Waveguides incorporating transmissive and reflective gratings and related methods of manufacturing

What is claimed is: 1. A waveguide display, comprising: a source of light modulated with an image data; and a waveguide comprising: at least one transmission grating; at least one reflection grating, wherein said at least one reflection grating and said at least one transmission grating at least partially overlap; at least one input coupler for coupling light from said source of light into a total internal reflection (TIR) path in said waveguide towards the at least partially overlapping at least one transmission grating and at least one reflection grating; and at least one output coupler, wherein the at least partially overlapping at least one transmission grating and at least one reflection grating are configured to redirect the light to the at least one output coupler which is configured to output the light. 2. The waveguide display of claim 1 , wherein said at least one reflection grating and said at least one transmission grating are multiplexed in a single grating layer. 3. The waveguide display of claim 1 , wherein said at least one input coupler is a grating. 4. The waveguide display of claim 1 , wherein: said at least one input coupler comprises an input transmission grating; said at least one transmission grating comprises a fold transmission grating; and said fold grating is multiplexed with said at least one reflection grating. 5. The waveguide display of claim 1 , wherein: said at least one input coupler comprises an input transmission grating; said at least one transmission grating comprises at least first and second fold transmission gratings; said at least one reflection grating overlaps at least one of said input transmission grating and said first and second fold transmission gratings; said first and second fold transmission gratings overlap each other; said first and second fold transmission gratings have crossed K-vectors; and each of the fold transmission gratings is configured to beam-expand light from the input grating and couple it towards the other fold transmission grating, which then beam-expand and extract light towards a viewer. 6. The waveguide display of claim 1 , wherein each of said gratings has a grating vector that in combination provide a resultant vector with substantially zero magnitude. 7. The waveguide display of claim 1 , wherein said light undergoes a dual interaction within at least one of said gratings. 8. The waveguide display of claim 1 , further comprising a beam splitter layer overlapping said at least one reflection grating. 9. The waveguide display of claim 1 , further comprising an alignment layer overlapping said at least one reflection grating. 10. The waveguide display of claim 1 , wherein said source of data modulated light is one selected from the group consisting of: a laser-scanning projector, a microdisplay panel, and an emissive display. 11. The waveguide display of claim 1 , wherein said source of light provides at least two different wavelengths. 12. The waveguide display of claim 1 , wherein at least one of said gratings is characterized by a spatial variation of a property selected from the group consisting of: refractive index modulation, K-vector, grating vector, grating pitch, and birefringence. 13. The waveguide display of claim 1 , wherein said gratings are configured to provide a plurality of separate optical paths for a property selected from the group consisting of: wavelength band, angular bandwidth, and polarization state. 14. The waveguide display of claim 1 , wherein said waveguide is curved. 15. The waveguide display of claim 1 , wherein said waveguide incorporates a GRIN structure. 16. The waveguide display of claim 1 , wherein said waveguide is plastic. 17. The waveguide display of claim 1 , wherein at least one of said gratings comprises a structure selected from the group consisting of: a switchable Bragg grating recorded in a holographic photopolymer a HPDLC material, a switchable Bragg grating recorded in a uniform modulation holographic liquid crystal polymer material, a Bragg grating recorded in a photopolymer material, and a surface relief grating. 18. A method of fabricating a holographic waveguide, the method comprising: providing at least one light source, a layer of holographic recording material, and an at least partially reflective surface; forming first and second recording beams using said at least one light source; transmitting said first and second recording beams into said layer of holographic recording material; transmitting a portion of said first recording beam through said layer of holographic recording material towards said at least partially reflective surface; reflecting said transmitted portion of said first recording beam off said at least partially reflective surface back into said layer of holographic recording material; forming a transmission grating in said layer of holographic recording material using said first and second recording beams; and forming a reflection grating in said layer of holographic recording material using said reflected portion of said first recording beam and said second recording beam, wherein the transmission grating and the reflection grating are multiplexed. 19. The method of claim 18 , further comprising: forming a liquid crystal and polymer anchoring structure for supporting a reflection grating. 20. A method of fabricating a holographic waveguide, the method comprising: providing a master grating, a substrate supporting a layer of recording material, a source of light, and an at least partially reflective surface disposed opposite to said master grating with respect to said layer of recording material; illuminating said master grating with light from said source of light to form a diffracted beam and a zero-order beam; reflecting said diffracted beam from said at least partially reflective surface; forming a transmission grating from said zero-order beam and said diffracted beam; and forming a reflection grating from said zero-order beam and said reflected diffracted beam, wherein the transmission grating and the reflection grating are multiplexed.