Method and device for checking refractive power distribution and centering

The invention claimed is: 1. A method for checking the centering of a spectacle lens mounted in a spectacle frame, the method comprising: arranging the spectacle lens in a measurement position; providing a test structure; capturing an actual image of the test structure with an imaging beam that passes through the spectacle lens arranged in the measurement position; and comparing at least one of: the captured actual image with a setpoint image of the test structure which would arise for an imaging beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be checked should have computationally on account of a design data on which the spectacle lens's production is based, or the captured actual image with a setpoint complement image complementary to a setpoint image of the test structure, wherein the setpoint image of the test structure is that image which would arise for an image beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be checked should have computationally on account of the design data on which its production is based, wherein the measurement position is a predefined setpoint measurement position of the spectacle frame with regard to location and orientation. 2. The method as claimed in claim 1 , wherein the test structure is calculated from the predefined setpoint image. 3. The method as claimed in claim 2 , wherein the test structure is calculated from the predefined setpoint image by a light ray tracing method. 4. The method as claimed in claim 1 , wherein the predefined setpoint measurement position of the spectacle frame with regard to location and orientation is determined from the coordinates of the centering point of the spectacle lens in the spectacle frame. 5. The method as claimed in claim 1 , wherein at least one of: the actual image and the setpoint image are displayed simultaneously, or the actual image and the setpoint complement image are displayed simultaneously. 6. The method as claimed in claim 5 , wherein at least one of: the actual image and the setpoint image are displayed alongside one another, the actual image and the setpoint image are displayed in a manner superimposed on one another, or the actual image and the setpoint complement image are displayed in a manner superimposed on one another. 7. The method as claimed in claim 5 , wherein at least one of: the actual image and the setpoint image are displayed in a manner brought to congruence, or the actual image and the setpoint complement image are displayed complementarily with respect to one another. 8. A device for checking the centering of a spectacle lens mounted in a spectacle frame, the device comprising: a holder configured to arrange the spectacle lens in a measurement position; a display unit configured to display a test structure; an image capture unit configured to capture an actual image of the test structure for an imaging beam which passes through the spectacle lens arranged in the measurement position; and at least one of: a comparison unit configured to compare the captured actual image with a setpoint image of the test structure, wherein the setpoint image of the test structure is that image which would arise for an imaging beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be checked should have computationally on account of the design data on which its production is based, or to compare the captured actual image with a setpoint complement image complementary to a setpoint image of the test structure, wherein the setpoint image of the test structure is that image which would arise for an imaging beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be checked should have computationally on account of the design data on which its production is based; or a display unit configured to simultaneously display the captured actual image and a setpoint image of the test structure, wherein the setpoint image of the test structure is that image which would arise for an imaging beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be checked should have computationally on account of the design data on which its production is based, or configured to simultaneously display the captured actual image and a setpoint complement image complementary to a setpoint image of the test structure, wherein the setpoint image of the test structure is that image which would arise for an imaging beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be checked should have computationally on account of the design data on which its production is based, wherein the holder is configured to hold the spectacle frame in a predefined setpoint measurement position with regard to location and orientation of the spectacle frame. 9. The device as claimed in claim 8 , wherein the holder has holding points, the position of which in space is previously known. 10. The device as claimed in claim 9 , wherein the holder has a compensation unit configured to compensate at least one of a forward inclination or a lateral inclination. 11. The device as claimed in claim 8 , wherein the holder is configured to hold spectacles, and wherein the holder comprises an interchange unit configured to sequentially check the centering of the right and left spectacle lenses of the spectacles. 12. The device as claimed in claim 8 , further comprising a displacement unit configured to displace the holder and the image capture unit relatively with respect to one another. 13. The device as claimed in claim 8 , further comprising a displacement unit configured to displace the holder and the display unit configured to display the test structure relative to one another. 14. A method for checking the centering of a spectacle lens mounted in a spectacle frame, the method comprising: arranging the spectacle lens mounted in the spectacle frame in a measurement position; providing a test structure; capturing an actual image of the test structure with an imaging beam which passes through the spectacle lens arranged in the measurement position; comparing at least one of: the captured actual image with a setpoint image of the test structure which would arise for an imaging beam passing through a spectacle lens arranged in a predefined setpoint measurement position with a predefined setpoint refractive power distribution, wherein the setpoint refractive power distribution is the refractive power distribution which the spectacle lens to be