Method for determining absolute coding of an optical coding track

What is claimed is: 1. A method for registering absolute coding, wherein the absolute coding is embodied by individual code elements of a code track and the individual code elements respectively form a main point or centroid, the method comprising: illuminating of the code elements with light; modulating of part of the illuminating light at code elements; registering of modulated light and generation of state signals, and establishing of a main point or centroid for the state signals and the positions thereof; wherein: the modulation of the light at adjacent code elements in the direction of extent of the code track is effected in a continuously varying manner. 2. The optical code track embodying absolute coding, for use in the method as claimed in claim 1 , wherein: the optical code track comprises a mechanical support, and the mechanical support, at least in regions, comprises code elements, wherein the individual code elements respectively form a defined main point or centroid; wherein the code elements are embodied in such a way that adjacent code elements modulate illuminating light in the direction of extent of the code track in a continuously varying manner. 3. The optical code track as claimed in claim 2 , wherein the mechanical support comprises either or both a disk or a ribbon. 4. The optical code track as claimed in claim 2 , wherein: in that the absolute coding is embodied as an aperture stop with continuous variation of code heights of adjacent code elements. 5. The optical code track as claimed in claim 2 , wherein: in that the absolute coding is embodied as a point grid with continuous variation of point densities of adjacent code elements. 6. The optical code track as claimed in claim 2 , wherein: in that the absolute coding is embodied as a polarizer with continuous variation of polarization efficiencies of adjacent code elements. 7. The optical code track as claimed in claim 6 , wherein: in that use is made of a polarizer which scatters light; or reflects light; or absorbs light; or is birefringent in the case of light. 8. The optical code track as claimed in claim 7 , wherein the optical code track comprises a coating whereby: the coating, at least in regions, has a constant optical density; and/or the coating, at least in regions, has a varying optical density. 9. The optical code track as claimed in claim 8 , wherein the coating, at least in regions, has a constant thickness. 10. The optical code track as claimed in claim 8 , wherein the coating, at least in regions, has a varying thickness. 11. The optical code track as claimed in claim 2 , wherein: in that the code elements have a constant code element width; and/or in that the code elements have a constant code element height. 12. A system for use in the method as claimed in claim 1 , wherein: the system comprises an absolute encoder including an optical sensor and an optical code track; the sensor is embodied for registering the light modulated with continuous variation at adjacent code elements in the direction of extent of the code track; and in that—on the basis of an output signal generated by the sensor when registering the light—state signals and, for the state signals, respectively one main point or centroid and the positions thereof are established by the absolute encoder and an absolute position value is derived therefrom. 13. The system as claimed in claim 12 , wherein the absolute encoder comprises an absolute rotary encoder or an absolute linear position encoder. 14. The system as claimed in claim 12 , wherein the absolute position value comprises an absolute angle or an absolute linear position. 15. The system as claimed in claim 12 , wherein: a sensor width of the sensor is equal to or greater than a sum of a code element width and a code element spacing of the code elements. 16. The system as claimed in claim 12 , wherein: a sensor height of the sensor is equal to or greater than a code element height of the code elements. 17. The system as claimed in claim 16 , wherein: the optical code track has an eccentricity; and in that the sensor height of the sensor is equal to or greater than a sum of: the maximum code element height of the code elements; and a maximum height offset of the code projection relative to the sensor caused by the eccentricity of the optical code track at different locations. 18. A method for producing the optical code track as claimed in claim 2 , comprising: providing a mechanical support of the optical code track; applying a coating onto the mechanical support, at least in regions; and structuring code elements into the coating, which code elements respectively form a main point or centroid and modulate illuminating light, wherein in that the code elements are structured in such a way that illuminating light is modulated with a continuous variation at adjacent code elements in the direction of extent of the code track. 19. A method for producing the optical code track as claimed in claim 2 , comprising: providing a mechanical support of the optical code track; generating diffractive structures as the optical code track on the mechanical support, at least in regions; and structuring code elements into the diffractive structures, which code elements respectively form a main point or centroid and modulate illuminating light, in that the code elements are structured in such a way that illuminating light is modulated with a continuous variation at adjacent code elements in the direction of extent of the code track. 20. A non-transitory computer program product, stored on a machine-readable medium, comprising program code which is suitable for establishing an object position from absolute coding of an optical code track registered by a system as claimed in claim 12 when the program is loaded into, and executed on, a microprocessor of an evaluation unit.