An auxiliary apparatus for testing the confocality of a scanning and descanning microscope component group has a connector configured for connecting the auxiliary apparatus in a defined relative position to the scanning and descanning microscope component group, and an optical axis running at a fixed orientation with respect to the connector. Further, the auxiliary apparatus has an auxiliary detector with a plurality of auxiliary detection apertures in a plurality of auxiliary detection aperture positions that are arranged at distances in direction of the optical axis and laterally with respect to the optical axis; and an auxiliary light source providing auxiliary light through a plurality of auxiliary emission apertures in a plurality of auxiliary emission aperture positions arranged at distances in direction of the optical axis and laterally with respect to the optical axis.

This invention discloses a handheld apparatus for measuring surface power or radius of prescription ophthalmic spectacle lenses, optical lenses or molds blocked with or without chuck during Rx production, and after comparing measurement results with designed data, providing correction data to the processing machines via wireless connection for correction processing if needed. The handheld apparatus integrates an optical measurement head into a monolithic optical system.

A camera-testing box for testing optical properties of an image-capturing device includes a box body, a light source, a photographic film, a mask, and a base. The light source is disposed inside the light-free box body. The photographic film is disposed on a side of the light source inside the box body. The mask is disposed on a side of the photographic film away from or facing the light source, and the mask includes a transparent area and a shielding area to reduce flare-causing light reflected by screws and other extraneous objects in the camera-testing box. The base is disposed inside the box body, and on a side of the mask away from the light source. The base supports the to-be-tested image-capturing device.

A system for monitoring the position of a blocking device on an ophthalmic lens (20) having at least one marking comprises: —a mechanical structure adapted to cooperate with the blocking device; —an image sensor (4) observing the ophthalmic lens (20); —a control unit (10) connected to the image sensor (4) and configured to produce an image having a point of reference with a determined position with respect to the mechanical structure and at least part of the ophthalmic lens (20) including said marking; and—a user interface (12) adapted to display a blocking device positional compensation proposal for an automatic positional compensation or for a manual positional compensation based on the comparison to a predetermined threshold of a distance between the point of reference and the marking on the image. A corresponding method and a method for edging an ophthalmic lens are also proposed.

A focusing state measuring apparatus for measuring a focusing state of a working apparatus with respect to a target object so as to perform work includes: a base plate installed in the working apparatus performing work on the target object and spaced apart from the target object; a first line beam generation unit provided on one side of the base plate and configured to irradiate a first line beam toward the target object; and a second line beam generation unit provided on one side of the base plate so as to be spaced apart from the first line beam generation unit in a first direction and configured to irradiate a second line beam toward the target object. The focusing state of the working apparatus with respect to the target object is determined according to states of the first line beam and the second line beam.

A method implemented by computer means for determining at least one optical parameter of a lens of eyewear adapted for a person, the method comprising: —an image reception step, during which at least a first image and a second image are received, the first image comprising a front view of the face of the person with at least one part of an eye of the person being directly visible, and the second image comprising a front view of the face of the person with said part of the eye of the person being visible through at least part of the lens, and —an optical parameter determination step, during which at least one optical parameter of the lens is determined based on a comparison between said part on the first and the second image.

The spatial structure of an optical element is determined. The optical element has a first optically active surface and a second optically active surface. The optical element is arranged in a holding device. The position of a point (P) on the first optically active surface and the position of a point (P′) on the second optically active surface are referenced in a coordinate system fixed to the holding device. The topography of the first optically active surface is determined in a coordinate system referenced to the holding device by the position of point (P) and the spatial structure of the optical element is calculated from the topography of the first optically active surface and from a data set as to the topography of the second optically active surface. The data set is referenced to the fixed coordinate system of the holding device by the position of point (P′).

Optical techniques for determining thermal properties of materials are described. Optical techniques include Raman scattering and thermal properties include relative length change and coefficient of thermal expansion. Correlations of features of bands observed in the Raman spectra of several glasses with thermal properties of the glasses are demonstrated. The technique provides a convenient method for determining thermal expansion properties of materials.

The present disclosure relates to a lens detection device and a lens detection system, wherein the lens detection device, including: a housing; and a detection module configured within the housing; wherein the detection module includes a control module, at least one light emitting module, and a photosensitive module cooperating with the light emitting module; the control module controls the light emitting module and the photosensitive module for conducting a detection process to a lens disposed between the light emitting module and the photosensitive module. As such, the lens detection may become much more convenient, the detection time may be reduced, and the lens detection device may be adopted widely thereby.

An optical measurement method and system and an optical device manufacturing system are provided. The optical measurement system includes an image generation system, an image measurement system and a control system. The image generation system is configured for generating test image information and outputting light containing the test image information to a device under test. The image measurement system is configured for obtaining detected image information according to the light passing through the device under test. The control system is configured for obtaining an aberration parameter according to imaging quality of the detected image information. The optical measurement method and system and an optical device manufacturing system can simulate any wavefront, and an assembled lens element can be simulated directly according to the compensation of an unassembled lens element to achieve a final imaging effect.