Virtual image display with curved light path

What is claimed is: 1. A display comprising: a projector configured to provide light of a virtual image; a waveguide into which the light of the virtual image is injected at an injection angle by the projector, wherein the waveguide is configured to emit the light at a point established by the injection angle; and a combiner disposed along the waveguide and configured to redirect the light of the virtual image, the combiner being further configured to allow ambient light from beyond the waveguide to pass through the combiner; wherein: the waveguide constrains the light of the virtual image through total internal reflection along a curved path for the light between the projector and the combiner; the combiner is transparent at wavelengths other than wavelengths of the light of the virtual image provided by the projector; and the combiner redirects the wavelengths of the light of the virtual image provided by the projector. 2. The display of claim 1 , wherein the waveguide comprises a wedge waveguide section, the wedge waveguide section being tapered to emit the light after a number of reflections within the wedge waveguide section in accordance with the injection angle. 3. The display of claim 1 , wherein the combiner comprises a set of volume holograms embedded in the waveguide in a section of the waveguide, each volume hologram of the set of volume holograms being configured to extract the light from the waveguide in accordance with the injection angle and redirect the extracted light in a predetermined direction established via recording of the volume hologram. 4. The display of claim 1 , wherein the waveguide comprises a first section disposed along an eyeglass temple, a second section disposed along the combiner, and a third section disposed between the first and second sections and defining the curved path. 5. The display of claim 1 , further comprising: a camera to capture data indicative of an image of a pupil of a viewer viewing the display; and a processor configured to determine a position of the pupil based on the captured data, and further configured to generate a control signal to establish the injection angle of the projector; and wherein the projector is configured to adjust the injection angle in accordance with the control signal. 6. The display of claim 5 , further comprising a scanner configured to concentrate the light redirected by the combiner at a plurality of possible positions of the pupil. 7. The display of claim 6 , wherein: the scanner comprises a stack of switchable gratings disposed between the combiner and the pupil; and the processor is further configured to generate further control signals to selectively activate one or more respective switchable gratings of the set of switchable gratings to steer the light redirected by the combiner toward a respective one of the plurality of possible positions of the pupil. 8. The display of claim 7 , wherein the stack of switchable gratings comprises: a first subset of switchable gratings to steer the light horizontally to one of a plurality of horizontal position offsets; and a second subset of switchable gratings to steer the light vertically to one of a plurality of vertical position offsets. 9. The display of claim 7 , wherein each switchable grating of the set of switchable gratings is pixelated to modulate an amount of steering provided by the respective switchable grating as a function of position. 10. The display of claim 5 , further comprising a peripheral vision system, the peripheral vision system comprising: a backlight unit configured to generate converging rays of light; and a liquid crystal display (LCD) panel illuminated by the converging rays; wherein the processor is configured to control the backlight unit in accordance with the position of the pupil to converge the rays of light at the pupil, and to control the LCD panel to provide peripheral vision imagery and to establish a deactivated region of the LCD panel through which the light emitted from the waveguide passes to reach a fovea of the viewer. 11. The display of claim 10 , wherein the backlight unit comprises an array of volume holograms, each volume hologram being configured to direct the rays to a respective pupil position upon excitation. 12. The display of claim 10 , wherein a region of the backlight unit does not provide light to the LCD panel to establish a non-illuminated region of the LCD panel to avoid conflict with the light emitted from the waveguide to reach the fovea of the viewer. 13. The display of claim 1 , wherein the projector is a holographic projector configured to correct for aberration arising from the curved path. 14. An electronic device comprising: a camera to capture data indicative of an image of a pupil of a viewer viewing the display; a memory in which pupil tracking instructions and projector control instructions are stored; a processor configured by the pupil tracking instructions to determine a position of the pupil based on the captured data; and a display comprising: a holographic projector configured to provide light of a virtual image; a waveguide into which the light of the virtual image is injected at an injection angle by the projector, wherein the waveguide is configured to emit the light at a point established by the injection angle; and a combiner disposed along the waveguide and configured to redirect the light of the virtual image, the combiner being further configured to allow ambient light from beyond the waveguide to pass through the combiner; wherein: the waveguide constrains the light of the virtual image through total internal reflection along a curved path for the light between the projector and the combiner; the processor is configured by the projector control instructions to generate a control signal to establish the injection angle of the projector; the combiner is transparent at wavelengths other than wavelengths of the light of the virtual image provided by the projector; and the combiner redirects the wavelengths of the light of the virtual image provided by the projector. 15. The electronic device of claim 14 , wherein the waveguide comprises a wedge waveguide section, the wedge waveguide section being tapered to emit the light after a number of reflections within the wedge waveguide section in accordance with the injection angle. 16. The electronic device of claim 15 , wherein the combiner comprises a grating disposed along the wedge waveguide section. 17. The electronic device of claim 14 , wherein the combiner comprises a set of volume holograms embedded in the waveguide in a section of the waveguide, each volume hologram of the set of volume holograms being configured to extract the light from the waveguide in accordance with the injection angle and redirect the extracted light in a predetermined direction established via recording of the volume hologram. 18. The electronic device of claim 14 , further comprising a peripheral vision system, the peripheral vision system comprising: a backlight unit configured to generate converging rays of light; a liquid crystal display (LCD) panel illuminated by the converging rays; and a polarizer disposed between the LCD panel and the viewer to filter an output of the LCD panel; wherein the processor is configured to control the backlight unit in accordance with the position of the pupil to converge the rays of light at the pupil, and to control the LCD panel to provide peripheral vision imagery and to establish a non-illuminated region of the LCD panel through which the li