Methods and devices for determining at least one centring parameter are disclosed. A mobile terminal is moved from a first position to a second position, and a respective image is captured of an eye area of a person. The acceleration is also measured during the movement. The centring parameter is then determined based on the captured image and the measured acceleration.

A device and a method for determining an ocular aberration of at least one eye of a user are disclosed. The device contains a wavefront sensing unit for measuring at least one optical wavefront with at least one light beam, from which an ocular aberration of the at least one eye of the user is determined. The device further contains at least one diffractive element for generating multiple diffraction orders in the light beam in two meridians in a manner that the multiple diffraction orders are spatially separated on the wavefront sensing unit and in the eye of the user. The device and the method allow generating an ocular defocus map in a one-shot assessment in real-time, especially by employing an automated measurement of the ocular aberrations with regard to different eccentricities of the eye of the user in two meridians.

Apparatus and methods are described, including providing a temporary progressive lens (20) that is configured for a subject's temporary use, based upon an initial progressive-lens optical design. The lens is composed of a base lens (22) and an attached additional and removable progressive lens part (24) for test purposes. Data that are indicative of suitability of the optical design for activities that are performed by the subject are received, the data being generated during use of the temporary progressive lens by the subject. Based upon the received data, the optical design for a progressive lens for the subject is optimised, and the optimised optical design in output.

Provided is a test method performed using a lens which comes into contact with a human body during use, the test method including the steps of: providing a membrane member including a membrane swellable upon absorbing water and a supporting base having an annular shape to support an outer periphery of the membrane; allowing cells to adhere on the membrane of the membrane member; and bringing the membrane to which the cells are adhered into close contact with the surface of the lens, by immersing the membrane member and the lens into a liquid and deforming the membrane in a swollen state along the surface of the lens.

A lens, system for designing, computer program for designing and a method for designing, with a computer, a progressive addition lens including a distance vision region, a near vision region, and an intermediate vision region, wherein a power gradually changes between the distance vision region and the near vision region, and wherein the progressive addition lens is based on prescription data, the method including: determining a transmission astigmatic performance parameter corresponding to a sum of a prescribed astigmatism included in the prescription data and of a predetermined amount of extra astigmatism; determining lens surface data corresponding to the determined transmission performance parameter.

An optical article may include a frame, a first active lens arrangement coupled to the frame, and a second active lens arrangement coupled to the frame. The first active lens arrangement and the second active lens arrangement may be lined up abreast with respect to each other. Further, the optical article may include a time-based optical power adjustment mechanism coupled to the first active lens arrangement and the second active lens arrangement. The time-based optical power adjustment mechanism may be configured to vary the optical power of the first active lens arrangement and the second active lens arrangement in accordance with a predetermined adjustment.

A method and apparatus for a diagnostic lens to determine decentration from the optical axis or pupil center in the manufacture of a prescription ophthalmic lens.

A method, a device, and a computer program product for determining a refractive error of an eye of a user are disclosed, as well as a method for producing a spectacle lens. The method for determining includes: a) displaying an image with a spatial modulation to the user; b) optionally, recording a reaction of the user to a variation of the spatial modulation over time; c) detecting a point in time at which a perception threshold of the user is reached; and d) determining the refractive error of the user from the spatial modulation, wherein the image contains a source image with several picture elements, wherein values for an image parameter are assigned to the picture elements, and wherein the spatial modulation is generated such that the values of the image parameter determine the values of a modulation parameter of the spatial modulation in the image.

The present disclosure relates to means of managing eye-length disorders, like myopia. The invention includes an apparatus and methods for the prescription, selection, supply and fitting of sets, stocks, or kits of pairs of myopia management spectacles, or spectacle fronts, attachable impermanent auxiliary optical films or mini optical elements used in conjunction with standard single vision spectacles, wherein the apparatus and methods are configured to provide substantially toric, or astigmatic, or asymmetric, directional optical cues to decelerate, ameliorate, control, inhibit, or reduce the rate of myopia progression over time, wherein the method is a prescribed care regimen providing temporal and spatial variation to the directional optical cues or stop signals.

The disclosure relates to an optical element intended to be worn in front of an eye of a human wearer. The optical element includes a dye composition configured so that, when the optical element is worn by a wearer having a given skin reflectance and is illuminated by a light source from a scene: —a first light beam is transmitted by the optical element towards the wearer, the first light beam having a first chroma; —a second light beam is transmitted by the optical element towards the scene after being reflected by the skin of the wearer, the second light beam having a second chroma; and —the absolute difference between the second chroma and the first chroma is greater than 6.