Some demonstrative embodiments include apparatuses, systems and/or methods of determining one or more optical parameters of a lens of eyeglasses. For example, a product may include one or more tangible computer-readable non-transitory storage media including computer-executable instructions operable to, when executed by at least one computer processor, enable the at least one computer processor to implement operations of determining one or more optical parameters of a lens of eyeglasses. The operations may include processing at least one image of an object captured via the lens; and determining the one or more optical parameters of the lens based on the at least one image.

A spectacle lens with has permanent markings is mounted on a mounting, in particular a suction mounting. The apparent location of the permanent markings is detected on the spectacle lens with a detection device. Additionally, the spectacle lens is illuminated eccentrically with respect to an optical axis of the detection device using eccentric light sources. Reflections from the lights sources on the spectacle lens are likewise detected. On the basis of the detected reflections and the apparent location of the permanent markings, the position and/or orientation of the mounted spectacle lens are determined.

Some demonstrative embodiments include apparatuses, systems and/or methods of determining one or more optical parameters of a lens of eyeglasses. For example, a product may include one or more tangible computer-readable non-transitory storage media including computer-executable instructions operable to, when executed by at least one computer processor, enable the at least one computer processor to process at least one captured image of at least one reflection of a flash on a lens of eyeglasses; and determine one or more optical parameters of the lens based at least on the at least one captured image.

An eccentricity measuring method includes a forming step of dividing reflected light from a first surface and a second surface of a test lens by a plurality of optical elements and of forming a first spot group and a second spot group, and an eccentricity calculating step of calculating an eccentricity amount of the first surface relative to the second surface based on the first spot group and the second spot group.

An inspection method for the positioning point of a contact lens is disclosed. In the inspection method, a trial lens comprising inspection points is worn on a patient's eye, and a camera device shoots an eye wearing the trial lens to obtain the shot content, and an electronic device calculates the distances from the limbus of the eye to the inspection points according to the shot content, so as to obtain the position of the positioning point of the eye on the trial lens, and the contact lens is made according to the position of the positioning point, so that an optical center of the contact lens can match the visual axis of the eye. During the inspection process, the eye sight is not blocked or affected by any object, thereby improving accuracy of the inspection for the positioning point.

Disclosed is an inspection and system method and system for determining the orientation of a contact lens on a lens support, particularly in an automated contact lens manufacturing line.

Some demonstrative embodiments include apparatuses, systems and/or methods of determining one or more parameters of a lens, For example, a computing device may be configured to process at least one depth map including depth information captured via a lens; and to determine one or more parameters of the lens based on the depth information.

An acquiring apparatus includes a first light source, a measurement optical system, an image sensor, an adjusting unit, an interferometer, and a calculating unit configured to calculate a distance between adjacent target surfaces among the plurality of target surfaces based on an interference signal. The index surface, a surface containing the first point, a surface containing the second point, and the light receiving surface have a conjugate relationship with each other with respect to the measurement optical system.

The present disclosure relates to a method for photometrical charting of a light source (Q, 3) clamped within a positioning device (1) and stationary relative to an object coordinate system (T) by means of a luminance density measurement camera (4) arranged stationary relative to a world coordinate system (W), wherein the light source (Q, 3) is moved between a first actual measurement position (P1) and at least one further actual measurement position (P2 to P5) along a kinematic chain of the positioning device (1) within the world coordinate system (W), wherein a luminance density measurement image (81 to 85) describing the spatial distribution of a photometric characteristic within a measurement surface is recorded by means of the luminance density measurement camera (4) in each actual measurement position (P1 to P5) with the light source (Q, 3) turned on, and wherein the position and/or orientation of the object coordinate system (T) relative to the world coordinate system (W) is recorded in each actual measurement position (P1 to P5) in direct reference to the world coordinate system (W) without reference to the kinematic chain of the positioning device (1). Moreover, the present disclosure relates to the use of such a method for photometric charting of a headlight (3).

A method of assembling an optical module according to the present disclosure includes disposing an input lens system at a position facing an input port, sensing a light intensity of divided light rays, adjusting the input lens system, and optically coupling the input lens system to the input port, and disposing a first output lens system and a second output lens system at positions facing a first output port and a second output port, respectively, and optically coupling the first output lens system and the second output lens system to the first output port and the second output port, respectively.