Rotational geometric phase hologram with application for fabricating geometric phase optical element

What is claimed is: 1. An apparatus comprising: plural geometric phase optical elements (GPOEs) serially cascaded along a common optical axis to form a GPOE cascade, the GPOE cascade having first and last GPOEs for generating a plurality of output light beams exited from an exit surface of the last GPOE in response to receiving a linearly-polarized (LP) light beam at the first GPOE, each GPOE in the GPOE cascade being rotatable about the common optical axis and having a rotation angle measured from a reference axis orthogonal to the common optical axis, wherein: interference occurred in the plurality of output light beams creates a polarization interference pattern on the exit surface; each GPOE in the GPOE cascade has a spatially-varying optic axis orientation distribution that varies one-dimensionally with a periodicity that exhibits odd or even symmetry; and respective rotation angles of the GPOEs in the GPOE cascade are reconfigurable and determined according to a spatially-varying linear polarization orientation distribution selected to be generated for the polarization interference pattern. 2. The apparatus of claim 1 further comprising: a light source for providing the LP light beam to the first GPOE. 3. The apparatus of claim 2 , wherein the light source is configured such that the LP light beam is ultraviolet (UV) light. 4. The apparatus of claim 2 , wherein the light source is configured such that the LP light beam is visible light. 5. The apparatus of claim 1 , wherein the LP light beam is monochromatic. 6. The apparatus of claim 5 , wherein each GPOE in the GPOE cascade satisfies a half wave condition with respect to a wavelength of the LP light beam. 7. The apparatus of claim 1 further comprising: a processor for determining the respective rotation angles. 8. The apparatus of claim 1 further comprising: a photoalignment substrate in close proximity to the exit surface for receiving the polarization interference pattern, wherein the photoalignment substrate is configured to record the spatially-varying linear polarization orientation distribution upon irradiated by the plurality of output light beams. 9. The apparatus of claim 1 , wherein: respective spatially-varying optic axis orientation distributions of the GPOEs are same. 10. The apparatus of claim 1 further comprising: a spatial filtering system for filtering the plurality of output light beams received from the last GPOE to form a plurality of filtered light beams used for creating a second polarization interference pattern having the spatially-varying linear polarization orientation distribution, wherein the spatial filtering system is configured to: block, from the plurality of output light beams, unwanted light beams that distort the spatially-varying linear polarization orientation distribution in creating the second polarization interference pattern; and allow two first-order diffracted light beams contributory to creating the polarization interference pattern to pass. 11. The apparatus of claim 10 further comprising: a photoalignment substrate located and arranged to receive the second polarization interference pattern, wherein the photoalignment substrate is configured to record the spatially-varying linear polarization orientation distribution upon irradiated by the plurality of filtered light beams. 12. The apparatus of claim 10 , wherein: the spatial filtering system comprises a first lens, a first aperture stop, a second aperture stop and a second lens, the first and second lens having a same focal length given by a first distance; the first lens is located from the last GPOE by the first distance for receiving and directing the plurality of output light beams to the first aperture stop; the first aperture stop is located from the first lens by the first distance; the second aperture stop is located between the first aperture stop and the second lens; and the second lens is located from the first aperture stop by the first distance for receiving the two first-order diffracted light beams and directing the two first-order diffracted light beams to interfere on a plane located from the second lens by the first distance to thereby generate the second polarization interference pattern. 13. The apparatus of claim 12 further comprising: a photoalignment substrate located on the plane for receiving the second polarization interference pattern, wherein the photoalignment substrate is configured to record the spatially-varying linear polarization orientation distribution upon irradiated by the plurality of filtered light beams sent out from the second lens. 14. An apparatus comprising: plural geometric phase optical elements (GPOEs) serially cascaded along a common optical axis to form a GPOE cascade, the GPOE cascade having first and last GPOEs for receiving a linearly-polarized (LP) light beam at the first GPOE and generating a plurality of output light beams exited from an exit surface of the last GPOE, each GPOE in the GPOE cascade being rotatable about the common optical axis and having a rotation angle measured from a reference axis orthogonal to the common optical axis, wherein interference occurred in the plurality of output light beams creates a polarization interference pattern on the exit surface, and respective rotation angles of the GPOEs in the GPOE cascade are reconfigurable and determined according to a spatially-varying linear polarization orientation distribution selected to be generated for the polarization interference pattern; and a spatial filtering system for filtering the plurality of output light beams received from the last GPOE to form a plurality of filtered light beams used for creating a second polarization interference pattern having the spatially-varying linear polarization orientation distribution, wherein the spatial filtering system is configured to: block, from the plurality of output light beams, unwanted light beams that distort the spatially-varying linear polarization orientation distribution in creating the second polarization interference pattern; and allow two first-order diffracted light beams contributory to creating the polarization interference pattern to pass. 15. The apparatus of claim 14 further comprising: a photoalignment substrate located and arranged to receive the second polarization interference pattern, wherein the photoalignment substrate is configured to record the spatially-varying linear polarization orientation distribution upon irradiated by the plurality of filtered light beams. 16. The apparatus of claim 14 , wherein: the spatial filtering system comprises a first lens, a first aperture stop, a second aperture stop and a second lens, the first and second lens having a same focal length given by a first distance; the first lens is located from the last GPOE by the first distance for receiving and directing the plurality of output light beams to the first aperture stop; the first aperture stop is located from the first lens by the first distance; the second aperture stop is located between the first aperture stop and the second lens; and the second lens is located from the first aperture stop by the first distance for receiving the two first-order diffracted light beams and directing the two first-order diffracted light beams to interfere on a plane located from the second lens by the first distance to thereby generate the second polarization interference pattern. 17. The apparatus of claim 16 further comprising: a photoalignment substrate located on the plane for receiving the second polarizati