Abstract: An objective for a microscope includes a displaceable lens group for correcting a spherical aberration. The displaceable lens group is designed in so that an offset of same in the direction perpendicular to the optical axis leads to only a small coma.

Abstract: An object transfer function for a sample object is determined on the basis of a reference measurement. Subsequently, an optimization is carried out in order to find an optimized illumination geometry on the basis of the object transfer function and an optical transfer function for an optical unit.

Abstract: An objective for a microscope includes a displaceable lens group for correcting a spherical aberration. The displaceable lens group is designed in so that an offset of same in the direction perpendicular to the optical axis leads to only a small coma.

Abstract: An object transfer function (201) for a sample object is determined on the basis of a reference measurement. Subsequently, an optimization (250) is carried out in order to find an optimized illumination geometry on the basis of the object transfer function and an optical transfer function (202) for an optical unit.

Abstract: The invention relates to a system for spherically correcting imaging of a three-dimensional object, comprising a microscope comprising an immersion medium and an embedding medium for holding the three-dimensional object separated from the immersion medium of the microscope by a boundary surface or a cover slip. According to the invention, the thickness (?s) of the immersion medium and the position (?s?) of the primary intermediate image of the three-dimensional object can be variably modified.

Abstract: An apochromatic microscope objective, including three optical sub-systems, wherein starting from the object plane, the first sub-system includes a meniscus and a convergent lens, wherein the meniscus is curved towards the object plane, the second sub-system is made up of three elements, wherein a first element includes a meniscus or a cemented element, a second element is configured as a collecting cemented element and a third element is a cemented element, and wherein either the first element or the third element is strongly scattering and the third sub-system has at least one cemented element with a collecting lens.

Abstract: The invention relates to a system for spherically correcting imaging of a three-dimensional object, comprising a microscope comprising an immersion medium and an embedding medium for holding the three-dimensional object separated from the immersion medium of the microscope by a boundary surface or a cover slip. According to the invention, the thickness (?s) of the immersion medium and the position (?s?) of the primary intermediate image of the three-dimensional object can be variably modified.

Abstract: The invention relates to a high aperture immersion objective particularly for uses in confocal microscopes where oil is the immersion fluid, which objective is composed of three lenses and/or subsystems comprising lens groups. An apochromatic correction in a range from 365 to 900 nm is achieved at high resolving numeric apertures of 1.3 to 1.4 and an object field from 0.4 to 0.625 mm by the specification of the optical components. Additionally, the immersion objective has sufficiently good transparency up to a wavelength of 340 nm.

Abstract: An optical system for digital microscopy having at least one lens, at least one telescope of the Kepler type and tube optics, wherein an aperture is arranged between the telescope and the tube optics, which aperture is imaged by means of the telescope at the rear focal point of the lens and the following conditions are met simultaneously: A light conductance value (L) of the lens is ?1.4, A light conductance value (L) of the telescope is ?0.35, A light conductance value (L) of the tube optics is ?0.35, wherein the equation for the light conductance value (L) is L=A(tan ?,) where A is the pupil diameter and ? is the angle of gradient of the pencil of light rays in infinite space, and wherein the microscope magnification (?) of the telescope is in the range ??????3.

Abstract: A device for three-dimensional measurement of an object, with a stereomicroscope of the telescope type, which has a common objective and a first and a second tube lens, a first image sensor, which is assigned to the first tube lens, a second image sensor (8), which is assigned to the second tube lens, and a control unit, which determines the three-dimensional shape of the object from the images obtained with the two image sensors and carries out a predetermined three-dimensional measurement, wherein the stereomicroscope is designed such that the images are obtained with object-side telecentric conditions of the stereomicroscope.

Abstract: The invention relates to an optical inspecting system designed to image an object to be inspected with a variable imaging scale, comprising a variation system for imaging the object into infinity, a lens group downstream of the variation system for imaging the object from infinity into the image plane of the whole system, and a light source for generating light in order to illuminate the object, means for imaging the illuminating light into the exit pupil of the variation system being provided in the airspace between the fifth lens group and the subsequent lens group. Of the five lens groups of the variation system, the first, second, and fourth lens groups, when seen in the imaging direction, are arranged in a movable manner in the direction of the optical axis, whereas the third and fifth lens groups are not movable.

Abstract: An apochromatic microscope objective, including three optical sub-systems, wherein starting from the object plane, the first sub-system includes a meniscus and a convergent lens, wherein the meniscus is curved towards the object plane, the second sub-system is made up of three elements, wherein a first element includes a meniscus or a cemented element, a second element is configured as a collecting cemented element and a third element is a cemented element, and wherein either the first element or the third element is strongly scattering and the third sub-system has at least one cemented element with a collecting lens.

Abstract: The invention relates to a high aperture immersion objective particularly for uses in confocal microscopes where oil is the immersion fluid, which objective is composed of three lenses and/or subsystems comprising lens groups. An apochromatic correction in a range from 365 to 900 nm is achieved at high resolving numeric apertures of 1.3 to 1.4 and an object field from 0.4 to 0.625 mm by the specification of the optical components. Additionally, the immersion objective has sufficiently good transparency up to a wavelength of 340 nm.

Abstract: An optical system for digital microscopy having at least one lens, at least one telescope of the Kepler type and tube optics, wherein an aperture is arranged between the telescope and the tube optics, which aperture is imaged by means of the telescope at the rear focal point of the lens and the following conditions are met simultaneously: A light conductance value (L) of the lens is ?1.4, A light conductance value (L) of the telescope is ?0.35, A light conductance value (L) of the tube optics is ?0.

Abstract: A high-aperture immersion objective, in particular for confocal applications in fluorescence microscopy and for TIRF applications, having three subsystems of lenses and/or lens groups. The design of the subsystems has made it possible for a relatively large object field of 0.25 mm to be present in the case of a high-resolution numerical aperture of 1.49. Furthermore, improved transparency is possible up to a wavelength of 340 nm.

Abstract: The invention relates to an optical inspecting system designed to image an object to be inspected with a variable imaging scale, comprising a variation system for imaging the object into infinity, a lens group downstream of the variation system for imaging the object from infinity into the image plane of the whole system, and a light source for generating light in order to illuminate the object, means for imaging the illuminating light into the exit pupil of the variation system being provided in the airspace between the fifth lens group and the subsequent lens group. Of the five lens groups of the variation system, the first, second, and fourth lens groups, when seen in the imaging direction, are arranged in a movable manner in the direction of the optical axis, whereas the third and fifth lens groups are not movable.

Abstract: A device for three-dimensional measurement of an object, with a stereomicroscope of the telescope type, which has a common objective and a first and a second tube lens, a first image sensor, which is assigned to the first tube lens, a second image sensor (8), which is assigned to the second tube lens, and a control unit, which determines the three-dimensional shape of the object from the images obtained with the two image sensors and carries out a predetermined three-dimensional measurement, wherein the stereomicroscope is designed such that the images are obtained with object-side telecentric conditions of the stereomicroscope.

Abstract: A tube unit for microscopes which has a tube lens, including two components with an intermediate, large air separation, and an overall positive refractive power. The air separation is at least half the size of the focal length f of the tube lens. A roof edge mirror or another suitable deflection element is arranged between the two components of the tube lens. The roof edge mirror includes two mirrors, which can be tilted with respect to one another, and which is able to be tilted around its roof edge. The tilting movement or the tilting angle of the tiltable mirror or deflection element corresponds to half the tilt or half the tilting angle of the tube or eyepiece viewing system.

Abstract: A high-aperture immersion objective, in particular for confocal applications in fluorescence microscopy and for TIRF applications, having three subsystems of lenses and/or lens groups. The design of the subsystems has made it possible for a relatively large object field of 0.25 mm to be present in the case of a high-resolution numerical aperture of 1.49. Furthermore, improved transparency is possible up to a wavelength of 340 nm.

Abstract: A tube unit for microscopes which has a tube lens, including two components with an intermediate, large air separation and an overall positive refractive power. The air separation is at least half the size of the focal length f of the tube lens. A roof edge mirror or another suitable deflection element is arranged between the two components of the tube lens. The roof edge mirror includes two mirrors which can be tilted with respect to one another, and which is able to be tilted around its roof edge. The tilting movement or the tilting angle of the tiltable mirror or deflection element corresponds to half the tilt or half the tilting angle of the tube or eyepiece viewing system.