High speed hologram recording apparatus

What is claimed is: 1. A hologram recording apparatus comprising: a coherent light source; a beam splitter which splits a beam emitted from the coherent light source into a signal beam and a reference beam; a signal beam forming unit comprising a first optical element which splits the signal beam into a plurality of sub signal beams and deflects each of the plurality of sub signal beams in a different direction, wherein the signal beam forming unit further directs the plurality of sub signal beams onto a plurality of different locations, respectively, on a hologram recording medium, such that each of the plurality of sub signal beams is incident on the hologram recording medium at the same angle; and a reference beam forming unit which directs the reference beam onto a location on the hologram recording medium which overlaps with the plurality of different locations on the hologram recording medium on which the plurality of sub signal beams are incident; wherein the overlapping of the plurality of sub signal beams and the reference beam on the hologram recording medium simultaneously records a plurality of hogels at the plurality of different locations on the hologram recording medium. 2. The hologram recording apparatus of claim 1 , wherein the first optical element comprising a plurality of refractive regions which split the signal beam into the plurality of sub signal beams and which refracts each of the plurality of signal beams to be deflected in different directions. 3. The hologram recording apparatus of claim 2 , wherein each of the plurality of refractive regions has a thickness which increases with a distance from a center axis of the signal beam. 4. The hologram recording apparatus of claim 2 , wherein each of the plurality of refractive regions has a thickness which decreases with a distance from the center axis of the signal beam. 5. The hologram recording apparatus of claim 2 , wherein the first optical element comprises m refractive regions, and the overlapping of the plurality of sub signal beams and the reference beam on the hologram recording medium simultaneously records m hogels on the hologram recording medium; wherein n is a an integer equal to or greater than 2 and m=n 2 . 6. The hologram recording apparatus of claim 2 , wherein the plurality of refractive regions are arranged in an n×n arrangement, wherein n is an integer equal to or greater than 2. 7. The hologram recording apparatus of claim 1 , wherein the first optical element splits the signal beam into m sub signal beams, and the overlapping of the plurality of sub signal beams and the reference beam on the hologram recording medium simultaneously records m hogels on the hologram recording medium; wherein n is a an integer equal to or greater than 2 and m=n 2 . 8. The hologram recording apparatus of claim 1 , wherein the signal beam forming unit further comprises: a spatial light modulator (SLM) which modulates the plurality of sub signal beams according to information of each of the plurality of hogels; and a first Fourier transformation optical system which Fourier transforms and focuses the modulated plurality of sub signal beams. 9. The hologram recording apparatus of claim 8 , wherein the SLM is disposed on an optical path between the first optical element and the first Fourier transformation optical system. 10. The hologram recording apparatus of claim 8 , wherein the SLM is a transmissive SLM. 11. The hologram recording apparatus of claim 8 , wherein the signal beam forming unit further comprises: a correction refractive optical element which corrects the plurality of sub signal beams focused by the first Fourier transformation optical system. 12. The hologram recording apparatus of claim 11 , wherein the correction refractive optical element comprises a plurality of correction refractive regions in a number corresponding to the plurality of refractive regions of the first optical element, and each of the plurality of refractive regions has a thickness which decreases with a distance from an axis corresponding to a center axis of the signal beam. 13. The hologram recording apparatus of claim 11 , wherein the signal beam forming unit further comprises: a second Fourier transformation optical system which transmits the plurality of sub signal beams from the correction refractive optical element onto the hologram recording medium. 14. The hologram recording apparatus of claim 8 , wherein the signal beam forming unit further comprises: a beam expanding optical system which expands a size of the signal beam from the beam splitter and transmits the expanded signal beam to the first optical element. 15. The hologram recording apparatus of claim 8 , wherein the signal beam forming unit further comprises: a phase mask, disposed on an optical path between the beam splitter and the first optical element, which adjusts a size and a shape of the signal beam and homogenizes an intensity of the signal beam. 16. The hologram recording apparatus of claim 8 , wherein the reference beam forming unit comprises: a beam shaping device which shapes the reference beam; and a telescopic optical system which adjusts an optical delay and a beam diameter of the reference beam. 17. The hologram recording apparatus of claim 1 , wherein the signal beam forming unit further comprises: a phase mask, disposed on an optical path between the beam splitter and the first optical element, which adjusts a size and a shape of the signal beam and homogenizes an intensity of the signal beam. 18. The hologram recording apparatus of claim 1 , wherein the reference beam forming unit comprises: a beam shaping device which shapes the reference beam; and a telescopic optical system which adjusts an optical delay and a beam diameter of the reference beam. 19. The hologram recording apparatus of claim 1 , further comprising: a location control system which varies spatial locations of the hogels on the hologram recording medium. 20. A hologram recording apparatus comprising: a coherent light source; a beam splitter which splits a beam from the coherent light source into a signal beam and a reference beam; a signal beam unit which splits the signal beam into a plurality of sub signal beams and deflects each of the plurality of sub signal beams in a different direction, modulates the plurality of sub-signal beams, and directs the modulated plurality sub signal beams onto a plurality of different locations, respectively, on a hologram recording medium, such that each of the modulated plurality of sub-signal beams is incident on the hologram recording medium at the same angle; and a reference beam unit which directs the reference beam onto a location on the hologram recording medium which overlaps simultaneously with the plurality of different locations of the hologram recording medium on which the plurality of sub signal beams are incident; wherein the overlapping of the plurality of sub signal beams and the reference beam on the hologram recording medium simultaneously records a plurality of hogels at the plurality of different locations on the hologram recording medium.