Method for computing holograms for holographic reconstruction of two-dimensional and/or three-dimensional scenes

The invention claimed is: 1. A method for calculating holograms for the holographic reconstruction of two-dimensional and/or three-dimensional scenes in a display apparatus, comprising decomposing a scene to be reconstructed into object points and encoding the object points as sub-holograms into at least one spatial light modulator device of the display apparatus, where a reconstructed scene is observed from a visibility region; determining at least one virtual plane of the at least one spatial light modulator device based on a real or physical plane of the spatial light modulator device, carrying out a calculation of sub-holograms in the at least one virtual plane of the at least one spatial light modulator device, and depending on the position of all object points of the scene to be reconstructed, the distance of the at least one virtual plane of the spatial light modulator device to the visibility region is selected such that the average size, preferably averaged over all object points, in form of a number of modulation elements of the sub-holograms to be calculated for the scene to be reconstructed takes a minimum value. 2. The method according to claim 1 , wherein the object points of the scene to be reconstructed are calculated as sub-holograms in the at least one virtual plane of the at least one spatial light modulator device, the calculated sub-holograms are transformed from the at least one virtual plane of the at least one spatial light modulator device into the visibility region by means of an integral transformation and are added up there, and the summed sub-holograms are transformed from the visibility region into the physical plane of the at least one spatial light modulator device by means of a further integral transformation and are written in as a hologram. 3. The method according to claim 1 , wherein the object points of the scene to be reconstructed are calculated as sub-holograms in the at least one virtual plane of the at least one spatial light modulator device and the sub-holograms are added up in the at least one virtual plane, the summed sub-holograms of the at least one virtual plane of the at least one spatial light modulator device are transformed into the visibility region by means of an integral transformation and are transformed from the visibility region into the physical plane of the at least one spatial light modulator device by means of a further integral transformation and are written in as a hologram. 4. The method according to claim 3 , wherein when at least two virtual planes of the at least one spatial light modulator device are determined, one of these virtual planes is each assigned to the object points of the scene to be reconstructed and the object points are calculated as sub-holograms in the virtual plane assigned to them and the sub-holograms of the object points assigned to the virtual plane are added up in each virtual plane, the summed sub-holograms are transformed from the at least two virtual planes into the visibility region by means of an integral transformation, the transforms of the at least two virtual planes are added up in the visibility region, and the total result of the summed transforms is transformed from the visibility region into the physical plane of the at least one spatial light modulator device by means of a further integral transformation and is written in as a hologram. 5. The method according to claim 3 , wherein when at least two virtual planes of the at least one spatial light modulator device are determined, one of these virtual planes is each assigned to the object points of the scene to be reconstructed and the object points are calculated as sub-holograms in the virtual plane assigned to them and the sub-holograms of the object points assigned to the virtual plane are added up in each virtual plane, the summed sub-holograms are transformed from the at least two virtual planes into the visibility region by means of an integral transformation, for each of the at least two virtual planes the corresponding transform is transformed from the visibility region into the real or physical plane of the at least one spatial light modulator device by means of a further integral transformation, the transforms of the at least two virtual planes are added up in the physical plane of the at least one spatial light modulator device, and the total result of the summed transforms is written in as a hologram. 6. The method according to claim 1 , wherein the transformation of the sub-holograms or the summed sub-holograms from a virtual plane into the visibility region or the further integral transformation from the visibility region into the physical plane of the spatial light modulator device is carried out by means of a one-dimensional integral transformation in the case of a single-parallax encoding or by means of a two-dimensional integral transformation in the case of a single-parallax encoding or a full-parallax encoding. 7. The method according to claim 1 , wherein the position of the at least one virtual plane of the spatial light modulator device is selected within the depth range of the scene to be reconstructed, where the depth range of the scene to be reconstructed is delimited by the object point having the smallest distance to the visibility region and the object point having the greatest distance to the visibility region. 8. The method according to claim 1 , wherein with respect to the depth range of the scene to be reconstructed, the position of the at least one virtual plane of the spatial light modulator device is selected such that the visible resolution during the reconstruction of the scene does not fall below a given value. 9. The method according to claim 1 , wherein the scene to be reconstructed is decomposed into at least two depth range sections, where one virtual plane of the spatial light modulator device is each assigned to the at least two depth range sections and the sub-holograms in the virtual plane assigned to the depth range section are calculated for all object points located within a depth range section. 10. The method according to claim 9 , wherein one virtual plane of the virtual planes of the spatial light modulator device, which are assigned to the at least two depth range sections, coincides with the physical plane of the spatial light modulator device. 11. The method according to claim 10 , wherein the adding up of the sub-holograms calculated for the physical plane of the spatial light modulator device is carried out either in the physical plane of the spatial light modulator device or in the visibility region. 12. The method according to claim 1 , wherein the individual object points of the scene to be reconstructed are encoded in form of sub-holograms on the physical plane of the spatial light modulator device as a lens element having different focal lengths in the horizontal direction and the vertical direction. 13. The method according to claim 1 , wherein the calculation of the sub-holograms in the at least one virtual plane of the spatial light modulator device is carried out by means of a two-dimensional full-parallax encoding or by means of a one-dimensional single-parallax encoding. 14. The method according to claim 1 , wherein depending on the depth range of the scene to be reconstructed, the number of the virtual planes of the spatial light modulator device as well as the distance of said virtual planes of the spatial light modulator device to the visibility region are selected such that the size in form of a number of modulation elements of the sub-holograms to be calculated for the scene to be reconstructed does not exceed a given value.