Waveguide comprising a bragg polarization grating

What is claimed is: 1. A system comprising: an optical waveguide comprising an input-coupler, an intermediate-component, an output-coupler, and a bulk-substrate having a first major surface and a second major surface opposite the first major surface; and a display engine configured to produce an image and to direct light corresponding to the image towards the input-coupler of the optical waveguide, wherein: the input-coupler is configured to couple light corresponding to the image, that is incident on the input-coupler, into the optical waveguide and towards the intermediate-component; the intermediate-component is configured to perform pupil expansion and direct the light corresponding to the image towards the output-coupler; the output-coupler is configured to couple, out of the optical waveguide, the light corresponding to the image that travels in the optical waveguide from the input-coupler to the output-coupler via the intermediate-component by way of total internal reflection (TIR); and the intermediate-component comprises a Bragg polarization grating comprising a stack of birefringent layers, the stack of birefringent layers being located on one of the first major surface or the second major or being embedded between the first major surface and the second major surface. 2. The system of claim 1 , wherein the Bragg polarization grating is further configured to: diffract the light corresponding to the image that is incident thereon into a zero-order beam having one of right handed circular polarization or left handed circular polarization, and a first-order beam having the other one of right handed circular polarization or left handed circular polarization; have a relatively high diffractive efficiency for light within an angle of incidence range having one of right handed circular polarization or left handed circular polarization; and have a relatively low diffractive efficiency for light within the angle of incidence range having the other one of right handed circular polarization or left handed circular polarization. 3. The system of claim 2 , wherein the relatively high diffractive efficiency for light within the angle of incidence range is at least one order of magnitude greater than the relative low diffractive efficiency for light within the angle of incidence range. 4. The system of claim 2 , wherein the Bragg polarization grating is further configured to: cause the zero-order beam to have the one of right handed circular polarization or left handed circular polarization for which the Bragg polarization grating has the relatively high diffractive efficiency; and cause the first-order beam to have the one of right handed circular polarization or left handed circular polarization for which the Bragg polarization grating has the relatively low diffractive efficiency. 5. The system of claim 2 , wherein the Bragg polarization grating is further configured to: cause the zero-order beam to have the one of right handed circular polarization or left handed circular polarization for which the Bragg polarization grating has the relatively low diffractive efficiency; and cause the first-order beam to have the one of right handed circular polarization or left handed circular polarization for which the Bragg polarization grating has the relatively high diffractive efficiency. 6. The system of claim 2 , wherein the Bragg polarization grating is further configured to reduce a quantity of interference loops that occur within the intermediate-component compared to if the intermediate component was not a Bragg polarization grating configured as specified in claim 2 . 7. The system of claim 2 , wherein the Bragg polarization grating is further configured to reduce an extent of destructive interference that is caused by interference loops that occur within the intermediate-component compared to if the intermediate component was not a Bragg polarization grating configured as specified in claim 2 . 8. The system of claim 2 , wherein the Bragg polarization grating is further configured to cause the zero-order and first-order beams to each have an elliptical polarization having an ellipticity angle that changes in dependence on where an optical interaction occurs with the intermediate-component. 9. The system of claim 2 , wherein the Bragg polarization grating is further configured to increase polarization diversity of the light corresponding to the image that travels through the optical waveguide from the input-coupler to the output-coupler via the intermediate-component by way of TIR, and thereby provides for a more uniform intensity distribution, compared to if the intermediate component was not configured to diffract the light corresponding to the image that is incident thereon into a zero-order beam having one of right handed circular polarization or left handed circular polarization, and a first-order beam having the other one of right handed circular polarization or left handed circular polarization. 10. The system of claim 1 , wherein: the pupil expansion that the intermediate-component is configured to perform is one of horizontal or vertical pupil expansion; and the output-coupler is configured to perform the other one of horizontal or vertical pupil expansion. 11. A method comprising: producing light corresponding to an image; coupling the light corresponding to the image into an optical waveguide comprising an input-coupler, an intermediate-component, and an output-coupler; after the light corresponding to the image has been coupled into the optical waveguide, and has traveled within at least a portion of the optical waveguide by way of total internal reflection (TIR), diffracting the light corresponding to the image into a zero-order beam having one of right handed circular polarization or left handed circular polarization, and a first-order beam having the other one of right handed circular polarization or left handed circular polarization; after the light corresponding to the image has been diffracted into the zero-order beam having the one of right handed circular polarization or left handed circular polarization, and the first-order beam having the other one of right handed circular polarization or left handed circular polarization, coupling at least a portion of the light corresponding to the image out of the optical waveguide; and implementing the intermediate-component using a stack of birefringent layers that is configured to: diffract the light corresponding to the image that is incident thereon into the zero-order beam having the one of right handed circular polarization or left handed circular polarization, and the first-order beam having the other one of right handed circular polarization or left handed circular polarization; have a relatively high diffractive efficiency for light within an angle of incidence range having one of right handed circular polarization or left handed circular polarization; and have a relatively low diffractive efficiency for light within the angle of incidence range having the other one of right handed circular polarization or left handed circular polarization. 12. The method of claim 11 , wherein: the coupling the light corresponding to the image into optical waveguide is performed using the input-coupler of the optical waveguide; the diffracting the light corresponding to the image into the zero-order beam having one of right handed circular polarization or left handed circular polarization, and the first-order beam having the other one of right handed circular polarization or left handed circular polarization, is performed using the intermediate-component of the optical waveguide; and the coupling at leas