Optical method and system for light field (LF) displays based on tunable liquid crystal (LC) diffusers

What is claimed: 1. An apparatus of light field display comprising: a first layer comprising an electrically adjustable liquid crystal capable of altering a polarization state of light passing through the first layer depending upon the state of electrical adjustment; and a second layer, parallel to the first layer, comprising a birefringent material having an optical interface to a substrate with surface features, wherein a refractive index difference associated with the optical interface depends on the polarization state of an incident light, wherein the second layer is configured to scatter, according to a first angular pattern, light passing through the second layer when the polarization state of the light is in a first polarization state corresponding to a first refractive index difference associated with the optical interface, and wherein the second layer is configured to scatter, according to a second angular pattern, light passing through the second layer when the polarization state of the light is in a second polarization state corresponding to a second refractive index difference associated with the optical interface. 2. The apparatus of claim 1 , wherein the birefringent material in the second layer having another optical interface to a substrate with surface features, wherein a refractive index difference associated with the other optical interface depends on the polarization state of an incident light, and wherein the second layer is configured to scatter light in a first direction when the polarization state of the light is in the first polarization state further corresponding to a first refractive index difference associated with the other optical interface, and wherein the second layer is configured to scatter in a second direction when the polarization state of the light is in the second polarization state further corresponding to a second refractive index difference associated with the other optical interface. 3. The apparatus of claim 2 , further comprising: a plurality of light emitting elements and collimating microlenses capable of producing collimated beams of light passing through the first layer; and a directionally controllable diffuser, comprising the first and the second layers, capable of switching between a first state wherein light is scattered in the first direction and a second state wherein light is scattered in the second direction. 4. The apparatus of claim 3 , wherein the directionally controllable diffuser is configured to scatter light in a vertical direction and the apparatus is configured so that only a single vertical view is generated if the apparatus is in a portrait orientation. 5. The apparatus of claim 3 , wherein at least a portion of the plurality of light emitting elements is configured in a plus-shaped pattern. 6. The apparatus of claim 3 , wherein responsive to a rotation of the apparatus, the directionally controllable diffuser is enabled to scatter light in a rotated direction and the apparatus is configured so that only a single view is generated in the rotated direction if the display orientation changes from portrait to landscape. 7. The apparatus of claim 3 , further comprising: a three-dimensional (3D) display, wherein the directional controllability of the diffuser is patterned across the 3D display allowing spatially varying diffusion directional characteristics. 8. The apparatus of claim 2 , wherein the surface features associated with the optical interface comprise linear microstructures that are orthogonal to the linear microstructures comprised in the surface features associated with the other optical interface. 9. A method, performed by a light field display device, comprising: altering a polarizing state of light passing through a first layer by adjusting an electrical state of an electrically adjustable liquid crystal comprised in the first layer; and scattering the light using a second layer, the second layer parallel to the first layer and comprising a birefringent material having an optical interface to a substrate with surface features, wherein a refractive index difference associated with the optical interface depends on the polarization state of an incident light, wherein the light is scattered according to a first angular pattern when the polarization state of the light is altered into a first polarization state corresponding to a first refractive index difference associated with the optical interface, and wherein the light is scattered according to a second angular pattern when the polarization state of the light is altered into a second polarization state corresponding to a second refractive index difference associated with the optical interface. 10. The method of claim 9 , wherein the birefringent material in the second layer having another optical interface to a substrate with surface features, wherein a refractive index difference associated with the other optical interface depends on the polarization state of an incident light, and wherein the light is scattered in a first direction when the polarization state of the light is altered into the first polarization state further corresponding to a first refractive index difference associated with the other optical interface, and wherein the light is scattered in a second direction when the polarization state of the light is altered into a second polarization state further corresponding to a second refractive index difference associated with the other optical interface. 11. The method of claim 10 , further comprising: emitting light using a plurality of light emitting elements; and collimating the emitted light, using microlenses, to produce collimated beams of the light passing through the first layer; and using a directionally controllable diffuser, comprising the first and the second layers, switching between a first state wherein light is scattered in the first direction and a second state wherein light is scattered in the second direction. 12. The method of claim 11 , wherein the first direction is a vertical direction, the switching to the first state comprises: generating a single vertical view when the display device is in a portrait orientation. 13. The method of claim 12 , wherein the second direction is a horizontal direction and responsive to a rotation of the display device from the portrait orientation to a landscape orientation, the switching to the second state comprises: generating a single horizontal view when the display device is in the landscape orientation. 14. The method of claim 10 , wherein the surface features associated with the optical interface comprise linear microstructures that are orthogonal to the linear microstructures comprised in the surface features associated with the other optical interface.