Optical components

The invention claimed is: 1. A moulding process for making a substantially transparent optical component which comprises polymer, the optical component having substantially matching grating imprints on respective portions of its surface, wherein the grating imprints have a substantially zero relative orientation angle, the process comprising: forcing substantially transparent molten polymer between two surfaces of a moulding component, the surfaces having surface modulations which form two substantially matching gratings, the molten polymer forced into contact with the surface modulations so as to imprint the gratings in the polymer, wherein the moulding component is configurable to change the relative orientation angle of the gratings; wherein at least an alignment portion of the moulding component is substantially transparent, the alignment portion located so that light which has interacted with both gratings is observable from the alignment portion when the substantially transparent polymer is between the surfaces, whereby an observable fringe pattern is formed as the relative orientation angle of the gratings is changed towards zero, the fringe pattern exhibiting a fringe spacing which increases as the relative orientation angle decreases, the process further comprising: whilst the polymer is still liquid, reconfiguring the moulding component from a current configuration to a new configuration in which the fringe spacing of the fringe pattern is substantially maximal, thus aligning the gratings to have a substantially zero relative orientation angle, wherein the new configuration is maintained whilst the polymer sets. 2. A moulding process according to claim 1 comprising capturing images of the fringe pattern as the cavity is reconfigured and performing an automatic image recognition procedure to detect the fringe pattern in the images, wherein the step of reconfiguring is based on the results of the image recognition procedure. 3. A moulding process according to claim 1 comprising sensing light of only a small portion of the fringe pattern as the cavity is reconfigured, wherein the step of reconfiguring is based on the rate at which the intensity of that light changes. 4. A moulding process according to claim 1 wherein each of the gratings lies substantially parallel to a plane, and the gratings do not overlap or only partially overlap with one another when viewed along a direction normal to the plane. 5. A moulding process according to claim 1 comprising illuminating the gratings with an expanded laser beam, the fringe pattern formed by light of the laser beam which has interacted with both gratings. 6. A moulding process according to claim 5 comprising: receiving the light of the laser beam at a detector, part of the received light having been reflected from one of the gratings and another part of the light having been reflected from the other of the gratings, whereby the part and the other part interfere at the detector to form the fringe pattern on a detection surface of the detector; and using an output of the detector to control the reconfiguring step. 7. A moulding process according to claim 1 wherein the opposing portions of the cavity's surface are substantially parallel, so that the opposing portions of the moulded optical component's surface are substantially parallel. 8. A moulding process according to claim 1 , wherein a first and a second further grating are formed on other opposing portions of the cavity's surface, the first further grating having a first orientation angle Φ 1 relative to the one of the gratings and the second further grating having a second orientation angle Φ 2 relative to the other of the gratings, so that the first and second further gratings are imprinted in the polymer having a relative orientation angle that is substantially |Φ 2 −Φ 1 | in the new configuration. 9. A moulding process according to claim 1 wherein at least one of the surfaces of the moulding component is curved so that the polymer sets in a curved configuration. 10. A moulding process according to claim 1 wherein the moulding component is arranged to provide a moulding cavity, the surfaces being of the moulding cavity, and wherein the polymer is forced into the moulding cavity to force the polymer into contact with the surface modulations, the moulding component reconfigured to the new configuration whilst the polymer in the cavity is still liquid. 11. A moulding process according to claim 1 wherein the polymer is arranged in layers on the surface of a substantially transparent substrate, whereby the gratings are imprinted in the layers, the moulding component reconfigured to the new configuration whilst the layers are still liquid, wherein the optical component comprises the substrate and the layers once set. 12. A product obtained by the process of claim 1 . 13. A moulding apparatus for moulding a substantially transparent optical component which comprises polymer, the optical component having substantially matching grating imprints on opposing portions of its surface, wherein the grating imprints have a substantially zero relative orientation angle, the apparatus comprising: a moulding component having two surfaces, the surfaces having surface modulations which form two substantially matching gratings, wherein the moulding component is configurable to change the relative orientation angle of the gratings; a drive mechanism coupled to the moulding component controllable to configure the moulding component; wherein at least an alignment portion of the moulding component is substantially transparent, the alignment portion located so that light which has interacted with both gratings is observable from the alignment portion when the substantially transparent polymer is between the surfaces, whereby an observable fringe pattern is formed as the relative orientation angle of the gratings is changed towards zero, the fringe pattern exhibiting a fringe spacing which increases as the relative orientation angle decreases, the apparatus further comprising: a light sensor configured to receive at least some of the light which has interacted with both gratings; and a controller configured, whilst the polymer is still liquid, to control the drive mechanism based on sensed data received from the image sensor to reconfigure the moulding component from a current configuration to a new configuration in which the fringe spacing of the fringe pattern is substantially maximal, thus aligning the gratings to have a substantially zero relative orientation angle, wherein the new configuration is maintained whilst the polymer sets. 14. A moulding apparatus according to claim 13 wherein the light sensor comprises a camera which captures images of the fringe pattern as the cavity is reconfigured, and wherein the controller comprises an image recognition module which performs an automatic image recognition procedure to detect the fringe pattern in the images, wherein the controller reconfigures the cavity based on the results of the image recognition procedure. 15. A moulding apparatus according to claim 13 wherein the light sensor senses light of only a small portion of the fringe pattern as the cavity is reconfigured, and the controller is reconfigured based on the rate at which the intensity of that light changes. 16. An optical component for use in an optical system, wherein the optical component is substantially transparent and has two opposing outer surfaces, wherein at least a respective portion of each of the opposing surfaces is formed of polymer in which a respective grating is imprinted, wherein the