Method for determining a position of an optical lens member placed on a lens blocking ring (22). A reference system, blocking ring data, and optical lens member surface data are provided. Position parameters are provided defining a position of a reference point of the surface of the lens member with respect to the main plane of the reference system and an orientation, about the main axis of said placed surface at said reference point. The position of the placed surface is determined according to the position parameters. During a repositioning step (S6) the placed surface is virtually translated and rotated. During an altitude determination step (S7) a difference in position between the blocking ring and the placed surface is determined. The repositioning and altitude determining steps (S6, S7) are repeated so as to minimize the difference in position between the blocking ring and the placed surface.

Disclosed is a machining method by turning at least one surface of an ophthalmic lens, using a turning machine having at least one geometrical defect. The method includes a step (101-104) of determining a turning configuration for machining by turning the at least one surface of the ophthalmic lens, the turning configuration including turning parameters and machine defects parameters associated to the turning parameters.

Disclosed is a machining method by turning at least one surface of an ophthalmic lens, using a turning machine having at least one geometrical defect. The method includes a step (101-104) of determining a turning configuration for machining by turning the at least one surface of the ophthalmic lens, the turning configuration including turning parameters and machine defects parameters associated to the turning parameters.

A device for fine processing of optically effective surfaces on workpieces has a workpiece spindle which protrudes into a working space and by which a workpiece to be polished can be rotationally driven about a workpiece axis of rotation. Two tool spindles are associated with the workpiece spindle and protrude into the working space oppositely to the workpiece spindle. On each tool spindle, a polishing tool can be rotationally driven about a tool axis of rotation and is retained so that the polishing tool can be axially advanced along the tool axis of rotation. Furthermore, the tool spindles can be moved together in relation to the workpiece spindle along a linear axis extending substantially perpendicularly to the workpiece axis of rotation and can be pivoted about different pivoting adjustment axes, which extend substantially perpendicularly to the workpiece axis of rotation and substantially perpendicularly to the linear axis.

The invention relates to a tool spindle for a device for fine machining optically active surfaces on workpieces, having a spindle housing and a tool holding portion which protrudes beyond the housing. The tool holding portion can be axially advanced towards the workpiece along a tool rotational axis via a guiding assembly, which can be rotated about the tool rotational axis in the spindle housing. In order to axially advance the tool holding portion, the guide assembly has a plurality of linear mounting elements, which are distributed about the tool rotational axis in a uniform manner, and respective paired guide rods, which are connected to the tool holding portion in a traction- and pressure-resistant manner.

The invention relates to a tool spindle for a device for fine machining optically active surfaces on workpieces, having a spindle housing and a tool holding portion which protrudes beyond the housing. The tool holding portion can be axially advanced towards the workpiece along a tool rotational axis via a guiding assembly, which can be rotated about the tool rotational axis in the spindle housing. In order to axially advance the tool holding portion, the guide assembly has a plurality of linear mounting elements, which are distributed about the tool rotational axis in a uniform manner, and respective paired guide rods, which are connected to the tool holding portion in a traction- and pressure-resistant manner.

The device for polishing optical lenses includes a lens holder; a device for positioning the lens holder; and a device for rotating the lens holder about an axis. There is also a polishing tool; a tool holder; a device for positioning the tool holder; and a device for rotating the tool holder about an axis. The device for polishing also includes a ball joint arranged between a shaft secured to the tool holder and the device for positioning the tool holder, or between a shaft secured to the lens holder and the device for positioning the lens holder, so as to enable a spherical movement of the polishing tool and of the lens. The invention also relates to a method for polishing using the device according to the invention.

The device for polishing optical lenses includes a lens holder; a device for positioning the lens holder; and a device for rotating the lens holder about an axis. There is also a polishing tool; a tool holder; a device for positioning the tool holder; and a device for rotating the tool holder about an axis. The device for polishing also includes a ball joint arranged between a shaft secured to the tool holder and the device for positioning the tool holder, or between a shaft secured to the lens holder and the device for positioning the lens holder, so as to enable a spherical movement of the polishing tool and of the lens. The invention also relates to a method for polishing using the device according to the invention.

A polishing fixture assembly comprises a fixture base, which has a ferrule aperture and a spring member, and a clamping assembly. The spring member comprises upper, middle, and lower springs. The upper spring forms a portion of a cam aperture. The middle spring is proximate the ferrule aperture. The clamping assembly has a clamp base, a lever, and a cam shaft. The clamp base is connected to the fixture base. The lever is pivotally connected to the clamp base and has unlocked and locked positions. The cam shaft is connected to the lever and rotates within the cam aperture when the lever pivots. As the lever is moved into the locked position, the cam shaft rotates, opposing narrower sides of the cam shaft contact the upper spring thereby flexing the middle spring and the lower spring so that the middle spring contacts a ferrule positioned in the ferrule aperture.

Provided is a technique by which an optical member is marked without degrading the quality of the optical member. The optical member is produced through a removing step (S108, S113) of partially removing a low refractive index layer, which is the outermost layer of a multilayer structure in which the low refractive index layer and a high refractive index layer are layered on each other, by performing non-heating processing on an antireflection film that is formed to cover an optical surface of an optical base member and has the multilayer structure, through irradiation with an ultrashort pulse laser beam so as to expose the high refractive index layer.