Multi-layer body

The invention claimed is: 1. A multi-layer body comprising: a first layer having a multiplicity of opaque and/or reflective first zones, which are respectively separated from one another by one or a plurality of transparent second zones, wherein the first zones are shaped as micro images having a smallest dimension of less than 100 μm and are arranged in accordance with a micro image grid having a distance between adjacent micro images in a first spatial direction of less than 300 μm, wherein the micro image grid spans a first coordinate system having a coordinate axis x 1 and a coordinate axis y 1 at right angles thereto; a second layer composed of a transparent material, said second layer being arranged below the first layer; and a reflection layer arranged below the second layer, wherein the second layer has a multiplicity of third zones, which are respectively separated from one another by one or a plurality of transparent fourth zones, each of the third zones having a microstructure impressed into the interface—facing away from the first layer—between the second layer and the reflection layer, which is covered with the reflection layer, and the reflection layer is not provided in the one or plurality of transparent fourth zones, and wherein each of the microstructures is configured such that it reflects back and/or diffracts back light incident perpendicularly with respect to the plane spanned by the first layer from the direction of the first layer in the region of the respective third zone onto a focus region of the first layer, the focus region having an area smaller than the area of the respective third zone by at least a factor of 10, and wherein the microstructures are arranged in accordance with a microstructure grid having a distance between adjacent microstructures in a second spatial direction of less than 300 μm, which microstructure grid spans a second coordinate system having a coordinate axis x 2 and a coordinate axis y 2 at right angles thereto, and wherein, in a first region of the multi-layer body, the microimages of the microimage grid and the microstructures of the microstructure grid are arranged in overlapping fashion in a fixed position with respect to one another and the microstructure distance determined by the distance between the area centroids of adjacent third zones and the microimage distance determined by the distance between the area centroids of adjacent first zones differ from one another in at least one third spatial direction in the first region by not more than 10%, and wherein, in the first region, the area occupied by the first zones is smaller than the area occupied by the third zones by at least a factor of 4, and wherein at least one of the micro image grid and the microstructure grid is a one-dimensional grid in the first region, and wherein the longitudinal axis of the micro images is extended relative to the transverse axis of the micro images by more than 10-fold by a transformation function. 2. The multi-layer body as claimed in claim 1 , wherein, in the first region, the area proportion constituted by the first zones in the total area of the first and second zones is between 20% and 10%. 3. The multi-layer body as claimed in claim 1 , wherein, in the first region, the area occupied by the first zones is smaller than the area occupied by the third zones at least by a factor of 10 to 20. 4. The multi-layer body as claimed in claim 1 , wherein, in the first region, the layer thickness of the second layer is between 5 and 150 μm. 5. The multi-layer body as claimed in claim 1 , wherein, in the first region, the reflection layer is at a distance from the first layer of between 5 and 150 μm. 6. The multi-layer body as claimed in claim 1 , wherein the microstructures are embodied in each case such that they reflect back and/or diffract back light incident perpendicularly with respect to the plane spanned by the first layer from the direction of the first layer in the region of the respective third zones onto a region of the first layer whose area is between 15 and 2500 times smaller, than the area of the respective third zone. 7. The multi-layer body as claimed in claim 1 , wherein the microstructures are diffractive structures having a spatial frequency of more than 300 lines/mm. 8. The multi-layer body as claimed in claim 1 , wherein the microstructures are in each case kinoforms. 9. The multi-layer body as claimed in claim 1 , wherein the spatial frequency of the microstructures has a minimum in the region of the area centroid of the respective third zones and the spatial frequency of the microstructure increases in at least one spatial direction proceeding from the area centroid. 10. The multi-layer body as claimed in claim 1 , wherein the flank inclination of that flank of the structure elements of the microstructure which is oriented in relation to the area centroid of the respective third zone increases in at least one spatial direction proceeding from the area centroid. 11. The multi-layer body as claimed in claim 1 , wherein the local structure depth with which the microstructure is impressed into the second layer decreases in at least one spatial direction proceeding from the area centroid of the respective third zones. 12. The multi-layer body as claimed in claim 1 , wherein the first layer is formed by a metal layer, wherein the metal of the metal layer is provided in the first zones and is not provided in the second zones. 13. The multi-layer body as claimed in claim 1 , wherein a first diffractive surface structure is impressed in the lower interface—oriented toward the second layer—of the first layer in the first zones. 14. The multi-layer body as claimed in claim 13 , wherein a second diffractive surface structure, which differs from the first diffractive surface structure, is impressed in the second zones. 15. The multi-layer body as claimed in claim 1 , wherein the first layer consists of one or a plurality of partial layers, selected from the group comprising metal layer, HRI layer, replication lacquer layer, colored photoresist layer and color layer. 16. The multi-layer body as claimed in claim 1 , wherein a third diffractive surface structure is impressed into the upper interface—facing away from the second layer—of the first layer or a partial layer of the first layer in the first zones. 17. The multi-layer body as claimed in claim 16 , wherein the third surface structure is formed by a surface structure having a depth-to-width ratio of the structure elements of more than 0.5 and a spatial frequency of more than 2000 lines/mm. 18. The multi-layer body as claimed in claim 1 , wherein a fourth layer is provided between the first and second layers, which is translucent or colored. 19. The multi-layer body as claimed in claim 1 , wherein the coordinate axis y 1 and the coordinate axis y 2 and also the coordinate axis x 1 and the coordinate axis x 2 are respectively oriented parallel to one another in the first region and, in the first region, the microstructure distance and the microimage distance between adjacent microstructures and microimages differs by between 0.5 and 10% in the direction of at least one coordinate axis. 20. The multi-layer body as claimed in claim 1 , wherein the coordinate axis y 1 and the coordinate axis y 2 and also the coordinate axis x 1 and the coordinate axis x 2 respectively form an angle of between 0.01° and 5° in the first region. 21. The multi-layer body as claimed in claim 1 , wherein the grid pi