Method and device for determining the position of an optical boundary surface along a first direction

What is claimed is: 1. A method for determining a position of an optical boundary surface along a first direction, the method comprising: a) imaging a pattern in a plane transverse to the first direction, wherein the pattern varies periodically in the plane in a second direction; b) recording a two-dimensional image of the pattern imaged in the plane transverse to the first direction; c) repeating step b) for a plurality of different positions in the first direction, wherein the plurality of different positions cover an area in the first direction in which the optical boundary surface lies; d) averaging each image from step b) along a direction transverse to the second direction such that in each case a one-dimensional data set is produced; e) transforming each data set from step d) into a frequency domain; f) determining the frequency of the greatest amplitude of all data sets transformed in step e); and g) determining the position of the optical boundary surface along the first direction by evaluating the data sets transformed in step e) at the frequency determined in step f). 2. The method according to claim 1 , wherein the pattern in step a) only varies periodically in the second direction. 3. The method according to claim 1 , wherein the pattern in step a) is a strip grating. 4. The method according to claim 1 , wherein, in step e), a discrete Fourier transform is performed. 5. The method according to claim 4 , wherein, in step g), an approximation is performed using a cubic polynomial function. 6. The method according to claim 1 , wherein, in step g), an approximation is performed using a cubic polynomial function. 7. The method according to claim 1 , wherein the optical boundary surface is a boundary surface of a specimen slide and, in step g), a spherical aberration caused by the specimen slide is corrected. 8. The method according to claim 1 , wherein, with steps b) g), the position of two optical boundary surfaces, and from this the distance between the two optical boundary surfaces, is determined. 9. The method according to claim 1 , wherein, in step f), the frequency is determined via a parabolic fit. 10. The method according to claim 1 , wherein, in step d), the direction transverse to the second direction is determined with reference to the respective image. 11. A device for determining the position of an optical boundary surface along a first direction, comprising: an illuminating module for imaging a pattern in a plane transverse to the first direction; an imaging module for recording the image of the pattern imaged in the plane; and a controller which is configured to perform at least the following steps: a) imaging the pattern in the plane transverse to the first direction, wherein the pattern varies periodically in the plane in a second direction; b) recording a two-dimensional image of the pattern imaged in the plane transverse to the first direction; c) repeating step b) for a plurality of different positions in the first direction, wherein the plurality of different positions cover an area in the first direction in which the optical boundary surface lies; d) averaging each image from step c) along a direction transverse to the second direction such that in each case a one-dimensional data set is produced; e) transforming each data set from step d) into a frequency domain; f) determining the frequency of the greatest amplitude of all data sets transformed in step e); and g) determining the position of the optical boundary surface along the first direction by evaluating the data sets transformed in step e) at the frequency determined in step f). 12. A device for determining the position of an optical boundary surface along a first direction, comprising: an optics that images a pattern in a plane transverse to the first direction; a camera to record the image of the pattern imaged in the plane; and a controller that is configured to perform the following steps: a) imaging the pattern in the plane transverse to the first direction, wherein the pattern varies periodically in the plane in a second direction; b) recording a two-dimensional image of the pattern imaged in the plane transverse to the first direction; c) repeating step b) for a plurality of different positions in the first direction, wherein the plurality of different positions cover an area in the first direction in which the optical boundary surface lies; d) averaging each image from step c) along a direction transverse to the second direction such that in each case a one-dimensional data set is produced; e) transforming each data set from step d) into a frequency domain; f) determining the frequency of the greatest amplitude of all data sets transformed in step e); and g) determining the position of the optical boundary surface along the first direction by evaluating the data sets transformed in step e) at the frequency determined in step f). 13. The device of claim 12 , wherein the optics is disposed in an imaging pathway between the pattern and an objective of a microscope. 14. The method according to claim 1 , wherein prior to step a), the method comprises placing the pattern in an imaging pathway such that an optics for imaging is disposed between the pattern and an objective of a microscope. 15. The device of claim 11 , wherein the illumination module is disposed in an imaging pathway between the pattern and an objective of a microscope.