Apparatus and method for transmitted light illumination for light microscopes and microscope system

The invention claimed is: 1. A transmitted light illumination apparatus for a light microscope with a microscope objective and a zoom body, wherein an effective entrance pupil of the microscope objective changes dependent on at least one of a type of objective, a zoom position and a microscope type, the apparatus comprising: a light source adapted to emit an illuminating light bundle, a holding device for holding a sample to be examined, and at least one diaphragm edge to trim the illuminating light bundle, wherein the diaphragm edge is arranged between the holding device and the light source, wherein the diaphragm edge extends transversely to an optical axis of said light microscope, which can be positioned in an operating state on the transmitted light illumination apparatus, wherein an optical path of illuminating light between the diaphragm edge and the holding device is free of beam-forming components, mechanical means for variable positioning of the diaphragm edge in a direction of the optical axis in dependence upon the effective entrance pupil of the objective, wherein a position of the diaphragm edge in the direction of the optical axis can be varied by the mechanical means for variable positioning irrespectively of a position of the diaphragm edge transversely to the optical axis, and wherein the position of the diaphragm edge in the direction of the optical axis is automatically set dependent on the type of objective, the zoom position and the microscope type. 2. The apparatus as defined in claim 1 , wherein means for variable positioning of the diaphragm edge in a direction transversely to the optical axis are provided in order to change the contrast. 3. The apparatus as defined in claim 1 , wherein the diaphragm edge is a linear diaphragm edge. 4. The apparatus as defined in claim 1 , wherein the diaphragm edge is an edge of a mechanical diaphragm. 5. The apparatus as defined in claim 1 , wherein the diaphragm edge is formed by an LCD array. 6. The apparatus as defined in claim 1 , wherein at least one further diaphragm is provided which is positioned directly next to the light source in order to vary an effective light area of the light source. 7. The apparatus as defined in claim 1 , wherein at least one further variably positionable diaphragm is provided between the holding device and the light source in order to trim the illuminating light bundle. 8. The apparatus as defined in claim 1 , wherein a carriage mechanism with a first carriage and a second carriage is provided to displace the diaphragm edge in the direction of the optical axis and in a direction transversely to the optical axis. 9. The apparatus as defined in claim 1 , wherein a first mechanical diaphragm and a second mechanical diaphragm are provided, the diaphragm edge is formed by an edge of the first mechanical diaphragm or by an edge of the second mechanical diaphragm, and for displacement of the diaphragm edge in the direction of the optical axis and in a direction transversely to the optical axis, a first carriage mechanism with a first carriage and a second carriage is provided for the first mechanical diaphragm and a second carriage mechanism with a third carriage and a fourth carriage is provided for the second mechanical diaphragm. 10. The apparatus as defined in claim 1 , wherein the diaphragm edge is configured to asymmetrically trim the illuminating light bundle. 11. The apparatus as defined in claim 1 , wherein the light source is a planar light source. 12. The apparatus as defined in claim 1 , wherein means for rotating the diaphragm edge about the optical axis are provided. 13. A transmitted light illumination method for a light microscope with a microscope objective and a zoom body, wherein an effective entrance pupil of the microscope objective changes dependent on at least one of a type of objective, a zoom position and a microscope type, in which a sample held by a holding device is subjected to illuminating light from a light source and in which an illuminating light bundle emitted from the light source is trimmed by a diaphragm edge arranged between the holding device and the light source, wherein an optical path of the illuminating light between the diaphragm edge and the holding device is free of beam-forming components, wherein the diaphragm edge extends transversely to an optical axis, and wherein a position of the diaphragm edge in a direction of the optical axis is automatically set dependent on type of objective, the zoom position and the microscope type. 14. The method as defined in claim 13 , wherein an absolute position of the diaphragm edge is determined before the start of a diaphragm positioning with at least one of: an optically and a mechanical measurement. 15. The method as defined in claim 13 , wherein the diaphragm edge is positioned in a direction transversely to the optical axis in order to set the contrast. 16. The method as defined in claim 13 , wherein a position of the diaphragm edge in a plane of the effective entrance pupil is determined by a) varying the position of the diaphragm edge in the direction of the optical axis of the objective, b) recording at least in part one microscope image for each position of the diaphragm edge in the direction of the optical axis, c) determining an illumination parameter for each microscope image, d) setting the position of the diaphragm edge in the direction of the optical axis, at which a course of the illumination parameter plotted against the position of the diaphragm edge in the direction of the optical axis has a predetermined characteristic, as a position of the diaphragm edge in the plane of the effective entrance pupil, and e) storing the set position. 17. The method as defined in claim 16 , wherein the illumination parameter is a measure for at least one of: an intensity gradient in a direction transversely to the diaphragm edge, an image contrast, a contrast range of the image, an image homogeneity and a shadow in the microscope image. 18. The method as defined in claim 16 , wherein for each microscope image a respective intensity gradient is determined as an illumination parameter, and the diaphragm edge is set to the position in the direction of the optical axis, at which a course of the intensity gradient plotted against the diaphragm edge's position in the direction of the optical axis has a zero passage. 19. The method as defined in claim 16 , wherein the microscope images are recorded with a digital camera and the illumination parameter intensity gradient is determined by evaluating data supplied by the digital camera. 20. The method as defined in claim 16 , wherein based on the illumination parameter which was determined for a previous position of the diaphragm edge in the direction of the optical axis, a next following position of the diaphragm edge in the direction of the optical axis is determined, wherein the next following position is spaced further apart from the previous position as an absolute value of the illumination parameter increases, and a direction in which the next following position is spaced apart from the previous position is determined from a +/− symbol of the illumination parameter determined for the previous position. 21. The method as defined in claim 13 , wherein the method comprises adapting a light area of the light source to an actually effective back-projection of the illuminating light.