A real-time calculation system capable of computing the industrial optical performance and yields of a prescription laboratory is disclosed. The system uses statistical analysis to determine the compensation factors that can be applied to given products, Semi-Finish, materials, or lens designs to increase the lab yields. Using a monitoring and configuration system, the user tracks the evolution of the laboratory's performance and identifies areas in which yields are impacted. The user defines how the calculation system will optimize the laboratory's performance, such as by defining how the compensation factors will be calculated and applied.

A real-time calculation system capable of computing the industrial optical performance and yields of a prescription laboratory is disclosed. The system uses statistical analysis to determine the compensation factors that can be applied to given products, Semi-Finish, materials, or lens designs to increase the lab yields. Using a monitoring and configuration system, the user tracks the evolution of the laboratory's performance and identifies areas in which yields are impacted. The user defines how the calculation system will optimize the laboratory's performance, such as by defining how the compensation factors will be calculated and applied.

A method of producing an optical element for a lithography apparatus, comprising the steps of: a) detecting a height profile of a surface of a crystal substrate of the optical element, and b) ascertaining, using the height profile detected, an installed orientation (2, 4, 6) of the optical element in an optical system of the lithography apparatus in relation to a stress-induced birefringence on incidence of polarized radiation, where the installed orientation (2, 4, 6) is an orientation in relation to a rotation of the optical element about a center axis of the optical element that runs through the surface.

A method of producing an optical element for a lithography apparatus, comprising the steps of: a) detecting a height profile of a surface of a crystal substrate of the optical element, and b) ascertaining, using the height profile detected, an installed orientation (2, 4, 6) of the optical element in an optical system of the lithography apparatus in relation to a stress-induced birefringence on incidence of polarized radiation, where the installed orientation (2, 4, 6) is an orientation in relation to a rotation of the optical element about a center axis of the optical element that runs through the surface.

A finishing tool for modifying a surface of a part, including: a base, wherein the base is one or more of rotated and translated; and one or more fibers coupled to the base; wherein a base portion of each of the one or more fibers is disposed at a first angle relative to a major axis of the base, wherein the first angle is equal to or between 90 degrees and 90 degrees; and wherein, in operation, an end portion of each of the one or more fibers is disposed at a second angle relative to the major axis of the base, wherein the second angle is approximately 90 degrees or 90 degrees, substantially parallel to the surface of the part. In operation, the base portion and the end portion of each of the one or more fibers is coupled by a continuously curved intermediate portion.

A computer-implemented method for establishing the representation of the edge of a spectacle lens or of a left spectacle lens and a right spectacle lens for a spectacle wearer is disclosed. The method includes: providing image data relating to the spectacle wearer with a worn spectacle frame; calculating information data derived from the image data; calculating a deterministically optimizable cost function linking the information data with spectacle lens data, wherein the spectacle lens data describe the spatial extent of at least one spectacle lens held in the spectacle frame; and setting a curve of an edge of the spectacle lens or of the left spectacle lens and the right spectacle lens by optimizing the cost function.

A computer-implemented method for establishing the representation of the edge of a spectacle lens or of a left spectacle lens and a right spectacle lens for a spectacle wearer is disclosed. The method includes: providing image data relating to the spectacle wearer with a worn spectacle frame; calculating information data derived from the image data; calculating a deterministically optimizable cost function linking the information data with spectacle lens data, wherein the spectacle lens data describe the spatial extent of at least one spectacle lens held in the spectacle frame; and setting a curve of an edge of the spectacle lens or of the left spectacle lens and the right spectacle lens by optimizing the cost function.

In a method for fine-processing of an axicon (L) having a concave or convex cone surface (KF) with a cone axis (KA) and a cone angle (), with use of geometrically indeterminate cutting edges in the form of grain in combination with a liquid at a processing region (BB) of a tool (W2), which is constructed for linear engagement (LE) with the cone surface and has a front end (EB) with respect to the cone axis, material removal is produced at the cone surface by a relative cutting speed which results from a rotational movement of the axicon about the cone axis and a relative oscillating linear movement (oscillation axis R) of the tool, in which the processing region is disposed in linear engagement with the cone surface and its front end moves back and forth in a direction radial with respect to the cone axis.

In a method for fine-processing of an axicon (L) having a concave or convex cone surface (KF) with a cone axis (KA) and a cone angle (), with use of geometrically indeterminate cutting edges in the form of grain in combination with a liquid at a processing region (BB) of a tool (W2), which is constructed for linear engagement (LE) with the cone surface and has a front end (EB) with respect to the cone axis, material removal is produced at the cone surface by a relative cutting speed which results from a rotational movement of the axicon about the cone axis and a relative oscillating linear movement (oscillation axis R) of the tool, in which the processing region is disposed in linear engagement with the cone surface and its front end moves back and forth in a direction radial with respect to the cone axis.

A method of polishing a surface of an optical lens intended to be mounted in a spectacle frame includes: obtaining edging contour data representative of the edging contour of the optical lens so as to be mounted in the spectacle frame; and determining polishing tool trajectory data corresponding to the trajectory of a polishing tool so as to polish the surface of the optical lens only within the edging contour; providing the polishing tool trajectory data to a CNC machine carrying a polishing tool; and polishing, via the polishing tool, the surface of the optical lens based on the polishing tool trajectory data.