Holographic display architecture

What is claimed is: 1. A holographic display of a head-mounted display (HMD) comprising: a source configured to emit light that is at least partially coherent light; a beam conditioner that conditions the light from the source into one or more beams of light; a spatial light modulator (SLM) configured to encode the one or more beams of light using a hologram of a virtual reality image; an objective lens having a first focal length, the objective lens configured to create an intermediate image at a Fourier plane, wherein the intermediate image is a Fourier transform of the hologram; a conversion lens having a second focal length, the conversion lens positioned away from the Fourier plane by the second focal length and configured to: perform a Fourier transform of the intermediate image to generate an output hologram, magnify a portion of the output hologram, the magnification based in part on the first focal length and the second focal length, and direct the magnified portion of the output hologram towards an exit pupil of the HMD corresponding to a location of an eye of a user of the HMD. 2. The holographic display of claim 1 , further comprising: a controller module configured to: calculate a Fresnel wave propagation of a three-dimensional synthetic image to generate a computer generated hologram, generate hologram instructions using the computer generated hologram, and provide the hologram instructions to the SLM; and wherein responsive to receiving the hologram instructions, the SLM displays the hologram in accordance with the hologram instructions. 3. The holographic display of claim 1 , further comprising: a spatial filter located at the Fourier plane, the spatial filter configured to transmit a single order of the intermediate image and block the remaining orders of the intermediate image and a DC component. 4. The holographic display of claim 3 , wherein the magnified portion of the output hologram is associated with two adjacent portions of a reconstructed image associated with the output hologram and the two adjacent portions are associated with different prism terms, and the two adjacent portions of the reconstructed image span a field of view larger than a largest field of view that a reconstructed image of a synthetic image can span without clipping. 5. The holographic display of claim 1 , wherein the beam conditioner further comprises: a diffraction grating configured to diffract the light emitted from the source into a plurality of diffracted beams, each beam corresponding to a different field of view of a reconstructed image associated with the output hologram; a focusing optic configured to focus the plurality of diffracted beams on a first plane; and a first spatial filter located at the first plane, the spatial filter configured to sequentially transmit different diffracted beams, of the diffracted beams, that each correspond to different fields of view of the reconstructed image, in accordance with filter instructions. 6. The holographic display of claim 5 , further comprising: a second spatial filter located at the Fourier plane, the second spatial filter configured to sequentially transmit different diffracted beams, of the diffracted beams, that each correspond to different fields of view of the reconstructed image, in accordance with the filter instructions. 7. The holographic display of claim 6 , wherein the magnified portion of the output hologram comprises a plurality of different portions of the output hologram that each correspond to a different diffracted beam. 8. The holographic display of claim 1 , further comprising: an additional source that is offset from the source and the additional source is associated with a field of view of the reconstructed image that is different from a field of view of the reconstructed image that is associated with the source. 9. The holographic display of claim 1 , wherein the SLM includes a plurality of SLM pixels and each SLM pixel is overlaid with an opaque portion and a pinhole. 10. The holographic display of claim 9 , wherein each pinhole is positioned randomly above its corresponding SLM subpixel. 11. The holographic display of claim 9 , wherein each pinhole is positioned at a same relative location above its corresponding SLM pixel. 12. The holographic display of claim 1 , wherein the SLM modulates phase information of the beam of light to encode the beam with phase information of the hologram. 13. The holographic display of claim 12 , further comprising an additional SLM configured to modulate phase information of the beam of light to encode the beam with additional phase information of the hologram. 14. The holographic display of claim 1 , wherein the SLM includes a plurality of SLM pixels and each SLM pixel is overlaid with an opaque portion and a pinhole, and each pinhole is positioned randomly above its corresponding SLM subpixel. 15. A holographic display of a head-mounted display (HMD) comprising: an source configured to emit at least partially coherent light; a beam conditioner that conditions the light from the source into one or more beams of light; a spatial light modulator configured to encode the one or more beams of light using a hologram of a virtual reality image; an objective lens, having a first focal length, the objective lens positioned to create an intermediate image at a Fourier plane, wherein the intermediate image is a Fourier transform of the hologram; a folding mirror that positions the real image of the hologram at the Fourier plane; a conversion lens having a second focal length, the conversion lens positioned away from the Fourier plane by the second focal length and configured to: perform a Fourier transform of the intermediate image to generate an output hologram, magnify a portion of the output hologram, the magnification based in part on the first focal length and the second focal length, and direct the magnified portion of the output hologram towards an exit pupil of the HMD corresponding to a location of an eye of a user of the HMD. 16. The holographic display of claim 15 , further comprising: a spatial filter located at the Fourier plane, the spatial filter configured to transmit a single order of the reconstructed image and block the remaining orders of the reconstructed image. 17. The holographic display of claim 16 , wherein the magnified portion of the output hologram is associated with two adjacent portions of a reconstructed image associated with the output hologram and the two adjacent portions are associated with different prism terms, and the two adjacent portions of the reconstructed image span a field of view larger than a largest field of view that a reconstructed image of a synthetic image can span without clipping. 18. The holographic display of claim 15 , wherein the beam conditioner further comprises: a diffraction grating configured to diffract the light emitted from the source into a plurality of diffracted beams, each beam corresponding to a different field of view of a reconstructed image associated with the output hologram; a focusing optic configured to focus the plurality of diffracted beams on a first plane; and a first spatial filter located at the first plane, the spatial filter configured to sequentially transmit different diffracted beams, of the diffracted beams, that each correspond to different fields of view of the reconstructed image, in accordance with filter instructions. 19. The holographic display of claim 18 , further comprising: a second spatial filter