Near-to-eye and see-through holographic displays

What is claimed is: 1. A holographic video display comprising: a plurality of space-multiplexed elemental modulators, wherein each elemental modulator is configured to employ leaky-mode diffraction of guided-mode light to produce a line of a holographic display, each elemental modulator comprising: an anisotropic waveguide; at least one in-coupling reflection grating positioned on the anisotropic waveguide at a location selected for coupling incident light into the waveguide to produce guided-mode light travelling in the waveguide, wherein the incident light is pulsed; a plurality of surface acoustic wave transducers disposed along the top of the anisotropic waveguide, wherein each surface acoustic wave transducer is configured to diffract the guided-mode light travelling in the waveguide into leaky-mode light output that propagates away from a viewer, and wherein the plurality of surface acoustic wave transducers are positioned such that guided-mode light that is undiffracted by a first one of the plurality of transducers is available for diffraction by subsequent ones of the plurality of transducers, thereby producing a longer holographic line than would be possible with a single transducer; and at least one output volume reflection grating positioned on the anisotropic waveguide, each output volume reflection grating being positioned at a location selected for steering the leaky-mode light output towards the viewer. 2. The holographic video display of claim 1 , further comprising an electrical control layer, the electrical control layer comprising a graphics processing unit, circuitry for RF up-conversion and amplification, and a multiplexor for switching amongst holographic lines to drive multiple holographic lines in sequence to achieve time-multiplexed operation. 3. The holographic video display of claim 1 , further comprising a substrate on which the plurality of elemental modulators are disposed. 4. The holographic video display of claim 3 , wherein the substrate is lithium niobate. 5. The holographic video display of claim 1 , wherein each anisotropic waveguide is divided into segments, each provided with separate illumination. 6. The holographic video display of claim 1 , wherein the display is transparent and all reflection volume gratings operate in the Bragg regime. 7. The holographic video display of claim 1 , wherein each anisotropic waveguide is associated with multiple one-to-one associated acoustic transducers and volume reflection gratings, arranged along the anisotropic waveguide to produce multiple output lines. 8. The holographic video display of claim 7 , further comprising a substrate on which the plurality of elemental modulators are disposed. 9. The holographic video display of claim 1 , wherein the plurality of acoustic transducers are disposed along the anisotropic waveguide in a manner that provides a specified length of optical line. 10. A holographic video image produced using the display of claim 1 . 11. A method for generating a holographic image, comprising: providing one or more wavelengths of incident light to a holographic video display, wherein the incident light is pulsed, the display comprising a plurality of space-multiplexed elemental modulators, wherein each elemental modulator is configured to employ leaky-mode diffraction of guided-mode light to produce a line of a holographic display, each elemental modulator comprising: an anisotropic waveguide; at least one in-coupling reflection grating positioned on the anisotropic waveguide at a location selected for coupling the incident light into the waveguide to produce guided-mode light travelling in the waveguide; a plurality of surface acoustic wave transducers disposed along the top of the anisotropic waveguide, wherein each surface acoustic wave transducer is configured to diffract the guided-mode light travelling in the waveguide into leaky-mode light output that propagates away from the viewer, and wherein the plurality of surface acoustic wave transducers are positioned such that guided-mode light that is undiffracted by a first one of the plurality of transducers is available for diffraction by subsequent ones of the plurality of transducers, thereby producing a longer holographic line than would be possible with a single transducer; and at least one output volume reflection grating positioned on the anisotropic waveguide, each output volume reflection grating being positioned at a location selected for steering the leaky-mode light output towards a viewer; providing holographic information to the video display; coupling the light received at the holographic video display into the elemental modulators for diffraction according to the holographic information; and scanning the steered light to form the holographic image. 12. The method of claim 11 , wherein the holographic video display further comprises an electrical control layer, the electrical control layer comprising a graphics processing unit, circuitry for RF up-conversion and amplification, and a multiplexor for switching amongst holographic lines to drive multiple holographic lines in sequence to achieve time-multiplexed operation. 13. The method of claim 11 , wherein the holographic video display further comprises a substrate on which the plurality of elemental modulators are disposed. 14. The method of claim 13 , wherein the substrate is lithium niobate. 15. The method of claim 11 , wherein each anisotropic waveguide is divided into segments, each provided with separate illumination. 16. The method of claim 11 , wherein the display is transparent and all reflection volume gratings operate in the Bragg regime. 17. The method of claim 11 , wherein each anisotropic waveguide is associated with multiple one-to-one associated acoustic transducers and volume reflection gratings, arranged along the anisotropic waveguide to produce multiple output lines. 18. The method of claim 17 , wherein the holographic video display further comprises a substrate on which the plurality of elemental modulators are disposed. 19. The method of claim 11 , wherein the plurality of acoustic transducers are disposed along the anisotropic waveguide in a manner that provides a specified length of optical line. 20. A holographic video display that employs the method of claim 11 .