Abstract: An optical system (10) for use in an underwater environment is proposed, wherein the optical system (10) comprises a housing which delimits an interior (60) of the optical system (10) with respect to the surroundings (50) in water-tight fashion, and a lens (20) with an outer surface (24), wherein the housing comprises a mount (40), wherein the lens (20) is received in the mount (40) in such a way that the outer surface (24) of the lens (20) is in fluid contact with water of the underwater environment when the optical system (10) is situated in the underwater environment, wherein the outer surface (24) of the lens (20) has an arched form, in particular a convex form, preferably a spherical convex form, wherein the lens (20) has a first arched contact face (28), in particular a spherical contact face, and the mount (40) has a second contact face (48), wherein the lens (20) is arranged in the mount (40) in such a way that the first contact face (28) presses against the second contact face (48) when the pressure

Abstract: Provided is a waveguide arrangement, comprising a diffractive input coupling element (11), in particular a volume hologram, a diffractive output coupling element (13), in particular a volume hologram, and optionally a beam expansion element (12), in particular a volume hologram. The expansion element (12) and the output coupling element (13) expand a light beam in different directions.

Abstract: An optical system (10) for use in an underwater environment is proposed, wherein the optical system (10) comprises a housing which delimits an interior (60) of the optical system (10) with respect to the surroundings (50) in water-tight fashion, and a lens (20) with an outer surface (24), wherein the housing comprises a mount (40), wherein the lens (20) is received in the mount (40) in such a way that the outer surface (24) of the lens (20) is in fluid contact with water of the underwater environment when the optical system (10) is situated in the underwater environment, wherein the outer surface (24) of the lens (20) has an arched form, in particular a convex form, preferably a spherical convex form, wherein the lens (20) has a first arched contact face (28), in particular a spherical contact face, and the mount (40) has a second contact face (48), wherein the lens (20) is arranged in the mount (40) in such a way that the first contact face (28) presses against the second contact face (48) when the pressure

Abstract: Provided is an optical arrangement comprising a stacked structure having at least three prisms. The optical arrangement also comprises a primary optical path and a secondary optical path for each of the prisms. The secondary optical path runs through the corresponding prism, is connected with the primary optical path by means of partial reflection of light, and is subject to total reflection at a further surface of the corresponding prism.

Abstract: An optical arrangement includes a stack structure comprising at least three prisms. The optical arrangement includes a main optical path and for each of the prisms, a secondary optical path. The optical arrangement also includes at least one interface. Each of the at least one interface is arranged between a corresponding first stack section of the stack structure and a corresponding second stack section of the stack structure. Each of the at least one interface is configured to enable relative movement of the corresponding first stack section and of the corresponding second stack section with respect to one another.

Abstract: Provided is a waveguide arrangement, comprising a diffractive input coupling element (11), in particular a volume hologram, a diffractive output coupling element (13), in particular a volume hologram, and optionally a beam expansion element (12), in particular a volume hologram. The expansion element (12) and the output coupling element (13) expand a light beam in different directions.

Abstract: An ophthalmic instrument for the application of laser radiation in a patient's eye, particularly for the examination and/or surgical laser treatment of the cornea and the lens of the eye, includes a femtosecond laser, an objective and optical assemblies. The optical assemblies are arranged in front of the objective, and selectively vary the focus position in the coordinate direction X, Y and Z either within the region of the cornea or within the region of the lens of the eye. The objective or at least one lens group is movable relative to the eye. The variation of the position of the lens group objective shifts the focus position from the cornea to the lens of the eye and vice versa.

Abstract: An optical arrangement includes a stack structure comprising at least three prisms. The optical arrangement includes a main optical path and for each of the prisms, a secondary optical path. The optical arrangement also includes at least one interface. Each of the at least one interface is arranged between a corresponding first stack section of the stack structure and a corresponding second stack section of the stack structure. Each of the at least one interface is configured to enable relative movement of the corresponding first stack section and of the corresponding second stack section with respect to one another.

Abstract: An ophthalmic instrument for the application of laser radiation in a patient's eye, particularly for the examination and/or surgical laser treatment of the cornea and the lens of the eye, includes a femtosecond laser, an objective and optical assemblies. The optical assemblies are arranged in front of the objective, and selectively vary the focus position in the coordinate direction X, Y and Z either within the region of the cornea or within the region of the lens of the eye. The objective or at least one lens group is movable relative to the eye. The variation of the position of the lens group objective shifts the focus position from the cornea to the lens of the eye and vice versa.

Abstract: An ophthalmic instrument for the application of laser radiation in a patient's eye, particularly for the examination and/or surgical laser treatment of the cornea and the lens of the eye, includes a femtosecond laser, an objective and optical assemblies. The optical assemblies are arranged in front of the objective, and selectively vary the focus position in the coordinate direction X,Y and Z either within the region of the cornea or within the region of the lens of the eye. The objective or at least one lens group is movable relative to the eye. The variation of the position of the lens group objective shifts the focus position from the cornea to the lens of the eye and vice versa.

Abstract: An ophthalmic instrument for the application of laser radiation in a patient's eye, particularly for the examination and/or surgical laser treatment of the cornea and the lens of the eye, includes a femtosecond laser, an objective and optical assemblies. The optical assemblies are arranged in front of the objective, and selectively vary the focus position in the coordinate direction X,Y and Z either within the region of the cornea or within the region of the lens of the eye. The objective or at least one lens group is movable relative to the eye. The variation of the position of the lens group objective shifts the focus position from the cornea to the lens of the eye and vice versa.

Abstract: An ophthalmic instrument for the application of laser radiation in a patient's eye, particularly for the examination and/or surgical laser treatment of the cornea and the lens of the eye, includes a femtosecond laser, an objective and optical assemblies. The optical assemblies are arranged in front of the objective selectively vary the focus position in the coordinate direction X,Y and Z either within the region of the cornea or within the region of the lens of the eye. The objective or at least one lens group is movable relative to the eye. The variation of the position of the lens group or objective shifts the focus position from the cornea to the lens of the eye and vice versa.

Abstract: An ophthalmic instrument for the application of laser radiation in a patient's eye, particularly for the examination and/or surgical laser treatment of the cornea and the lens of the eye, includes a femtosecond laser, an objective and optical assemblies. The optical assemblies are arranged in front of the objective, and selectively vary the focus position in the coordinate direction X,Y and Z either within the region of the cornea or within the region of the lens of the eye. The objective or at least one lens group is movable relative to the eye. The variation of the position of the lens group or objective shifts the focus position from the cornea to the lens of the eye and vice versa.

Abstract: The present invention is directed to a controllable microscope illumination within a microscope system by which all essential contrasting methods in microscopy can be realized. The illumination device according to the invention comprises a plurality of individual light sources which can be regulated with respect to brightness, wherein these individual light sources are formed as unit cells and form a luminous surface by a periodic arrangement. In an advantageous arrangement, imaging optics are associated with each individual light source in order to magnify the image of the source surface of the individual light source so that the images of the source surfaces of adjacent individual light sources touch. Illumination variants for all of the essential contrasting methods in microscopy can be generated by way of the proposed solution. The proposed LED illumination is electronically switchable, can be regulated with respect to brightness, supplies all colors, is long-lasting and economical.

Abstract: The present invention is directed to a controllable microscope illumination within a microscope system by which all essential contrasting methods in microscopy can be realized. The illumination device according to the invention comprises a plurality of individual light sources which can be regulated with respect to brightness, wherein these individual light sources are formed as unit cells and form a luminous surface by a periodic arrangement. In an advantageous arrangement, imaging optics are associated with each individual light source in order to magnify the image of the source surface of the individual light source so that the images of the source surfaces of adjacent individual light sources touch. Illumination variants for all of the essential contrasting methods in microscopy can be generated by means of the proposed solution. The proposed LED illumination is electronically switchable, can be regulated with respect to brightness, supplies all colors, is long-lasting and economical.

Abstract: The invention is directed to a device for changing objectives which are arranged in a work position in the optical axis of a beam path of an optical device at a distance from the object to be examined. The optical device has in particular a housing with a front surface and rear surface and side surfaces and focusing means for the objectives to be changed. Receptacles are provided which are connected to the housing of the device directly or by intermediate members and in which the objectives are arranged. The device comprises first means for the linear movement and/or combined rotational and swiveling movement of the receptacle in up to three coordinates, by which an objective can be positioned in the work position in the optical axis of the beam path of the device and outside the optical axis in a standby position.

Abstract: An electrochemical cell stack has alternately arranged membrane electrode assemblies (12) and separator plates (11) having channel regions (13) via which the reactant or oxidant fluids are supplied to and removed from the membrane electrode assembly (12), the separator plates (11), on one side, having a surface structure of channels (15) and ridges (14) located therebetween and, on the other side, having a surface structure which is negative with respect thereto.