An ophthalmic lens having a front face having a front power and a back face having a back power, the ophthalmic lens having a prescription resulting from the combination of the front and back powers, the back face presenting Fresnel rings and the ophthalmic lens having a transmittance of visible light smaller than 80%. Furthermore, a semi-finished blank from which the ophthalmic lens can be manufactured, a method for manufacturing an ophthalmic lens, a system for the execution of the method, and a computer-readable storage medium comprising program instructions for performing the method.

A contact lens and a method for treating an eye with myopia is described. The contact lens includes an inner optic zone and an outer optic zone. The outer optic zone includes at least a portion with a first power, selected to correct distance vision. The inner optic zone has a relatively more positive power (an add power). In some embodiments the add power is substantially constant across the inner optic zone. In other embodiments the add power is variable across the inner optic zone. While in some embodiments the inner optic zone has a power designed to substantially eliminate lag of accommodation in the eye with myopia, in other embodiments, the add power may be higher.

A method for determining an ophthalmic lens having unwanted astigmatism, the ophthalmic lens being adapted to a wearer, the method including: a wearer prescription data providing during which wearer prescription data indicative of an ophthalmic prescription of the wearer are provided; a wearer focal data providing during which wearer focal data indicative of the wearer preferred image focal plan are provided; an ophthalmic lens determining during which the ophthalmic lens is determined based on the prescription of the wearer and the wearer focal data to reduce impact of unwanted astigmatism of the ophthalmic lens for the wearer.

The current disclosure is directed to a method for determining an improved design for a progressive spectacle lens. Further, there are provided a method for manufacturing a progressive spectacle lens, a system for determining an improved design for a progressive spectacle lens, a non-transitory computer program and a progressive spectacle lens.

A computer-implemented method for providing a lens shape for an ophthalmic lens is disclosed. Further, there is provided a method for angular smoothing of a surface determined by carrier lines radially outwards of a prescription zone bordered by a first boundary line. In addition, there is provided an ophthalmic lens, in particular, a spectacle lens. Moreover, a method for minimizing the difference in thickness between two ophthalmic lenses for the same spectacles is provided. A computer program product and a machine-readable storage medium are provided as well.

A progressive spectacle lens includes a substrate which has a front face and a rear face and is made from a material with a regionally varying refractive index, wherein the front face and/or the rear face has/have a free-form surface geometry. The progressive spectacle lens complies with the following optical requirements: (1) a prescribed dioptric power in the distance reference point within the permissible limit deviations in accordance with EN ISO 8980-2:2004 and a prescribed dioptric power in the near reference point within the permissible limit deviations in accordance with EN ISO 8980-2:2004, (2) a monotonically steady increase in the dioptric power between the distance reference point and near reference point along a principal line of vision, and (3) a progression channel. The progressive spectacle lens has a free-form surface geometry of the front face and/or rear face.

A target design is produced with a computer-implemented method that takes into consideration an astigmatic effect and is suitable for optimizing a spectacle lens having the astigmatic effect. The method includes providing an initial target design that does not directly take into consideration the astigmatic effect of the spectacle lens, and producing the target design by correcting the initial target design on the basis of a correction target design that directly takes into consideration the astigmatic effect of the spectacle lens.

A method for determining a progression length of an ophthalmic lens, the method including providing an addition value Add, providing a model, the model linking an addition value Add with a progression length, and based on the model and on the provided addition value, determining the progression length.

The progressive ophthalmic lens comprises at least one multifocal surface, in which at each point of its surface an astigmatism value and a gradient of astigmatism value can be measured, the lens comprising: a far-vision zone with a reference point (FV), a near-vision zone with a reference point (NV), an intermediate vision zone with a progression path that connects the far vision zone and the near vision zone, a foveal projection, and a para-foveal projection, and said lens defining a lens addition.

If the lens addition is different than 2.00D, the astigmatism value is k*Add*0.41D, being Add the lens addition and k 0.5 and, if the progression path is shorter than 15 mm, the maximum astigmatism value of the foveal projection is substituted by (0.03*d)D/mm+0.86D, if the lens progression path is larger than 15 mm, the maximum astigmatism value of the foveal projection is substituted by (0.02*d)D/mm+0.71D.

Eyeglass lenses having a plurality of image-generating cells have a lens body formed of an optically-transmissive material, the lens body having an arcuate convex first surface, the lens body having an arcuate concave second surface, a reflective layer embedded within the lens body between the first and second surfaces, the reflective layer having an array of facets, and each facet of the reflective layer having a planar surface. Each of the facets may be a polygon. The reflective layer may be optically transmissive. The lens body may have a forward portion between the first surface and the reflective layer. The forward portion may have a plurality of cells, each cell being coextensive with an associated facet, each cell having the form of a plano-convex lens and mirror assembly adapted to receive parallel incoming rays and to focus the rays at a focal point beyond the first surface of the lens.