitch of at least one of the coupling element, the first one-dimensional decoupling grating, and the second one-dimensional decoupling grating is in a range of 300-600 nm. 8 . The waveguide system of claim 1 , wherein the waveguide is configured to expand the in-coupled light in at least one dimension. 9 . The waveguide system of claim 8 , wherein each of the second one-dimensional decoupling grating and the third one-dimensional decoupling grating is configured to expand the in-coupled image light along a different dimension and to out-couple the redirected light along a third dimension. 10 . The waveguide system of claim 1 , wherein the waveguide is configured to expand the in-coupled light in at least one dimension parallel to the surface of the waveguide. 11 . The waveguide system of claim 1 , wherein the coupling element and the first one-dimensional decoupling grating are separated by a distance at least along a first dimension and a second dimension orthogonal to the first dimension along the surface of the waveguide, and the first coupling element and the second one-dimensional decoupling grating located at a central position along the second dimension. 12 . The waveguide system of claim 1 , wherein the coupling element is a diffraction grating on at least a first surface and a second surface of the waveguide, the coupling element configured to couple a first angular range and a second angular range of the light, and the second surface is opposite to the first surface. 13 . The waveguide system of claim 12 , wherein the first portion of light and the second portion of light are in the first angular range, the first one-dimensional decoupling grating expands the first portion of light to the second dimension, and the second one-dimensional decoupling grating expands the second portion of light to the second dimension. 14 . The waveguide system of claim 1 , wherein the first one-dimensional decoupling grating and the second one-dimensional decoupling grating are located on the surface of the waveguide with an interfacial layer between the first one-dimensional decoupling grating and the second one-dimensional decoupling grating. 15 . The waveguide system of claim 1 , wherein the first one-dimensional decoupling grating and the second one-dimensional decoupling grating are embedded into the waveguide and separated by an interfacial layer. 16 . The waveguide system of claim 1 , wherein the coupling element includes a first grating element and a second grating element separated along a first dimension parallel to the surface of the waveguide. 17 . The waveguide system of claim 16 , wherein the second one-dimensional decoupling grating is located between the first grating element and the second grating element, and the second one-dimensional decoupling grating is located at a central location on a second dimension between the first grating element and the second grating element, the second dimension orthogonal to the first dimension. 18 . The waveguide system of claim 1 , wherein the coupling element is a refractive surface. 19 . The waveguide system of claim 1 , wherein the first one-dimensional decoupling grating includes one or more cascaded reflectors configured to deflect the in-coupled light over an angular range, and the second one-dimensional decoupling grating includes one or more cascaded reflectors configured to output the deflected light to the eyebox. 20 . The waveguide system of claim 1 , wherein the waveguide system provides a diagonal FOV of at least 60 degrees.