Abstract: A distance determination system for a microscope system for coarse focus setting includes a sample stage with a placement surface for holding a displaceable sample carrier, an overview camera with a non-telecentric objective for producing digital images, directed at the sample stage, and an evaluation unit, which includes a storage system storing at least two recorded digital images of the sample stage at different viewing angles, a trained machine-learning-based system for identifying corresponding structures of a sample carrier in the sample stage in the two recorded digital images and a distance determination unit, which determines the distance of a reference point of the sample carrier from a reference point of the overview camera based on the different viewing angles onto the sample stage, a pixel distance of the two recorded digital images with respect to one another using the associated corresponding structures contained in the recorded images.

Abstract: A semiconductor lithography projection exposure apparatus includes a sensor reference including reference elements. The apparatus also includes an optical element, which includes a main body comprising receiving elements receiving the reference elements. The optical element further includes a referential surface that is an optically active surface of the optical element. The reference elements are arranged to determine a position and an orientation of the optical element. A method includes aligning a sensor reference with respect to a referential surface in a semiconductor lithography projection exposure apparatus.

Abstract: The invention relates to an optical arrangement and a method for correcting centration errors and/or angle errors in a beam path. The beam path here comprises an optical compensated system in which at least two optical elements are present and aligned relative to one another such that imaging aberrations of the optical elements are compensated. According to the invention, a correction unit is arranged in an infinity space of the beam path and between the at least two optical elements, wherein the correction unit changes the propagation direction of radiation propagating along the beam path and the correction unit either has a reflective surface or is embodied to be transmissive for the radiation. The correction unit is movable such that the angle of a change in the propagation direction can be set.

Abstract: An optical lens contains a laminated film, which includes a first adhesive layer, a first barrier layer, a photochromic layer, a second barrier layer, and a second adhesive layer. The layers are arranged in succession and the laminated film is substantially incorporated into the optical lens body. A method for producing this optical lens as well as a pair of spectacles containing this optical lens are also disclosed.

Abstract: Techniques in connection with the use of a multi-pixel polarization filter in the light-microscopic examination of a sample object are described. In this way e.g. a particle analysis can be carried out, e.g. in particular for determining the technical cleanness of a surface of the sample object.

Abstract: The invention relates to a gas reservoir (3000) for receiving a precursor (3035). The gas reservoir (3000) has a gas-receiving unit (3004) which is arranged in a first receiving unit (3002) of a basic body (3001), and a sliding unit (3007) which is arranged movably in a second receiving unit (3003) of the basic body (3001). The gas-receiving unit (3004) has a movable closure unit (3006) for opening or closing a gas outlet opening (3005) of the gas-receiving unit (3004). In a first position of the sliding unit (3007), both a first opening (3009) of a sliding-unit line device (3008) is fluidically connected to a first basic body opening (3011) and a second opening (3010) of the sliding-unit line device (3008) is fluidically connected to a second basic body opening (3012). In the second position of the sliding unit (3007), both the first opening (3009) is arranged at an inner wall (3015) of the second receiving unit (3003) and the second opening (3010) is arranged at the movable closure unit (3006).

Abstract: A method for producing a coating on a surface of a coated or uncoated spectacle lens includes: applying a masking on a partial region of the surface of the coated or uncoated spectacle lens, applying at least one layer on the surface, and removing the masking and the at least one layer applied on the masking from the partial region of the surface. The masking is applied with a matrix printing method. A spectacle lens produced by the method is also disclosed.

Abstract: An apparatus is for localizing brain tissue regions connected with a brain function in a brain operating field. The apparatus includes a stimulation apparatus and a localization unit with a camera. The stimulation apparatus is configured to carry out a number of stimulation cycles. Each cycle includes a stimulation phase during which the brain function is stimulated and a rest phase during which there is no stimulation of the brain function. The localization unit records at least one stimulation image with the stimulated brain function and at least one reference image without the stimulated brain function during each stimulation cycle and uses the recorded stimulation and reference images to localize the brain tissue regions connected with the stimulated brain function. The stimulation apparatus is configured to output a feedback signal to the localization unit with at least the start of a stimulation cycle being evident from the feedback signal.

Abstract: An apparatus for ascertaining a distance to an object has a light source unit for emitting an optical signal with a time-varying frequency, an evaluation device for ascertaining a distance to the object based on (a) a measurement signal that arose from the signal and was reflected at the object and (b) a reference signal that was not reflected at the object. The apparatus has also a dispersive element disposed in the signal path of the optical signal and an optical position sensor disposed downstream of this dispersive element in the signal path.

Abstract: A computer-implemented method for generating data to produce a spectacle lens adapted to a spectacle frame is disclosed. The method includes: (i) providing, on a storage medium, a first data set containing a centering value and a three-dimensional model of the spectacle frame; (ii) creating, using the first data set, a second data set containing a geometric value of a surface of the spectacle lens; (iii) creating, in order to produce the spectacle lens from a spectacle lens blank and to grind in and/or fit the at least one spectacle lens into the spectacle frame using the first and second data sets, a third data set stored on the storage medium, wherein the data values of each data set have a spatial relationship with respect to each other such that the data values of each data set are consistently specified in relation to a particular coordinate system.

Abstract: Methods and devices for determining at least one centring parameter are disclosed. A mobile terminal is moved from a first position to a second position, and a respective image is captured of an eye area of a person. The acceleration is also measured during the movement. The centring parameter is then determined based on the captured image and the measured acceleration.

Abstract: A progressive spectacle lens has a front face and a rear face and a uniform substrate with a locally varying refractive index. The front face and/or the rear face of the substrate is formed as a free-form surface and carries only functional coatings, if any. The refractive index varies (a) only in a first spatial dimension and in a second spatial dimension and is constant in a third spatial dimension, a distribution of the refractive being neither point-symmetrical nor axis symmetrical, or (b) in a first spatial dimension and in a second spatial dimension and in a third spatial dimension, a distribution of the refractive index being neither point-symmetrical nor axis symmetrical, or (c) in a first spatial dimension and in a second spatial dimension and in a third spatial dimension, a distribution of the refractive index not being point-symmetrical or axis symmetrical at all.

Abstract: Provided is an intraocular lens having an optical body and having at least one haptic element coupled to the optical body, wherein the at least one haptic element has a first haptic component and at least a second haptic component formed adjacent thereto, which is movable elastically relative to the first haptic component, and having a principal optical axis that penetrates through a front side and a reverse side of the optical body, wherein the haptic element, measured in the direction of the principal optical axis, has a maximum of a first height, wherein the second haptic component is displaceable relative to the first haptic component from a non-spread position to a spread position in such a way that the haptic element, measured in the direction of the principal optical axis, attains a maximum of a second height which is greater than the first height, and, in the spread position, the second haptic component can be locked in place relative to the first haptic component, wherein the first haptic component h

Abstract: A sealing device seals a first component part of a lithography apparatus vis-à-vis a multiplicity of second component parts of the lithography apparatus. The sealing device includes a multiplicity of sealing rings and a multiplicity of connection locations. The sealing rings are connected to one another with the aid of the connection locations.

Abstract: The present application relates to a scanning probe microscope comprising a probe arrangement for analyzing at least one defect of a photolithographic mask or of a wafer, wherein the scanning probe microscope comprises: (a) at least one first probe embodied to analyze the at least one defect; (b) means for producing at least one mark, by use of which the position of the at least one defect is indicated on the mask or on the wafer; and (c) wherein the mark is embodied in such a way that it may be detected by a scanning particle beam microscope.

Abstract: A method for operating a multi-beam particle beam microscope includes: scanning a multiplicity of particle beams over an object; directing electron beams emanating from impingement locations of the particle beams at the object onto an electron converter; detecting first signals generated by impinging electrons in the electron converter via a plurality of detection elements of a first detection system during a first time period; detecting second signals generated by impinging electrons in the electron converter via a plurality of detection elements of a second detection system during a second time period; and assigning to the impingement locations the signals which were detected via the detection elements of the first detection system during the first time period, for example on the basis of the detection signals which were detected via the detection elements of the second detection system during the second time period.

Abstract: An apparatus includes a light intensity sensor arrangement, a focusing unit for focusing the light beam at a specified location on the light intensity sensor arrangement, and an adjustment unit which adjusts a relative position of the intensity centroid of the light beam in relation to a specified location on the light intensity sensor arrangement when there is a change in the beam angle present upon entry in the apparatus. The adjustment unit is configured to keep the relative position of the intensity centroid of the light beam in relation to the specified location on the light intensity sensor arrangement constant up to a specified maximum deviation. The maximum deviation corresponds to half the mean beam diameter upon incidence on the light intensity sensor arrangement.

Abstract: A device for performing an ophthalmic procedure in an eye including a hand-held portion; an elongate member extending from a distal end region of the hand-held portion; and an aspiration pump within the hand-held portion. The elongate member includes a lumen and an opening near a distal end region of the elongate member. The aspiration pump is in fluid communication with the opening of the elongate member. The aspiration pump includes a camshaft extending along a longitudinal axis and having a plurality of lobed cams; tubing extending parallel to the longitudinal axis; and a plurality of cam followers driven by the cams of the camshaft to move in a plane perpendicular to the longitudinal axis to sequentially compress the tubing. Related devices, systems, methods are provided.

Abstract: The present application describes the addition of various feedback mechanisms including visual and audio feedback mechanisms to an ophthalmic diagnostic device to assist a subject to self-align to the device. The device may use the visual and non-visual feedback mechanisms independently or in combination with one another. The device may provide a means for a subject to provide feedback to the device to confirm that an alignment condition has been met. Alternatively, the device may have a means for sensing when acceptable alignment has been achieved. The device may capture diagnostic information during the alignment process or may capture after the alignment condition has been met.

Abstract: The invention relates to a method for producing a sample on an object using a material processing device. The invention further relates to a computer program product and a material processing device for carrying out the method.