JPWO2020016431A5 - - Google Patents

Claims (24)

The progressive with instructions for manufacturing the progressive spectacle lens using an additive method, which is located in (i) a progressive spectacle lens or (ii) a data medium in the form of computer readable data. Representation of a refractive spectacle lens, or (iii) a virtual representation of the progressive spectacle lens in the form of computer readable data, with instructions for manufacturing the progressive spectacle lens using an additive method. A product comprising a representation of the progressive spectacle lens in the form of a computer-readable data signal having instructions for manufacturing the progressive spectacle lens using a data medium, or (iv) additive method. , The progressive refraction spectacle lens
-A uniform substrate with a spatially variable index of refraction and front and back surfaces.
-During intended use, either the front surface or the rear surface either forms the outer surface of the progressive power spectacle lens itself, or does not contribute to the equivalent spherical power of the progressive power spectacle lens, or at each point. Exclusively provided with one or more functional coatings that contribute less than 0.004 dpt.
-In a product, the front surface is implemented as a free-form surface and / or the rear surface is implemented as a free-form surface.
(A) The refractive index changes only in the first spatial dimension and the second spatial dimension, and is constant in the third spatial dimension, and the above-mentioned in the first spatial dimension and the second spatial dimension. A product characterized in that the distribution of the refractive index is neither point-symmetrical nor axially symmetric. Containing information about the fit of the progressive power spectacle lens in front of the eye , including the zero line-of-sight direction during intended use, and in the case of (a), the third spatial dimension.
-Differences of 5 ° or less from the zero line of sight during intended use, or-Differences of 10 ° or less from the zero line of sight during intended use, or-During intended use, said zero line of sight The product according to claim 1, wherein the product extends in different directions by 20 ° or less from the direction. It contains information about the fit of the progressive power spectacle lens in front of it, including the direction of the principal line of sight during intended use, and data that characterizes the object distance model, and in the case of (a), the third space. The dimension is
-During intended use, differing by 5 ° or less from the direction of the main line of sight, or-During intended use, differing by 10 ° or less from the direction of the main line of sight, or-During intended use, the line of sight. The product according to claim 1, wherein the product extends in different directions by 20 ° or less from the direction. In the case of (a), the third spatial dimension is
-Different by 5 ° or less from the direction of the front normal vector at the geometric center of the progressive refractive spectacle lens, or-From the direction of the front normal vector at the geometric center of the progressive refractive spectacle lens The product according to claim 1, wherein the product differs by 10 ° or less, or-extends in a direction different by 20 ° or less from the direction of the normal vector on the front surface at the geometric center of the progressive refractive force spectacle lens. .. Including a prism measuring point according to DIN EN ISO 13666: 2013-10-14.2.12, and in the case of (a), the third spatial dimension is:
-A difference of 5 ° or less from the direction of the normal vector at the prism measurement point, or-A difference of 10 ° or less from the direction of the normal vector at the prism measurement point, or-The normal vector at the prism measurement point The product according to claim 1, wherein the product extends in a direction different from the direction of 20 ° or less. Including the centering points according to section 5.20 of DIN EN ISO 13666: 2013-10, and in the case of (a), the third spatial dimension is:
-A difference of 5 ° or less from the direction of the normal vector at the centering point, or-A difference of 10 ° or less from the direction of the normal vector at the centering point, or-The normal vector at the centering point The product according to claim 1, wherein the product extends in different directions by 20 ° or less from the direction. (I) The front surface implemented as a free-form surface is such that the maximum absolute value of the mean curvature of the front surface is in the intermediate progressive zone, and / or (ii) the front surface implemented as a free-form surface. The posterior surface is such that the minimum absolute value of the mean curvature of the posterior surface is in the intermediate progressive zone, or (iii) the posterior surface has a spherical, rotationally symmetric aspherical or toric surface geometry, or 2 The front surface having two planes of symmetry and implemented as a free-form surface is such that the maximum absolute value of the mean curvature of the front surface is in the middle progressive zone, or (iv) the front surface. Is a surface having a spherical surface, a rotationally symmetric aspherical surface or a toric plane geometry, or having two planes of symmetry, and the rear surface implemented as a free-form surface has a minimum absolute value of the mean curvature of the rear surface. The mode is such that it is in the middle progressive zone, or (v) the back surface is not implemented as a free-form surface, and the front surface implemented as a free-form surface is the maximum of the absolute value of the mean curvature of the front surface. Is in a mode such that is in the middle progressive zone, or (vi) the front surface is not implemented as a free-form surface, and the rear surface implemented as a free-form surface is the absolute value of the mean curvature of the rear surface. The product according to any one of claims 1 to 6 , characterized in that the minimum is in a mode such that it is in the middle progressive zone. -(I) Predetermined placement of the progressive spectacle lens in front of the intended progressive spectacle wearer, which is placed in a data medium in the form of computer-readable data. Or (ii) data having computer-readable data relating to a predetermined arrangement of the progressive spectacle lens in front of the intended progressive spectacle wearer. Including more media,
-The progressive power spectacle lens has an equivalent spherical power for the predetermined arrangement of the progressive power spectacle lens in front of the eye of the progressive power spectacle wearer for which the progressive power spectacle lens is intended. Having a distribution,
-The progressive power spectacle lens has an intermediate progressive zone having a width, and the refractive power of the progressive power spectacle lens is such that the width of the intermediate progressive zone of the progressive power spectacle lens is intermediate. In the case of the same configuration of the control progressive power spectacle lens in at least a section of the progressive zone or over the entire length of the control progressive power spectacle lens in front of the progressive power spectacle wearer, the equivalent spherical surface. Greater than said width of said intermediate progressive zone in at least one section of said intermediate progressive zone or over the entire length of a controlled progressive power optic lens having the same distribution of powers but spatially unchanged refractive power. The product according to any one of claims 1 to 7 , wherein the product changes in space as described above. group:
-Horizontal section,
-Section in semi-participatory power,
-Horizontal section in semi-participatory power,
-Horizontal section in semi-participatory power,
-Horizontal section at 25% of the added refractive power,
-Horizontal section at 75% of the added refractive power,
-Horizontal section at semi-participatory power and horizontal section at 25% of said joined power,
-Horizontal section at semi-participatory power and horizontal section at 75% of said combined power,
-Deformations of the horizontal section at semi-participatory power and the horizontal section at 25% of said joiner power and the horizontal section at 75% of said joiner power are characterized by being selected for the at least one section. The product according to claim 8 . -(I) The progressive refractive power spectacle lens of the progressive refractive power spectacle lens in front of the wearer of the progressive refractive power spectacle lens, which is arranged in a data medium in the form of computer readable data. Representation of the residual turbulence distribution for a given arrangement and / or (ii) said progressive refractive spectacle wearer intended for the progressive refractive spectacle lens arranged in a data medium in the form of computer readable data. Representation of the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the progressive refractive force spectacle lens in front of the eye and / or (iii) arranged in a data medium in the form of computer readable data. Representation of a formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the intended progressive refractive spectacle wearer, and / or ( iv) The predetermined progressive refractive spectacle lens of the progressive refractive spectacle lens in front of the wearer of the progressive refractive spectacle lens, which is disposed on a data medium in the form of computer readable data. Representation of the distribution of equivalent spherical powers for arrangement and / or (v) said progressive refractive spectacle lens in front of the progressive refractive spectacle wearer intended for which the progressive refractive spectacle lens is intended. A data medium having computer-readable data on the residual turbulence distribution for a given arrangement and / or (vi) the progressive refraction in front of the eyes of the progressive refraction spectacle wearer intended for which the progressive refractive spectacle lens is intended. A data medium having computer-readable data on the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the force spectacle lens and / or (vii) the progressive refractive force intended by the progressive spectacle lens. A data medium having computer-readable data about the formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the spectacle wearer and / or (viii) the progressive refractive spectacle lens is intended. Further comprising a data medium having computer-readable data on the distribution of the equivalent spherical power for the predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer.
-The progressive power spectacle lens has a distance portion and a near portion, and
-In the width of the intermediate progressive zone, the absolute value of residual astigmatism is a predetermined limit value, and the group specified below:
(A) The limit value is in the range of 0.25 dpt to 1.5 dpt.
(B) The limit value shall be in the range of 0.25 dpt to 1.0 dpt.
(C) The limit value shall be in the range of 0.25 dpt to 0.75 dpt.
(D) The limit value shall be in the range of 0.25 dpt to 0.6 dpt.
(E) The limit value is in the range of 0.25 dpt to 0.5 dpt.
(F) The length of the intermediate progressive zone extending between the distance portion and the near portion, the limit value being less than a predetermined limit value selected within the range of 0.5 dpt. The product of claim 8 or 9 , characterized in that it corresponds to a dimension across a direction. -(I) Predetermined placement of the progressive spectacle lens in front of the intended progressive spectacle wearer, which is placed in a data medium in the form of computer-readable data. Or (ii) further include a data medium having computer-readable data relating to a predetermined arrangement of the progressive spectacle lens in front of the intended progressive spectacle wearer. That and
-The progressive power spectacle lens has an equivalent spherical power for the predetermined arrangement of the progressive power spectacle lens in front of the eye of the progressive power spectacle wearer for which the progressive power spectacle lens is intended. Having a distribution and
-The product is
(I) The predetermined of the progressive refractive spectacle lens in front of the wearer of the progressive refractive spectacle lens, which is disposed on a data medium in the form of computer-readable data and is intended for the progressive refractive spectacle lens. Representation of the residual turbulence distribution for the arrangement of, and / or (ii) the eyes of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is disposed in a data medium in the form of computer readable data. Representation of the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the progressive refractive force spectacle lens in front of, and / or (iii) arranged in a data medium in the form of computer readable data. Representation of a formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the intended progressive refractive spectacle wearer, and / or (iv). ) The predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is arranged in a data medium in the form of computer readable data. Representation of the distribution of the equivalent spherical power of the A data medium having computer-readable data on the residual turbulence distribution for the arrangement of the, and / or (vi) the progressive refractive force spectacle lens intended for said progressive refractive force spectacle wearer said said progressive refractive force in front of the eye. A data medium having computer-readable data on the non-point aberration refraction force distribution required for complete correction of the predetermined arrangement of the spectacle lens and / or (vii) the progressive refraction force spectacle lens for which the progressive refraction force spectacle lens is intended. A data medium having computer-readable data about the formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the wearer and / or (viii) the progressive refractive spectacle lens is intended. Further comprising a data medium having computer-readable data on the distribution of the equivalent spherical power for the predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer.
-The refractive index of the progressive spectacle lens is such that the maximum value of the residual random vision of the progressive spectacle lens is the control progressive spectacle lens, in front of the person wearing the progressive spectacles. In the case of the same arrangement of the control progressive spectacle lenses, the residual random vision of the control progressive spectacle lens having the same distribution of the equivalent spherical powers but having a refractive index that does not change spatially seems to be less than the maximum value. The product according to any one of claims 1 to 10 , characterized in that it changes in space. -(I) Predetermined placement of the progressive spectacle lens in front of the intended progressive spectacle wearer, which is placed in a data medium in the form of computer-readable data. Or (ii) further include a data medium having computer-readable data relating to a predetermined arrangement of the progressive spectacle lens in front of the intended progressive spectacle wearer. That and
-The progressive power spectacle lens is an equivalent spherical power for the predetermined arrangement of the progressive power spectacle lens in front of the eye of the progressive power spectacle wearer for which the progressive power spectacle lens is intended. Having a distribution of W) and
-The product is
(I) The predetermined of the progressive refractive spectacle lens in front of the wearer of the progressive refractive spectacle lens, which is disposed on a data medium in the form of computer-readable data and is intended for the progressive refractive spectacle lens. Representation of the residual turbulence distribution for the arrangement of, and / or (ii) the eyes of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is disposed in a data medium in the form of computer readable data. Representation of the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the progressive refractive force spectacle lens in front of, and / or (iii) arranged in a data medium in the form of computer readable data. Representation of a formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the intended progressive refractive spectacle wearer, and / or (iv). ) The predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is arranged in a data medium in the form of computer readable data. Representation of the distribution of the equivalent spherical power of the A data medium having computer-readable data on the residual turbulence distribution for the arrangement of the, and / or (vi) the progressive refractive force spectacle lens intended for said progressive refractive force spectacle wearer said said progressive refractive force in front of the eye. A data medium having computer-readable data on the non-point aberration refraction force distribution required for complete correction of the predetermined arrangement of the spectacle lens and / or (vii) the progressive refraction force spectacle lens for which the progressive refraction force spectacle lens is intended. A data medium having computer-readable data about the formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the wearer and / or (viii) the progressive refractive spectacle lens is intended. Further comprising a data medium having computer-readable data on the distribution of the equivalent spherical power for the predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer.
-The progressive power spectacle lens has an intermediate progressive zone and a principal line of sight, and the refractive power of the progressive power spectacle lens is a predetermined residual astigmatism value on a horizontal section at the narrowest point of the intermediate progressive zone. A _{res, lim} , and the group (a) The residual astigmatism value Ares _{, lim} is in the range of 0.25 dpt to 1.5 dpt.
(B) The residual astigmatism values Ares _{and lim} are in the range of 0.25 dpt to 1.0 dpt.
(C) The residual astigmatism value Ares _{, lim} shall be in the range of 0.25 dpt to 0.75 dpt.
(D) The residual astigmatism values Ares _{and lim} are in the range of 0.25 dpt to 0.6 dpt.
(E) The residual astigmatism values Ares _{and lim} are in the range of 0.25 dpt to 0.5 dpt.
(F) The residual astigmatism value Ares _{, lim} is about the predetermined residual astigmatism value Ares, _lim of 0.5 dpt, or a horizontal section passing through a point on the main line of sight where the semi-participatory refractive power is achieved. About, the following relational expression:

Is variable in space such that it fits within a region having a horizontal distance of 10 mm on either side of the main line of sight, and in the equation, grad W is the progressive power at the narrowest point of the intermediate progressive zone on the main line of sight. Describes the refractive power gradient of the equivalent spherical power at the direction of the principal line of sight of the spectacle lens or at a point on the principal line of sight where the semi-participatory power is achieved, where B is the residual astigmatism _Ares ≤ _Ares . _{, Lim} describes the width of the region in the progressive power spectacle lens, where c is the group:
(A) 1.0 <c,
(B) 1.1 <c,
(C) 1.2 <c,
(D) 1.3 <c
The product according to any one of claims 1 to 11 , characterized in that it is a constant selected from. The progressive spectacle lens having instructions for manufacturing the progressive spectacle lens using an additive method, which is located in (i) a progressive spectacle lens or (ii) a data medium in the form of computer readable data. Having a representation of the progressive spectacle lens, or a virtual representation of the progressive spectacle lens in the form of computer readable data, with instructions for manufacturing the progressive spectacle lens using (iii) additive methods. The progressive refractive force spectacle lens is a product including a data medium.
-Front and back,
-Has a refractive index that changes spatially,
-The front surface is implemented as a free-form surface implemented as a progressive surface, and / or the rear surface is implemented as a free-form surface implemented as a progressive surface.
-The progressive power eyeglass lens is a substrate of the substrate, which does not include individual layers and includes the front and rear surfaces as well as the spatially variable index of refraction and one or more individual layers. In a product comprising a substrate having a front coating on the front surface and / or a back coating on the back surface of the substrate comprising one or more individual layers.
-Equivalent spherical power measured at each point on the front surface of the progressive power spectacle lens having the front surface coating and / or the back surface coating, and a control progressive power spectacle lens having no front surface coating. And the difference from the equivalent spherical power measured at each corresponding point on the anterior surface of the control progressive power spectacle lens, which has no posterior coating but has the same substrate, is the group specified below:
(A) The value of the difference is less than 0.001 dpt.
(B) The value of the difference is less than 0.002 dpt.
(C) The value of the difference is less than 0.003 dpt.
(D) The value of the difference is less than the value from being less than 0.004 dpt.
(A) The refractive index changes only in the first spatial dimension and the second spatial dimension, and is constant in the third spatial dimension, and the above-mentioned in the first spatial dimension and the second spatial dimension. A product characterized in that the distribution of refractive index is neither point-symmetrical nor axially symmetric. Characterized by information regarding the fit of the progressive power spectacle lens in front of the eye, including the intended zero line-of-sight direction in use, in the case of (a), the third spatial dimension is:
-Differences of 5 ° or less from the zero line of sight during intended use, or-Differences of 10 ° or less from the zero line of sight during intended use, or-During intended use, said zero line of sight 13. The product of claim 13 , extending in different directions by 20 ° or less from the direction. Characterized by information about the fit of the progressive power spectacle lens in front of the eye, including the intended main line-of-sight direction in use, and data characterizing the object distance model, in the case of (a), the third space. The dimension is
-During intended use, differing by 5 ° or less from the direction of the main line of sight, or-During intended use, differing by 10 ° or less from the direction of the main line of sight, or-During intended use, the line of sight. 13. The product of claim 13 , extending in different directions by 20 ° or less from the direction. In the case of (a), the third spatial dimension is
-Different by 5 ° or less from the direction of the front normal vector at the geometric center of the progressive refractive spectacle lens, or-From the direction of the front normal vector at the geometric center of the progressive refractive spectacle lens 13. The product of claim 13 , characterized in that it differs by 10 ° or less, or-extends in a direction that differs by 20 ° or less from the direction of the front normal vector at the geometric center of the progressive refractive force spectacle lens. .. Characterized by prismatic measurement points according to DIN EN ISO 13666: 2013-10-14.2.12, in the case of (a), the third spatial dimension is:
-Is it different by 5 ° or less from the direction of the normal vector at the prism measurement point, or-is it different by 10 ° or less from the direction of the normal vector at the prism measurement point, or-is it different by 10 ° or less from the direction of the normal vector at the prism measurement point? The product according to claim 13 , which extends in different directions by 20 ° or less from the direction. Characterized by a centering point according to section 5.20 of DIN EN ISO 13666: 2013-10, in the case of (a), the third spatial dimension is:
-A difference of 5 ° or less from the direction of the normal vector at the centering point, or-A difference of 10 ° or less from the direction of the normal vector at the centering point, or-The normal vector at the centering point The product according to claim 13 , which extends in different directions by 20 ° or less from the direction. The progressive power spectacle lens includes an intermediate progressive zone and
(I) The front surface implemented as a free-form surface is in such a manner that the mean curvature has the maximum in the intermediate progressive zone, and / or (ii) the rear surface implemented as a free-form surface has a mean curvature. Is in a mode such that has a minimum in the intermediate progressive zone, or (iii) the rear surface has a spherical, rotationally symmetric aspherical or toric surface geometry, and the front surface implemented as a free-form surface. The mode is such that the maximum absolute value of the mean curvature of the anterior surface is in the intermediate progressive zone, or (iv) the anterior surface has a spherical, rotationally symmetric aspherical or toric surface geometry, and a free-form surface. The posterior surface is such that the minimum absolute value of the mean curvature of the posterior surface is in the intermediate progressive zone, or (v) the posterior surface is not implemented as a free-form surface and is free. The anterior surface implemented as a morphological surface is such that the maximum absolute value of the mean curvature of the anterior surface is in the intermediate progressive zone, or (vi) the anterior surface is not implemented as a free morphological surface. 1 _ The products listed in the section. -(I) Predetermined placement of the progressive power spectacle lens in front of the intended progressive power spectacle wearer, which is placed on a data medium in the form of computer-readable data. Or (ii) further include a data medium having computer-readable data regarding a predetermined arrangement of the progressive power spectacle lens in front of the wearer of the progressive power spectacles.
-The progressive power spectacle lens has an equivalent spherical power for the predetermined arrangement of the progressive power spectacle lens in front of the eye of the progressive power spectacle wearer for which the progressive power spectacle lens is intended. Having a distribution,
-The progressive power spectacle lens has an intermediate progressive zone having a width, and the refractive power of the progressive power spectacle lens is such that the width of the intermediate progressive zone of the progressive power spectacle lens is intermediate. In the case of the same configuration of the control progressive power spectacle lens in at least a section of the progressive zone or over the entire length of the control progressive power spectacle lens in front of the progressive power spectacle wearer, the equivalent spherical surface. A claim, wherein a control progressive power spectacle lens having the same distribution of powers but having a refractive power that does not change spatially changes in space so as to be larger than the width of the intermediate progressive zone. The product according to any one of 13 to 19 . group:
-Horizontal section,
-Section in semi-participatory power,
-Horizontal section in semi-participatory power,
-Horizontal section at semi-participatory power and horizontal section at 25% of said joined power,
-Horizontal section at semi-participatory power and horizontal section at 75% of said combined power,
-Deformations of the horizontal section at semi-participatory power and the horizontal section at 25% of said joiner power and the horizontal section at 75% of said joiner power are characterized by being selected for the at least one section. The product according to claim 20 . -(I) The progressive refractive power spectacle lens of the progressive refractive power spectacle lens in front of the wearer of the progressive refractive power spectacle lens, which is arranged in a data medium in the form of computer readable data. Representation of the residual turbulence distribution for a given arrangement and / or (ii) said progressive refractive spectacle wearer intended for the progressive refractive spectacle lens arranged in a data medium in the form of computer readable data. Representation of the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the progressive refractive force spectacle lens in front of the eye and / or (iii) arranged in a data medium in the form of computer readable data. Representation of a formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the intended progressive refractive spectacle wearer, and / or ( iv) The predetermined progressive refractive spectacle lens of the progressive refractive spectacle lens in front of the wearer of the progressive refractive spectacle lens, which is disposed on a data medium in the form of computer readable data. Representation of the distribution of equivalent spherical powers for arrangement and / or (v) said progressive refractive spectacle lens in front of the progressive refractive spectacle wearer intended for which the progressive refractive spectacle lens is intended. A data medium having computer-readable data on the residual turbulence distribution for a given arrangement and / or (vi) the progressive refraction in front of the eyes of the progressive refraction spectacle wearer intended for which the progressive refractive spectacle lens is intended. A data medium having computer-readable data on the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the force spectacle lens and / or (vii) the progressive refractive force intended by the progressive spectacle lens. A data medium having computer-readable data about the formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the spectacle wearer and / or (viii) the progressive refractive spectacle lens is intended. Further comprising a data medium having computer-readable data on the distribution of the equivalent spherical power for the predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer.
-The progressive power spectacle lens has a distance portion and a near portion, and
-In the width of the intermediate progressive zone, the absolute value of residual astigmatism is a predetermined limit value, and the group specified below:
(A) The limit value is in the range of 0.25 dpt to 1.5 dpt.
(B) The limit value shall be in the range of 0.25 dpt to 1.0 dpt.
(C) The limit value shall be in the range of 0.25 dpt to 0.75 dpt.
(D) The limit value shall be in the range of 0.25 dpt to 0.6 dpt.
(E) The limit value is in the range of 0.25 dpt to 0.5 dpt.
(F) The length of the intermediate progressive zone extending between the distance portion and the near portion, the limit value being less than a predetermined limit value selected within the range of 0.5 dpt. The product of claim 20 or 21 , characterized in that it corresponds to a dimension across a direction. -(I) Predetermined placement of the progressive power spectacle lens in front of the intended progressive power spectacle wearer, which is placed on a data medium in the form of computer-readable data. Or (ii) further include a data medium having computer-readable data regarding a predetermined arrangement of the progressive power spectacle lens in front of the wearer of the progressive power spectacles.
-The progressive power spectacle lens has an equivalent spherical power for the predetermined arrangement of the progressive power spectacle lens in front of the eye of the progressive power spectacle wearer for which the progressive power spectacle lens is intended. Having a distribution and
-The product is
(I) The predetermined of the progressive refractive spectacle lens in front of the wearer of the progressive refractive spectacle lens, which is disposed on a data medium in the form of computer-readable data and is intended for the progressive refractive spectacle lens. Representation of the residual turbulence distribution for the arrangement of, and / or (ii) the eyes of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is disposed in a data medium in the form of computer readable data. Representation of the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the progressive refractive force spectacle lens in front of, and / or (iii) arranged in a data medium in the form of computer readable data. Representation of a formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the intended progressive refractive spectacle wearer, and / or (iv). ) The predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is arranged in a data medium in the form of computer readable data. Representation of the distribution of the equivalent spherical power of the A data medium having computer-readable data on the residual turbulence distribution for the arrangement of the, and / or (vi) the progressive refractive force spectacle lens intended for said progressive refractive force spectacle wearer said said progressive refractive force in front of the eye. A data medium having computer-readable data on the non-point aberration refraction force distribution required for complete correction of the predetermined arrangement of the spectacle lens and / or (vii) the progressive refraction force spectacle lens for which the progressive refraction force spectacle lens is intended. A data medium having computer-readable data about the formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the wearer and / or (viii) the progressive refractive spectacle lens is intended. Further comprising a data medium having computer-readable data on the distribution of the equivalent spherical power for the predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer.
-The refractive index of the progressive spectacle lens is such that the maximum value of the residual random vision of the progressive spectacle lens is the control progressive spectacle lens, in front of the person wearing the progressive spectacles. In the case of the same arrangement of the control progressive spectacle lenses, the residual random vision of the control progressive spectacle lens having the same distribution of the equivalent spherical powers but having a refractive index that does not change spatially seems to be less than the maximum value. The product according to any one of claims 13 to 22 , wherein the product changes in space. -(I) Predetermined placement of the progressive power spectacle lens in front of the intended progressive power spectacle wearer, which is placed on a data medium in the form of computer-readable data. Or (ii) further include a data medium having computer-readable data regarding a predetermined arrangement of the progressive power spectacle lens in front of the wearer of the progressive power spectacles.
-The progressive power spectacle lens is an equivalent spherical power for the predetermined arrangement of the progressive power spectacle lens in front of the eye of the progressive power spectacle wearer for which the progressive power spectacle lens is intended. Having a distribution of V) and
-The product is
(I) The predetermined of the progressive refractive spectacle lens in front of the wearer of the progressive refractive spectacle lens, which is disposed on a data medium in the form of computer-readable data and is intended for the progressive refractive spectacle lens. Representation of the residual turbulence distribution for the arrangement of, and / or (ii) the eyes of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is disposed in a data medium in the form of computer readable data. Representation of the non-point aberration refractive force distribution required for complete correction of the predetermined arrangement of the progressive refractive force spectacle lens in front of, and / or (iii) arranged in a data medium in the form of computer readable data. Representation of a formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the intended progressive refractive spectacle wearer, and / or (iv). ) The predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer intended for the progressive refractive spectacle lens, which is arranged in a data medium in the form of computer readable data. Representation of the distribution of the equivalent spherical power of the A data medium having computer-readable data on the residual turbulence distribution for the arrangement of the, and / or (vi) the progressive refractive force spectacle lens intended for said progressive refractive force spectacle wearer said said progressive refractive force in front of the eye. A data medium having computer-readable data on the non-point aberration refraction force distribution required for complete correction of the predetermined arrangement of the spectacle lens and / or (vii) the progressive refraction force spectacle lens for which the progressive refraction force spectacle lens is intended. A data medium having computer-readable data about the formulation and object distance model for the predetermined arrangement of the progressive refractive spectacle lens in front of the wearer and / or (viii) the progressive refractive spectacle lens is intended. Further comprising a data medium having computer-readable data on the distribution of the equivalent spherical power for the predetermined arrangement of the progressive refractive spectacle lens in front of the progressive refractive spectacle wearer.
-The progressive power spectacle lens has an intermediate progressive zone and a principal line of sight, and the refractive power of the progressive power spectacle lens is a predetermined residual astigmatism value on a horizontal section at the narrowest point of the intermediate progressive zone. A _{res, lim} , and the group (a) The residual astigmatism value Ares _{, lim} is in the range of 0.25 dpt to 1.5 dpt.
(B) The residual astigmatism values Ares _{and lim} are in the range of 0.25 dpt to 1.0 dpt.
(C) The residual astigmatism value Ares _{, lim} shall be in the range of 0.25 dpt to 0.75 dpt.
(D) The residual astigmatism values Ares _{and lim} are in the range of 0.25 dpt to 0.6 dpt.
(E) The residual astigmatism values Ares _{and lim} are in the range of 0.25 dpt to 0.5 dpt.
(F) The residual astigmatism value Ares _{, lim} is about the predetermined residual astigmatism value Ares, _lim of 0.5 dpt, or a horizontal section passing through a point on the main line of sight where the semi-participatory refractive power is achieved. About, the following relational expression:

Is variable in space such that it fits within a region having a horizontal distance of 10 mm on either side of the main line of sight, where in the equation the grad W is the narrowest point or the semi-participation of the intermediate progressive zone on the main line of sight. Describes the refractive power gradient of the equivalent spherical power of the progressive power spectacle lens at the point on the principal line of sight where the power of refraction is achieved, where B is the progressive power where the residual astigmatism is _Ares ≤ _{Ares, lim} . Describes the width of the region in the optical power spectacle lens, where c is the group:
(A) 1.0 <c,
(B) 1.1 <c,
(C) 1.2 <c,
(D) 1.3 <c
The product according to any one of claims 13 to 23 , characterized in that it is a constant selected from.