Polarization independent optical shutter using cholesteric liquid crystals and three-dimensional image acquisition apparatus employing the same

What is claimed is: 1. An optical shutter comprising: a first polarization filter including a nanopore-cholesteric liquid crystal layer, the nanopore-cholesteric liquid crystal layer including a cholesteric liquid crystal matrix and a plurality of liquid crystal nanopores embedded in the cholesteric liquid crystal matrix, the plurality of liquid crystal nanopores associated with the first polarization filter including a plurality of first non-reactive liquid crystals (LCs), and the plurality of first non-reactive LCs configured to rearrange when an electric field is applied to the nanopore-cholesteric liquid crystal layer to vary a reflective wavelength band of the first polarization filter; and a second polarization filter parallel to the first polarization filter and including a nanopore-cholesteric liquid crystal layer, the nanopore-cholesteric liquid crystal layer including a cholesteric liquid crystal matrix and a plurality of liquid crystal nanopores embedded in the cholesteric liquid crystal matrix, the plurality of liquid crystal nanopores associated with the second polarization filter including a plurality of first non-reactive liquid crystals (LC), and the plurality of second non-reactive LCs configured to rearrange when the electric field is applied to the nanopore-cholesteric liquid crystal layer to vary a reflective wavelength band of the second polarization filter. 2. The optical shutter of claim 1 , wherein an effective refractive index of the nanopore-cholesteric liquid crystal layer and the reflective wavelength bands are changed when the electric field is applied to the nanopore-cholesteric liquid crystal layer. 3. The optical shutter of claim 1 , wherein a diameter of one or more of the plurality of liquid crystal nanopores is smaller than or equal to about 100 nm. 4. The optical shutter of claim 1 , wherein the nanopore-cholesteric liquid crystal layer of the first polarization filter and the nanopore-cholesteric liquid crystal layer of the second polarization filter are configured to have the same reflective wavelength band with respect to lights of opposite circular polarization. 5. The optical shutter of claim 1 , wherein the nanopore-cholesteric liquid crystal layer of the first polarization filter and the nanopore-cholesteric liquid crystal layer of the second polarization filter are configured to have the same reflective wavelength band with respect to lights of circular polarization that are in the same direction, and wherein a half-wave plate is between the first and second polarization filters. 6. The optical shutter of claim 5 , wherein at least one of the first and second polarization filters have fixed spiral directions of the cholesteric liquid crystal matrix. 7. The optical shutter of claim 1 , wherein the nanopore-cholesteric liquid crystal layers of the first and second polarization filters are configured to turn on or off light in a wavelength band from about 650 nm to about 2500 nm according to control of a voltage applied to the first and second polarization filters. 8. A three-dimensional (3D) image acquisition apparatus comprising: a lighting unit configured to irradiate light in an infrared band to an object in order to obtain depth information about the object; an image-forming lens unit configured to form an image of the object; the optical shutter of claim 1 configured to turn on or off the light in the infrared band irradiated by the lighting unit; a visible light shutter configured to turn on or off light in a visible light band; a control unit configured to control the optical shutter and the visible light shutter to alternately turn on or off the light by time multiplexing; an image sensor configured to sense the light reflected from the object and passing through the image-forming lens unit; and a 3D image processor configured to obtain color image information and depth image information by using the light sensed by the image sensor and generating 3D image information. 9. The 3D image acquisition apparatus of claim 8 , further comprising a broadband filter configured to transmit light in the infrared band and light in the visible light band. 10. The 3D image acquisition apparatus of claim 9 , wherein the broadband filter is between the object and the image-forming lens unit. 11. The 3D image acquisition apparatus of claim 10 , wherein the broadband filter is on a lens surface of the image-forming lens unit at an object side. 12. The 3D image acquisition apparatus of claim 8 , wherein the lighting unit is configured to irradiate light in a wavelength band from about 650 nm to about 2500 nm. 13. The 3D image acquisition apparatus of claim 8 , wherein the nanopore-cholesteric liquid crystal layer of the first polarization filter and the nanopore-cholesteric liquid crystal layer of the second polarization filter are configured to have the same reflective wavelength band with respect to lights of opposite circular polarization. 14. The 3D image acquisition apparatus of claim 8 , wherein the nanopore-cholesteric liquid crystal layer of the first polarization filter and the nanopore-cholesteric liquid crystal layer of the second polarization filter are configured to have the same reflective wavelength band with respect to lights of circular polarization that are in the same direction, and a half-wave plate is between the first and second polarization filters. 15. The optical shutter of claim 1 , wherein the plurality of first non-reactive LCs is configured to rearrange when the electric field is applied to the nanopore-cholesteric liquid crystal layer to vary the reflective wavelength band of the first polarization filter without changing a first spiral pitch of the cholesteric liquid crystal matrix associated with the first polarization filter. 16. The optical shutter of claim 1 , wherein the plurality of second non-reactive LCs is configured to rearrange when the electric field is applied to the nanopore-cholesteric liquid crystal layer to vary the reflective wavelength band of the second polarization filter without changing a second spiral pitch of the cholesteric liquid crystal matrix associated with the second polarization filter.