Beam steering device using liquid crystal polarization gratings

The invention claimed is: 1. An imaging device comprising an image sensor, the imaging device comprising: one or more liquid crystal polarization gratings (LCPGs), wherein the one or more LCPGs are controllable to apply a deflection to an electromagnetic beam such that the electromagnetic beam is directed from a different field of view (FOV) other than a non-deflected FOV onto the image sensor; an image sensor comprising a plurality of pixels, responsive to electromagnetic beams directed by the one or more LCPGs so as to be incident thereon to generate a signal representative of the incident electromagnetic beams; and an imaging controller for controlling the one or more LCPGs so as to direct electromagnetic beams from a first and a second FOV onto each of the plurality of pixels to create a first and a second intermediate image, respectively, so as to create a combined higher resolution image output of the image sensor. 2. An imaging device according to claim 1 , wherein the one or more LCPGs are controlled to cause deflection of the electromagnetic beam onto the image sensor by less than a pitch of the pixels of the image sensor. 3. An imaging device according to claim 1 , wherein the one or more LCPGs are controlled to cause deflection of the electromagnetic beam onto the image sensor by a non-integer multiple of a pitch of the pixels of the image sensor. 4. An imaging device according to claim 1 , wherein the imaging device further comprises an illumination source for emitting an electromagnetic beam, wherein the one or more LCPGs are arranged at the illumination source such that electromagnetic beam is capable of being directed to different parts of a scene. 5. An imaging device according to claim 4 , wherein the illumination source is configured to emit structured light. 6. An imaging device according to claim 1 , wherein the one or more LCPGs comprises a plurality of LCPGs arranged in a stack. 7. An imaging device according to claim 6 , wherein the plurality of LCPGs comprises at least one LCPG arranged orthogonally to another LCPG to permit for two-dimensional deflection of the electromagnetic beam. 8. An imaging device according to claim 6 , wherein the plurality of LCPGs comprises at least two LCPGS arranged in the same orientation to permit for greater angular deflection of the beam than available from a single grating. 9. An imaging device comprising an image sensor comprising a plurality of pixels and having a native field of view (FOV) and a native resolution, the imaging device comprising: an image controller; imaging optics including one or more controllable liquid crystal polarization gratings (LCPGs), wherein the one or more LCPGs are controllable by the image controller to steer light onto the image sensor from across a wider FOV than the native FOV to obtain images from across the wider FOV; and a determination unit for determining a region-of-interest (ROI) within the wider FOV and corresponding to a subset of the wider FOV such that the ROI can be imaged with a higher resolution than the native resolution of the image sensor. 10. An imaging device according to claim 9 , wherein the image controller controls the one or more LCPGs to image the ROI with a higher resolution than the native resolution of the image sensor. 11. An imaging device according to claim 10 , wherein the image sensor is responsive to electromagnetic beams directed by the one or more LCPGs so as to be incident thereon to generate a signal representative of the incident electromagnetic beams, and creates a first and a second intermediate image by reading signals representative of a first and second incident electromagnetic beam, respectively, from a first and second FOV each having the ROI and each being a subset of the wider FOV, wherein the second incident electromagnetic beam is deflected relative to a first incident electromagnetic beam, respectively, so as to create a combined higher resolution image output of the image sensor. 12. An imaging device according to claim 9 , wherein the image controller controls the amount of steering provided by the one or more LCPGs for obtaining images across a wider FOV than the native FOV to be greater than the amount of steering provided by the LCPGs for imaging the ROI with a higher resolution than the native resolution of the image sensor. 13. An imaging device according to claim 12 , wherein the one or more LCPGs are controlled to cause deflection of an electromagnetic beam onto the image sensor by either: less than a pitch of the pixels of the image sensor or a non-integer multiple of a pitch of the pixels of the image sensor. 14. An imaging device according to claim 9 , wherein the imaging device further comprises an illumination source for emitting an electromagnetic beam, wherein the one or more LCPGs are arranged at the illumination source such that electromagnetic beam is capable of being directed to different parts of a scene. 15. An imaging device according to claim 14 , wherein the one or more LCPGs are controlled to cause deflection of the electromagnetic beam onto a part of the scene such that the electromagnetic beam that is received by the image sensor shifts by either: a distance of less than a pitch of the pixels of the image sensor in order to capture the first or second FOV or a distance of a non-integer multiple of a pitch of the pixels of the image sensor in order to create the higher resolution image. 16. A method of surveillance across a field of view (FOV) wider than a native FOV of an image sensor, the image sensor comprising a plurality of pixels, the method comprising: providing an image sensor having a native FOV and native resolution, and imaging optics to allow an image to be obtained by the image sensor, the imaging optics including one or more controllable liquid crystal polarization gratings (LCPGs); controlling the one or more LCPGs to steer light onto to the image sensor from across a wider FOV than the native FOV to obtain images from across the wider FOV; determining a region-of-interest (ROI) within the wider FOV and corresponding to a subset of the wider FOV; and imaging the ROI with a higher resolution than the native resolution of the image sensor. 17. A method according to claim 16 , wherein imaging the ROI with a higher resolution than the native resolution of the image sensor comprises imaging using the one or more LCPGs. 18. A method according to claim 17 , wherein imaging the ROI with a higher resolution than the native resolution of the image sensor comprises: receiving a first incident electromagnetic beam generated by or reflected from remote objects at each of the plurality of pixels via one or more LCPGs; for a first FOV having the ROI that is a subset of the wider FOV, obtaining a first intermediate image by reading a signal representative of the first incident electromagnetic beam at each of the plurality of pixels; receiving a second incident electromagnetic beam generated by or reflected from the remote objects at each of the plurality of pixels via the one or more LCPGs that is deflected relative to the first incident electromagnetic beam; for a second FOV having the ROI that is a subset of the wider FOV, obtaining a second intermediate image by reading a signal representative of the second incident electromagnetic beam at each of the plurality of pixels; and multiplexing the first and the second intermediate images together to create a combined higher resolution image output of the image sensor. 19. A method according to claim 18 , further co