TH38482A - Lenses for use with multi-optical eyes - Google Patents

Abstract

DC60 (08/01/42) in a multi-point eye lens incorporating a distortion-shaped surface. A sphere with an average spherical shape and a cylinder at all points on the surface of the remote sight area. Field of view And the medium-term sightseeing area The length of that progression is the length which the top is going to be proportional to the quantity set in Different regions of this lens Will be a short length To avoid distortion on the periphery of the lens, which would otherwise occur. Isospeer and isosylender lines Will be distributed on the surface of the lens in order to ensure the variation in spherical shape. That is not too abrupt, along a circle with a radius of 20 mm centered on the center. Geometric center of the lens And the variation of the spherical shape on the surface of the lens within the figure Such a circle is also a small value. This lens has an enlarged field of view. Bigger and progress is less perceived to the wearer In a multi-point eye lens, the optical focus consists of a distorted surface. A sphere with an average spherical shape and a cylinder at all points on the surface of the remote sight area. Field of view And the medium-term sightseeing area The length of that progression is the length which the top is going to be proportional to the quantity set in Different regions of this lens Will be a short length To avoid distortion on the periphery of the lens, which would otherwise occur. Isospeer and isosylender lines Will be distributed on the surface of the lens in order to ensure the variation in spherical shape. That is not too abrupt, along a circle with a radius of 20 mm centered on the center. Geometric center of the lens And the variation of the spherical shape on the surface of the lens within the figure Such a circle is also a small value. This lens has an enlarged field of view. Bigger and progress is less perceived to the wearer

Claims (7)

1. A lens for use with a multi-point optical eye consisting of a spherical distortion surface that There is an average spherical shape and a cylindrical shape at every point on it. The lens will have additional power. And which will include VL remote sight area, short distance sight zone VP, medium distance sight zone VI, main meridian of MM \ 'progression spanning the region. Three such areas And the addition of power where the main length of the progression established here is shorter than 16 mm, the maximum I dS / d theta I max of the tangential derivative modulus of the spherical shape. On average A circle with a diameter of 40 mm, centered on the geometric center of Such lenses are less than a quarter of the Pmer maximum of the average spherical slope according to The meridian I dS / d theta I max / Pmer <0.25 and C max of the cylindrical inside this circle is less than the addition of power at Cmax &lt; Anom 2. Lens according to claim 1, where the main meridian of advancement will be made. Is raised by the midpoint of the corresponding contour segment formed by the point at which the figure values The cylinder is 0.50 diopter. 3. Lens according to claim 1, where the short-distance sighting zone, which has been delimited in the The top of the aforementioned lens by a line formed by a point where the value of the cylinder is half the The additional power will have a width greater than 14.5 mm at the point of reference for close-up sights. 4. Lens according to claim 1, where the said remote sight zone was established. In the upper part of the lens by the line formed by the point where the value of the cylinder is half. Of additions are to be contained, at least with one angular sector formed by semi. Two upward infinity lines that begin at the geometric center of the lens and are angled 5. Lenses according to claim 1, where the value of the cylindrical shape at the surface of such a lens is at least 150 ํ. 6. Lens according to claim 5, where the cylindrical value at the surface of such lens is less than 90% of the addition of power. 7. Lens according to claim 1, where the difference of The maximum cylindrical value of the two halves of such lenses, separated by the main meridian of progression, is less than 0.1 diopter. 8. Lens according to claim 7, where the difference The maximum cylindrical value of the two halves of such lenses, separated by the main meridian of progression, is less than 0.05 diopter. 9. Lens according to claim 1, where the lens This is a multi-point lens that is made up. For short and medium excursions The lens will have additional power. Defined as the difference between the maximum and the minimum of the average sphere on the following meridian. Say of progress within a circle with a radius of 20 mm centered on the center of the path. Geometry of such lenses 1 0. Lens according to claim 9, where the main length of the progression will be determined. It is the ratio between the addition of power and the maximum value of the average circular slope Pmer along the aforementioned meridian. 1 1. Lens according to claim 1, where this lens will be a multi-point lens. pace Page with reference point for the near-field observation area The reference points for the distant sights and the defined additions are the difference between the average spherical values at these two points. 1 2. Lens according to claim 11, where the main length of Progress will be set. Is the difference of the height between the y-axis of the integral center and the y-axis of the points on the meridian, where the mean spherical value is equal to the sum of the average spherical values at The reference point for telephoto sights plus 85% of the above additional power 1 3. A multi-point eye lens incorporating a spherical distortion surface. With an average spherical shape and a cylindrical shape at every point on it. The lens will have additional power. And which will include a remote sightseeing area VL Short-term Sightseeing Region VP Intermediate Sightseeing Area VI Major Meridian of MM \ 'Progression Spanning Three such areas And the addition of power where the main length of the progression set here is shorter than 13 mm, the maximum I dS / d theta I max of the modulus of the tangential derivative of the sphere. On average A circle with a diameter of 40 mm, centered on the geometric center of Such lenses are less than a quarter of the Pmer maximum of the average spherical slope according to The meridian I dS / d theta I max / Pmer <0.25 and the maximum Cmax of the cylindrical inside this circle is less than the addition of power at Cmax &lt; Anom 1 4. Lens according to claim 13 where the main meridian of advancement will be addressed. It is made up by the midpoint of the corresponding line-to-line segments formed by the point where the figure's value. Cylinder equal to 0.50 diopter 1 5. Lens according to claim 13, where the near-field sighting zone, which is doped in The upper part of such a lens by a line formed by a point where the value of the cylinder is half of The addition is to have a width greater than 14.5 mm at the point of reference for close-up sights 1 6. Lens according to claim 13, where the said remote sight zone is established. It comes in the upper part of the lens by the line formed by the point where the value of the cylinder is half. One of the additions is going to contain at least one angular sector formed by The two upward-facing semi-infinite lines that begin at the geometric center of the lens and have The angle between the two sides, determined to be at least 150 ํ 1 7. Lens according to claim 13, where the value of the cylindrical shape at the surface of the lens will Less than the addition of power 1. 8. Lens according to claim 17, where the cylindrical value at the surface of such lens is less than 90% of the addition of power 1. 9. Lens according to claim 13, where The difference of the maximum cylindrical value of the two segments of such lenses that is bordered by the main meridian of progression is less than 0.1 diopters 2 0. Lens according to the claim clause. 19 where the maximum cylindrical difference in the two halves of such lenses, separated by the main meridian of progression, is less than 0.05. Article 13 where this lens will be a multi-focus lens made For close-up and short-distance tours The lens will have additional power. Defined as the difference between the maximum and the minimum of the average sphere on the following meridian. Say of progress within a circle with a radius of 20 mm centered on the center of the path. 2 2. The lens according to claim 21, where the main length of the progression is fixed. It is the ratio between the addition of power and the maximum value of the slope of the average circular shape, Pmer, along the aforementioned meridian. 2. 3. Lens according to claim 13, where this lens will be a multi-point lens. pace Page with reference point for the near-field observation area The reference points for the distant viewing area and the set enhancement are the result of the average spherical value at these two points. 2 4. Lens according to claim 23, where the main length of the progression. Will be set Is the difference of the height between the y-axis of the integral center and the y-axis of the points on the meridian, where the mean spherical value is equal to the sum of the average spherical values at The reference point for telephoto sights plus 85% of the additional power 2 5. Lenses for use with multi-point optics, including spherical distortion surfaces. With an average spherical shape and a cylindrical shape at every point on it. The lens will have additional power. And which will include VL remote sight area, short distance sight zone VP, medium distance sight zone VI, main meridian of MM \ 'progression spanning the region. The service of the three districts. And the addition of power, where the main length of the progression is set here, lies in the range of approximately 12 to 13 mm, the maximum I dS / d theta I max of the derivative modulus. The tangent of the average sphere on A circle with a diameter of 40 mm, centered on the geometric center of Such lenses are less than a quarter of the Pmer maximum of the average spherical slope according to The meridian I dS / d theta I max / Pmer <0.25 and the maximum Cmax of the cylindrical inside this circle is less than the addition of power at Cmax &lt; Amon 2 6. Lens according to claim 25, where the main meridian of advancement will be addressed. It is made up by the midpoint of the corresponding line-to-line segments formed by the point where the figure's value. The cylinder is 0.50 diopter 2. 7. Lens according to claim 25, where the short-range sighting zone, which is doped in The upper part of such a lens by a line formed by a point where the value of the cylinder is half of The addition is to have a width greater than 14.5 mm at the point of reference for the close-up sight. 2. 8. Lens according to claim 25, where the said remote sight zone is established. It comes in the upper part of the lens by the line formed by the point where the value of the cylinder is half. One of the additions is the containment capacity, at least with one angular sector formed by The two upward-facing semi-infinite lines that begin at the geometric center of the lens and have The angle between the two sides, determined to be at least 150 ํ 2. 9. Lens according to claim 25, where the value of the cylindrical shape at the surface of the lens is Less than the addition of power 3.0. Lens according to claim 29, where the cylindrical value at the surface of such a lens is less than 90% of the addition of power 3. 1. Lens according to claim 25, where the difference of the maximum cylindrical value at the two parts of such lens that is delimited by the main meridian of progression is less than 0.1 dions. Pointer 3 2. Lens according to claim 31, where the difference of the maximum cylindrical value at the two parts of such lens that is delimited by the main meridian of progression is less than 0.05 dions. Pointer 3 3. Lens according to claim 25, where this lens will be a multi-focus lens made For close-up and short-distance tours The lens will have additional power. Defined as the difference between the maximum and the minimum of the average sphere on the following meridian. Say of progress within a circle with a radius of 20 mm centered on the center of the path. Geometry of such lenses 3 4. Lens according to claim 33, where the main length of the progression will be fixed. It is the ratio between the addition of power and the maximum of the slope of the average sphere, Pmer, along the aforementioned meridian 3. 5. Lens according to claim 25, where such a lens is a multi-point, step light. The reference point for the near-field observation area. The reference points for the remote viewing area and the set enhancement are the result of the average sphere values at these two points. 6. Lens according to claim 35, where the main length of the progression will be fixed. Is the difference of the altitude between the y-axis of the integral center and the y-axis value of the points on the meridian, where the average spherical value is equal to the sum of the values of the average sphere at the point Reference for remote viewing plus 85% of the said addition 3. 7. Lens according to claim 25, where the main length of this progression will be 12.4.