Abstract: A method and an arrangement for producing a workpiece using additive manufacturing techniques involve pre-process, in-process and post-process measurement in order to determine individual characteristics of one or more workpiece layers. In particular, dimensional and/or geometrical characteristics of a workpiece layer are measured before the next workpiece layer is produced. Advantageously, production parameters are controlled in response to individual material characteristics determined prior to the production process. Also advantageously, measurement results are fed back into a production process in order to increase accuracy, reliability, repeatability and precision of the production process.

Abstract: A lab-on-a-chip system (100) comprises an optical detection waveguide (122) that has an at least partially periodic structure (123, 501, 502, 503, 504) that is configured to couple light (152) from surroundings of the optical detection waveguide (122) into the optical detection waveguide (122). The lab-on-a-chip system (100) furthermore also comprises a microfluidic network (212), wherein the microfluidic network (212) has multiple lines and at least one reaction chamber (211, 211-1, 211-2, 211-3).

Abstract: A method for additive manufacturing includes obtaining a dataset that defines the workpiece in multiple workpiece layers arranged one on top of the other. A layer stack of multiple workpiece layers is produced based on the dataset. The layer stack has a respective topmost workpiece layer at a defined instant of time. The layer stack is thermally excited at the defined instant of time and a sequence of images of the respective topmost workpiece layer is recorded. The layer stack is inspected using the sequence of images. The inspection involves evaluation of an individual temporal deformation profile of the respective topmost workpiece layer in response to the thermal excitation. The individual temporal deformation profile has multiple characteristic features including an individual deformation increase, an individual deformation maximum, and an individual deformation decrease. The inspection result is determined by evaluating at least one of the characteristic features.

Abstract: Methods and devices for additive manufacturing of workpieces are provided. For analysis during production, a test is carried out using a selected test method. The test results are compared with simulated test results derived during a simulation of the manufacturing and testing. The test may use one or more of a laser ultrasound test unit, an electronic laser speckle interferometry test unit, an infrared thermography test unit, or an x-ray test unit.

Abstract: A device for additive manufacturing of a workpiece includes a production platform supporting a defined material layer of particulate material, a structuring tool, an inspection sensor, a control unit, and a position encoder. The inspection sensor has a line scan camera and a line light source and is movable along a movement direction relative to the production platform. The position encoder generates a position signal representing a respective instantaneous position of the inspection sensor relative to the production platform. The control unit generates a spatially resolved image of the defined layer using the line light source, the line scan camera, and the position signal. The control unit controls the structuring tool in order to produce a defined workpiece layer by selectively solidifying particulate material of the defined material layer based on the image of the defined material layer and/or an image of a previously produced workpiece layer.

Abstract: An optical system includes an illumination module configured to illuminate a sample object with at least one angle-variable illumination geometry. The optical system includes an imaging optical unit configured to produce an imaged representation of the sample object that is illuminated with the at least one angle-variable illumination geometry on a detector. The optical system includes the detector, which is configured to capture at least one image of the sample object based on the imaged representation. The optical system includes a controller configured to determine a result image based on a transfer function and the at least one image. A method includes illuminating a sample object with at least one angle-variable illumination geometry, imaging the sample object on a detector, based on the imaged representation, capturing at least one image of the sample object, and, based on a transfer function and the at least one image, determining a result image.

Abstract: An optical coherence tomography (OCT) system (63) is used to inspect bonding points (66A, 66B, 66C) sandwiched between two materials (layers 62, 64 of e.g. displays). The OCT differentiates between a bonding point, e.g. a weld, and air gaps between the two materials. The bonding points are identified as breaks in the air gap between the materials. By extracting various physical characteristics of the bonding points and the gap between the two materials, the present system determines whether the bonding is faulty.

Abstract: A process, in particular a 3D printing process, for producing a spectacle lens is disclosed. The process includes providing a coated substrate, providing a three-dimensional model of the spectacle lens, digitally cutting the three-dimensional model into individual two-dimensional layers, providing at least one printing ink, typically a 3D printing ink, building up the spectacle lens from the sum of the individual two-dimensional layers with a printing operation on the substrate, and hardening of the spectacle lens. The hardening can take place completely or partially after application of individual volume elements or after application of a layer, and the partial hardening can be completed after conclusion of the printing process.

Abstract: A refractive optical component has a main body with a plurality m of optical layers extending between a front side and a back side, each layer having a thickness, wherein each of the layers extends over a region common to all layers, the common region being greater than the maximum thickness of the respective layer by at least a factor of 10, wherein the thickness of the layers varies over the extent thereof transversely to the principal axis, and wherein the main body has a refractive index curve (n=n(x, y, z)), modulated at least in the direction parallel to the principal axis, with a plurality of maxima and minima, a distance between adjacent maxima and minima ranging between 0.5 ?m and 100 ?m and a refractive index difference ?n between adjacent maxima and minima ranging between 10?4 and 0.3.

Abstract: A refractive optical component has a main body with a plurality m of optical layers extending between a front side and a back side, each layer having a thickness, wherein each of the layers extends over a region common to all layers, the common region being greater than the maximum thickness of the respective layer by at least a factor of 10, wherein the thickness of the layers varies over the extent thereof transversely to the principal axis, and wherein the main body has a refractive index curve (n=n(x, y, z)), modulated at least in the direction parallel to the principal axis, with a plurality of maxima and minima, a distance between adjacent maxima and minima ranging between 0.5 ?m and 100 ?m and a refractive index difference ?n between adjacent maxima and minima ranging between 10?4 and 0.3.

Abstract: An optical coherence tomography (OCT) system (63) is used to inspect bonding points (66A, 66B, 66C) sandwiched between two materials (layers 62, 64 of e.g. displays). The OCT differentiates between a bonding point, e.g. a weld, and air gaps between the two materials. The bonding points are identified as breaks in the air gap between the materials. By extracting various physical characteristics of the bonding points and the gap between the two materials, the present system determines whether the bonding is faulty.

Abstract: A method and an arrangement for producing a workpiece using additive manufacturing techniques involve pre-process, in-process and post-process measurement in order to determine individual characteristics of one or more workpiece layers. In particular, dimensional and/or geometrical characteristics of a workpiece layer are measured before the next workpiece layer is produced. Advantageously, production parameters are controlled in response to individual material characteristics determined prior to the production process. Also advantageously, measurement results are fed back into a production process in order to increase accuracy, reliability, repeatability and precision of the production process.

Abstract: The invention relates to an apparatus and a method for determining a defocussing value (?z, ?z1, ?z2) for at least one image feature in an image, wherein at least one monochromatic image of an object is generated, wherein the defocussing value (?z, ?z1, ?z2) is determined on the basis of the image and depending on the wavelength (?) of the monochromatic image, and a method and apparatus for image-based determination of a dimensional size.

Abstract: Methods and devices for additive manufacturing of workpieces are provided. For analysis during production, a test is carried out using a selected test method. The test results are compared with simulated test results derived during a simulation of the manufacturing and testing. The test may use one or more of a laser ultrasound test unit, an electronic laser speckle interferometry test unit, an infrared thermography test unit, or an x-ray test unit.

Abstract: A spectacle lens contains, starting from the object-sided front surface of the spectacle lens to the opposite rear-side of the spectacle lens, at least a) one component A including an ultrathin glass, b) one component B including at least one polymer material and/or at least one mineral glass, c) one component C, including at least one functional layer and/or an ultra-thin glass. A method for producing such a spectacle lens is also disclosed.

Abstract: An optical system includes an illumination module configured to illuminate a sample object with at least one angle-variable illumination geometry. The optical system includes an imaging optical unit configured to produce an imaged representation of the sample object that is illuminated with the at least one angle-variable illumination geometry on a detector. The optical system includes the detector, which is configured to capture at least one image of the sample object based on the imaged representation. The optical system includes a controller configured to determine a result image based on a transfer function and the at least one image. A method includes illuminating a sample object with at least one angle-variable illumination geometry, imaging the sample object on a detector, based on the imaged representation, capturing at least one image of the sample object, and, based on a transfer function and the at least one image, determining a result image.

Abstract: A process, in particular a 3D printing process, for producing a spectacle lens is disclosed. The process includes providing a coated substrate, providing a three-dimensional model of the spectacle lens, digitally cutting the three-dimensional model into individual two-dimensional layers, providing at least one printing ink, typically a 3D printing ink, building up the spectacle lens from the sum of the individual two-dimensional layers with a printing operation on the substrate, and hardening of the spectacle lens. The hardening can take place completely or partially after application of individual volume elements or after application of a layer, and the partial hardening can be completed after conclusion of the printing process.

Abstract: A spectacle lens contains, starting from the object-sided front surface of the spectacle lens to the opposite rear-side of the spectacle lens, at least a) one component A including an ultrathin glass, b) one component B including at least one polymer material and/or at least one mineral glass, c) one component C, including at least one functional layer and/or an ultra-thin glass. A method for producing such a spectacle lens is also disclosed.

Abstract: A method of operating a projection exposure tool for microlithography is provided. The projection exposure tool has a projection objective for imaging object structures on a mask into an image plane using electromagnetic radiation, during which imaging the electromagnetic radiation causes a change in optical properties of the projection objective.

Abstract: An illumination optical unit for microlithography illuminates an object field with illumination light. The unit includes a first facet mirror that has a plurality of first facets, and a second facet mirror that has a plurality of second facets. The unit has facet pairs which include respectively a facet of the first facet mirror and a facet of the second facet mirror which predefine a plurality of illumination channels for illuminating the object field. At least some of the illumination channels have in each case an assigned polarization element for predefining an individual polarization state of the illumination light guided in the respective illumination channel.