CN1471651A - Wide field spherical lenses and protective eyewear - Google Patents

Wide field spherical lenses and protective eyewear Download PDF

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Publication number
CN1471651A
CN1471651A CNA01818197XA CN01818197A CN1471651A CN 1471651 A CN1471651 A CN 1471651A CN A01818197X A CNA01818197X A CN A01818197XA CN 01818197 A CN01818197 A CN 01818197A CN 1471651 A CN1471651 A CN 1471651A
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China
Prior art keywords
lens
glasses
edge
diopter
spherical
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Granted
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CNA01818197XA
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Chinese (zh)
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CN1303452C (en
Inventor
迈克尔・A・莫里斯
迈克尔·A·莫里斯
M・派罗特
科林·M·派罗特
J・爱德华
西蒙·J·爱德华
に蛊绽滋
雷·S·斯普雷特
L・达
戴维·L·达
�・叶
布兰登·叶
・亚当斯
布赖恩·亚当斯
克・贝格利
帕雷埃克·贝格利
・布莱克
理查德·布莱克
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Carle, Zeiss, Phenix Optical Company Limited
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Sola International Inc
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Priority claimed from US09/698,270 external-priority patent/US6682193B1/en
Application filed by Sola International Inc filed Critical Sola International Inc
Publication of CN1471651A publication Critical patent/CN1471651A/en
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Publication of CN1303452C publication Critical patent/CN1303452C/en
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    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C7/00Optical parts
    • G02C7/10Filters, e.g. for facilitating adaptation of the eyes to the dark; Sunglasses
    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C7/00Optical parts
    • G02C7/02Lenses; Lens systems ; Methods of designing lenses

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  • Health & Medical Sciences (AREA)
  • Ophthalmology & Optometry (AREA)
  • Physics & Mathematics (AREA)
  • General Health & Medical Sciences (AREA)
  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Eyeglasses (AREA)
  • Surface Treatment Of Optical Elements (AREA)
  • Optical Filters (AREA)

Abstract

The present invention relates to novel ophthalmic lens elements (402, 404) and eyewear (400) having wide field of view, low distortion, improved astigmatism correction where required and enhanced eye protection properties. Series of lens elements have steeply curved spherical reference surfaces. The edged lenses of the series have approximately consistent aperture size, shape and hollow depth across a range of common prescriptions. Novel sunglasses, laser protection eyewear, and lens edgings, coatings, and frames are included in the invention.

Description

Wide visual angle spherical lens and protective spectacles
Technical field
The present invention relates to improved ophthalmic lens assembly and glasses, comprising requiring lens (prescription lenses), glasses, sunglasses, laser protection eyewear, so also comprise picture frame, plated film and side cut.
Background technology
Most of conventional need lens have the baseline (base curve) of relatively flat.Because the restriction of marginal distortion and/or physical size, these lens provide limited visual angle.The shape of their relatively flats has limited the eye protection that lens can provide, especially near temporal part.
People have been developed annular glasses so that wideer visual angle and more eye protection to be provided.Annular design also allows to realize different even distinct pattern.Yet annular glasses are typical non-requirements (non-prescription).The typical flat baseline of these products is between 6 to 10D.Its annular shape (being rake shape shape sometimes) is by realizing at the optical axis of wearing direction rotation and/or translated lens.For example referring to the U.S. Patent No. 1,741,536 that belongs to Rayton; The U.S. Patent No. 5,689,323 that belongs to people such as Houston.This has caused wearer's sight line to depart from optical axis, and optical property then can be had a greatly reduced quality.The visual effect of marginal portion is very poor usually.
Early stage in the ophthalmology development history, the lens that require of precipitous bending were described, although it is not for providing big visual field or eye protection to occur in this description.Flexibility (curvature) and the relation that sees through diopter (through power) are represented with so-called " Tscherning ' s " ellipse.Before the such description of first example appeared at nearly 100 years, it attempted to determine to access the lens flexibility of minimum aberration and the combination between the lens strength.Fig. 1 has shown the general shape of Tscherning ellipse.Fig. 1 obtains under the situation of supposition lens canonical parameter value, and these canonical parameters have refractive index, vertex distance, lens thickness etc.This Tscherning ellipse is for different lens parameter assumed values, and elliptical shape and vergence direction are constant, but oval exact position of going up point may change.Ellipse among Fig. 1 is to obtain by the distance from von Rohr equation (after Morgan) the derivation point focusing (zero astigmatism) revised.
Oval the latter half 10 is so-called " Ostwalt parts ", and this part has been described the front surface of a relatively flat and selected, and described front surface is used to realize the diopter (power) of typical conventional need ophthalmic lens.The first half 12 of curve is known as " Wollaston part ", and it has been described curvature and has wanted much bigger lens, and this kind lens never are accepted as lens type, although the trial (Wollaston) of realizing this goal was once arranged in history.Referring to M.Jalie, The Principles of Ophthalmic Lenses p, 464 (4 ThEd.London, 1994).Because the difficulty on making, early stage this kind of lens only might be little openings, so not being accepted of it may be exactly because reason attractive in appearance and limited visual field.
Modern lens with precipitous crooked spherical anterior surface are manufactured to be used for lacking the crystalline lens treatment of (as lack the natural lens of eyes under the situation of surgery excising operation).Fig. 2 has represented the general shape of this lens.Referring to M.Jalie p.151.This lens are the substitute as lens in the eyes in essence, and this lens characteristics is big thickness and high positive diopter (be higher than+5D, representative value is at+12D or higher).The opening A's of this lens is small-sized, and for example diameter is 26 or 28mm.This that uses when typically lacking crystalline lens kind of lens have a planar radial edge 14.
Today, most conventional need lens are relatively flat, monoscopic, belong to Ostwalt part, meniscus shaped lens, and it is just as the windowpane that is installed in the smooth spectacle-frame outline.
The glasses of traditional Ostwalt part are capped sometimes, processing or plated film to be to provide special reflection or antireflective properties.What know the most is sunglasses, and it provides the optionally rete of stop portions incident light spectrum.Some this lens is designed to produce the color that the observer likes, and this realizes by optionally selecting or absorbing incident light spectrum.This rete can comprise the metal oxide of metallic mirror layer and/or multi-layer vacuum evaporation or sputter coating.For example, belong to the U.S. Patent No. 2758510 of A ü w  rter disclosed the plated film of sunglasses.As another example, the U.S. Patent No. 4070097 that belongs to Geller discloses certain multi-layer anti-reflective film.Also can be referring to U.S. Patent No. 5719705 and No.5959518.Traditional Ostwalt part also is used for protecting the wearer to prevent intensive ultraviolet or infrared radiation or laser beam by plated film especially sometimes.
Summary of the invention
The applicant had studied the characteristic of precipitous curved lens, and think the lens of a series generally have requirement plus or minus see through diopter.The applicant observes this lens can provide wide visual field and eye protection on principle.Yet some problem has been disturbed the realization of this lens covering a wide angle of field.In general, exist to make and the problem of distortion, and requiring has that common plus or minus is dioptric to have or do not have lens that common astigmatism is corrected or " cyl " requires in the production certain limit, also is a problem.
A more delicate problem is the dioptric wide region of front surface, needs it can provide one to require dioptric scope jointly.For example, among Fig. 1 about the setting of lens, the Wallaston part just is understood as that: see through diopter in the+5D scope to-8D in order to realize product, the diopter variation range of front surface is exactly to about 20D from about 15D.This range of curvature radius corresponding to front surface should be from about 29 to about 39mm, and overall dimension and shape of these expression lens have bigger variation to realize the enough big lens that wide visual angle can be provided.This lens can not be installed in the single frame size as window is installed, and in fact, each requires self all can require its own special frame size and pattern.Du Te pattern has its value like this, but they are inconsistent with a large amount of glasses commodity of unified profile are provided.
A total target of the present invention is to provide the ophthalmic lens with good visual characteristic.
The precipitous curved lens series that provides one to be easy to produce and market is provided another target of the present invention.
The ophthalmic lens that provides one to have good visual characteristic owing to wide visual angle is provided another target of the present invention.
Another target of the present invention is to provide an edge region to reduce the precipitous curved lens of distortion.
Another target of the present invention is to provide the glasses that can provide how effective glasses protection.
Another target of the present invention is to provide the precipitous curved lens with common diopter and astigmatism requirement.
The precipitous bending of use that another target of the present invention is to provide the requirement for certain limit to have unified profile and framed structure requires the glasses of lens.
Some other advantage will be by being understood of the present invention telling about.It is sightless (apparent non-flanged) to the wearer that the visual angle that increases can make the edge of glasses exist actually.The present invention can also reduce enlarge-effect in some precipitous curved lens and relevant distortion.
Other advantage comprises to eyeglass design person and is provided at the selection that has the lens of fine edge visual characteristic under the multiple requirement, this selection be up to now can not obtain.This comprises the ability of using little frame lens, from layout and all very attractive three-dimensional bending rims of the lens and the eyes frame of angle attractive in appearance, and visually is more prone to the edge thickness and the surface that hide.
Other advantage comprises that providing novel can provide required aesthetic and the certain reflection and the sunglasses and the protective spectacles of antireflective properties.
The object and advantage of these and other will be from hereinafter and become clear the description of the drawings.
In general, the present invention relates to glasses, so also just relate to the ophthalmic lens assembly.According to this paper, the ophthalmic lens assembly can comprise the ophthalmic lens of finishing or cut edge, and half-done lens are so also comprise lens mould or mould.Also comprise the thin slice that is used for forming stratiform lens or lens mould in addition.
Fig. 3 is an example of the present invention, and it has represented some geometric properties of precipitous crooked homocentric lens among the present invention.Fig. 3 represents the horizontal sectional view of a left eye and right eye (being respectively 20 and 22).Each eye has a rotation center, 24 and 26.Rotation center can be understood that intraocular a part of volume, and it has the diameter C that is approximately 1-2mm D, eyes present the motion around this rotation center rotation when direction of gaze changes.As shown in Figure 3, the precipitous curved lens 28 and 30 in the left and right sides is placed near the eyes.In the drawings, the optical axis of each lens is that this point is represented with line 32 and 34 respectively in each eye with the sight line conllinear of each eye.These lines have also been represented the z axle (the x-y plane is perpendicular to plane, figure place) of the coordinate system that hereinafter adopts in order to describe lens surface.
Lens 28 and 30 generally can be described as spherical or ball base.In a preferred embodiment, front surface is spherical, and it has the radii fixus less than 35mm for all required values in the series.In another embodiment, lens preferably are described as has spherical rear surface, and this is just as comprising that a reference sphere or picture place among the fixing spherical shell.In each case, the position during the wearing of the radius of reference sphere or shell and lens all makes the centre of sphere of reference sphere or shell drop on the inside of the near zone or the rotation center of eyes rotation center.Left eye among Fig. 3 has represented that front surface is that radius is the sphere of R and the situation that the centre of sphere is positioned at the left eye rotation center.
Be positioned at for given radius and the centre of sphere eyes rotation center or near ball base selectional restriction vertex distance d v, the left eye among the present Fig. 3 of this distance table is exactly the distance between pupil plane, 36 place and the lens rear surface 38.Hereinafter will describe the shape of front surface radius and rear surface in detail, and other design parameter correspondingly, such as the refractive index of the lens material of lens thickness, decision optics of lens characteristic.
The applicant has been found that lens design of the present invention can analyze and describe with the data array of type shown in Figure 4.This figure is known as according to two name among the inventor " Morris-Spratt " figure.
In the drawings, every some center that all is positioned at theoretical light line tracking figure, this theoretical light line tracking figure comes from the lens that have the lattice point characteristic in every dot center.It is the diopter (refractive index is got the normal value of n=1.530) of the lens front surface of unit that right-hand member " y " axle has provided with diopter (diopter).Bottom " x " axle is represented the diopter that sees through of lens center.This is corresponding to the diopter requirement of lens plus or minus.For this figure, each lens all supposes with the polycarbonate to be material (n=1.586), and for negative diopter lens, its center thickness is 1.8mm, and for the positive diopter lens, its center thickness requires decision separately by each, is that the minimum value of the overall lens thickness in edge in the lens mould of 58mm is 1mm at diameter like this.Each lens is positioned at and makes the position of its front surface apart from eyes rotation center 33.1mm, and lens are homocentric and have the front surface diopter of 16.0diopter with rotation center here.
Expression has owing to eyes go to the ray trajectory that 40 degree produce on each lattice point.Dark space on each lattice point represented each require relatively to have less than the root mean square diopter error of 0.125diopters and allow the lens of the range of adjustment of 0.375diopters at the most.Root mean square diopter error will award mathematical definition hereinafter.This standard is be sure of to be to weigh a good sign of lens performance.
The circle representative of complete filling has lens less than the root mean square diopter error of 0.125diopters when eyes among Fig. 4 when all directions rotation 40 is spent.For those points that surround with ring, root mean square diopter error rises to more than the 0.125diopters during eye rotation angle in the middle of some, falls back below the threshold value in some low-angle zones again then.
Those local oval outlines of maximum point are substantially corresponding to a Tcherning ' s ellipse, and this ellipse produces according to the selected special lens parameter of applicant.Traditional viewpoint asserts that the front surface of sphere lens (lens with spherical anterior surface and rear surface) must follow Tcherning ' s ellipse to obtain high quality lens.Yet Morris-Spratt figure shows, for the lens parameter of suitable selection, exist among the figure one almost the zone of level can be used for making high-quality lens.People know can make the plane sphere lens (zero vertical curve that sees through near the large scale point composition the diopter has illustrated this point) with high optical quality in very wide front surface curvature range.Many such lens can obtain on present market.The new thought that Morris-Spratt figure is showed is, can utilize single precipitous curved front surfaces or spherical reference surface or spherical shell, makes high-quality sphere lens in certain claimed range by suitable selection lens parameter.It should be noted that for having used the lens of diopter as the front surface of 16diopter (capable number 40 lattice point), at least in-6 to+4diopter scope, its low root mean square diopter error band has very wide angular range (being almost complete or full week).Surpassing 95% during all require all drops in this scope.So, can in the requirement of a wide region, utilize high diopter front surface or camber line single, suitable selection, produce high-quality ophthalmology sphere lens.In addition, as what Fig. 4 expressed, some little deviation of single relatively diopter or accurate concentricity can occur, thereby but still can provide good lens quality and enough lens shape consistance can use same framework pattern.
Fig. 5 has represented a series of lens with high optical quality of the preferred embodiment of the present invention.Among this embodiment, front surface is selected as about 16 ± approximately 1/2D again.This scope drops between horizontal line 50 and 52.Especially, preferred embodiment provides a series of lens, and described lens are in-2D is to+2D (zone 54), and-6D is to+4D (zone 54 and 56), or-requirement of 8D in+5D (zone 54, the 56 and 58) scope.
In order to reach the purpose of contrast, partly be superimposed on Fig. 5 for the Wollaston of the Tscherning ellipse 60 of this particular case.The figure shows the represented front surface flexibility of horizontal block and seen through diopter scope and said the misfitting of Tscherning ellipse, according to the Tscherning ellipse,-8D changes to the front surface that diopter should corresponding 5D that sees through of+5D, and in the central authorities that see through the diopter scope a very steep curve should be arranged.
The preferred embodiments of the present invention comprise a series of lens subassemblies, these lens subassemblies are by the single reference sphere definition homocentric with the rotation center of wearer's glasses, the radius-of-curvature of ball arrives in the scope of 50mm 25 herein, more advise arriving in the scope of 35mm 30, best recommendation is about 33mm ± about 1mm.
Advantageously this a series of lens subassembly provides the diopter of suitable requirement and cyl to correct.At front surface is among the embodiment of sphere, and diopter and cyl that the rear surface is configured to provide suitable correct.In a preferred embodiment, the lens subassembly of a series can comprise that above-mentioned is 1/4D through diopter scope and increment.Can provide to have every kind of usually each dioptric lens subassembly of requiring of astigmatism, be increment from 0D to-2D with 1/4 for example.Will be understood that because the ball symmetry of lens subassembly, the angle that cyl corrects can obtain selecting by the suitable rotation when edging and the assembling.
Traditional astigmatism correction is based on double-curved surface (toroid surfaces), this double-curved surface is described through principal meridian (principle meridia) commonly used, just is positioned at the quadrature meridian (orthogonal meridia) of the minimum and maximum flexibility of lens axis central authorities representative position.Barrel-shaped double-curved surface and annular double-curved surface all once were used to provide cyl to correct.To tell about as following, the applicant has been developed the new astigmatism that is used for precipitous curved lens and has been corrected face, and this correction face can be described as and have identical principal meridian and along principal meridian between identical dioptric barrel-shaped double-curved surface and the annular double-curved surface.These two kinds of curved surfaces are following " complete circular meridian " surface and " average double-curved surface " surfaces told about in detail.
The shape of lens of the present invention will be described now.Noun used herein " precipitous flexibility " is the overall shape that is used for describing lens or reference sphere or shell.In object lesson, flexibility can be quantized into the mean radius of curvature that is positioned at lens or curved surface outer or that comprise lens surface or spherical shell.
The feature of the general shape of lens of the present invention also is them with great visual angle, and this is often expressed as optical axis and the most close temporal edge or the angle between the edge of close nose.Corresponding to the preferred embodiments of the present invention, the central authorities of spherical surface are that an angle is opened at the center before the lens, and this angle is greater than 80 °, in a preferred embodiment greater than 100 °.Because lens optically are available at these fringe regions, just be appreciated that these angles are performances of lens coverage certainly.
The feature of the unique layout shape of lens can be thought radial depth or " hollow " degree of depth that is it among the present invention, and this generally is that lens and the three-dimensional degree of rims of the lens one measures.As mentioned below, these degree of depth relate to the distance of frontoparallel plane and the most close temple marginal point.Corresponding to the preferred embodiments of the present invention, have the mean radius that is no more than 50mm, the centre of sphere is positioned at the degree of depth eyes rotation center and hollow and has at least the lens of 8mm to exist.In a particularly preferred embodiment, the radius of front surface is about 33mm ± about lmm, and the hollow degree of depth has 10mm at least.
The method that requires glasses (prescription eyewear) that provides also is provided in the present invention.These methods have adopted the lens subassembly with precipitous flexibility.Preferred embodiment adopts and to be positioned at thickness and to be no more than the front surface that 2mm and radius are no more than the spherical shell of 50mm.A rear surface is formed in the lens corrects so that lens subassembly has the astigmatism that sees through a diopter and a requirement of a requirement.Lens subassembly makes the centre of sphere of spherical shell drop on respect to wearer's position or near the rotation center of eyes, this is to realize by lens being fit in the framework that has with the corresponding normal window of spherical shell radius, and this spherical shell has and differently sees through diopter, comprises that to formulate dioptric lens subassembly common.These glasses provide the diopter and the astigmatism that require to correct in wearer's whole fixed viewpoint.
The present invention also comprises the frame of particular design.In a preferred embodiment, frame is suitable for a series of ophthalmic lens, and it is 25 to the spherical surface of 35mm that each lens has a single radius, and one is selected to cooperate with spherical surface the second surface that multiple general requirement is provided.In a preferred embodiment, framework is adjusted with carries left on one's body the wearer and right lens, makes the centre of sphere of spherical surface drop on respectively or near the rotation center of left eye and right eye.Frame can comprise the marginal portion of temple part and contact left and right sides lens.The marginal portion of getting in touch each lens can have such shape: the closed camber line with described spherical surface radius radius about equally of having that is positioned on the reference sphere.In such frame, the point of close nose and the most close temporal point can open one section greater than 90 ° camber line about the center fixed point of spherical surface on the closed camber line.
This frame may comprise a left temple part, a right temple part and a nose bridge.In a preferred embodiment, the length of nose bridge is adjustable, and it has allowed the horizontal adjustment of lens distance so that the centre of sphere of spherical surface is positioned at the rotation center of eyes.In other embodiment, the non-flanged framework is also in company with annex with support being hinged together of temple part and provide, and hinged can the adjustment realizing directly connects the reference spherical surface at the close temple edge that is positioned at each lens.
The present invention also comprises the new type lens frame, and this frame can be used for precipitous flexibility lens, and especially those have at least one radius-of-curvature at the lens of 31mm to the spherical surface between the 33mm.
In this case, almost the spherical surface with lens is vertical at the edge of lens.The glasses made from this lens can be unskirted, and edge surface is invisible in essence concerning the wearer, this be because when the wearer when a direction is watched attentively, edge surface is similar to and is positioned on wearer's the sight line.In addition, the observability at observer edge also has been reduced to external world.This edge can produce with the grinding machine around the axle rotation of joining with the spherical surface center.In a preferred embodiment, edge surface is cut so that it opens a little camber line about the arc centers of spherical surface, and this camber line is positioned at the arbitrary plane that comprises lens axis.
The present invention also comprises the method that is suitable for the precipitous flexibility lens subassembly of assembled glasses of making.This method may comprise makes the lens mould with a radius-of-curvature, its radius-of-curvature corresponding to principal meridian in its part of front surface less than the situation of 35mm.After grinding tool was made, the rear surface was cut out on the lens mould, and these and front surface provide the requirement of a non-zero to see through diopter together.At last, the lens mould is cut edge to provide one to have the maximum hollow degree of depth at least at the lens of the side cut of 8mm.Rear surface of having cut and front surface can be designed to the wearer together provides the astigmatism of a non-zero to correct.
In one embodiment, the front portion of lens mould is added with progressive additional surface diopter.As selection, cut the rear surface that progressive additional surface diopter also can be added in the lens mould.
Others of the present invention relate to the sunglasses of precipitous bending, such as above-mentioned lens with radius of spherical optical surface less than 35mm.This sunglasses manufacturing is the method that has adopted the precipitous flexibility coating of lenses of the present invention and/or dyeing.In a preferred embodiment, an optical surface (for example front surface) can be coated with partial reflection deielectric-coating group, and this generally is blue in special preferred embodiment.Surface coating may be by refractive index height and the low layer multilayer film that utilizes sputtering sedimentation that interlocks and occur and form of refractive index.Especially the film group of being made up of silicon and zirconia layer can form surface coating, wherein has at least layer of zirconia thickness to surpass 10nm.The design of rete makes that its reflectivity begins to descend and keep low relatively value until the near-infrared region always when lambda1-wavelength surpasses about 480nm.
The invention still further relates to and comprise a left side with spherical surface and the protective spectacles of right lens.Each spherical surface suggestion has the radius-of-curvature between about 31mm and 35mm.Framework is being supported lens so that the centre of sphere of the spherical surface of left and right sides lens roughly lays respectively at the rotation center of right and left eyes in wearer's face.
Multicoating can be formed on each lens, stops that in order to part the radiation that is incident on the lens arrives eyes.These retes have the part of the incident radiation spectrum that is used for stopping that at least at least one is selected through the refractive index of selecting and thickness.In the embodiment of sunglass lens, ultraviolet light is stopping by part at least.Protection to laser emission also can provide by the glasses in industry or the military equipment.In this case, plated film and/or dyeing are used to stop the laser in the selected spectral range.Especially, the infrared laser radiation can partly be stopped at least.Incidenting laser radiation is stopped fully so that its power level drops to a safety value.The incident radiation of off-axis is stopped that by film layer group the color of being dyed absorbs, and/or have one and can not arrive amphiblestroid light path.
In protective spectacles embodiment of the present invention; such advantage is arranged: each lens extends to the temple edge in eye socket zone from the nasal margin in eye socket zone; and extend to coboundary from the lower limb in eye socket zone; so just can stop and to arrive amphiblestroid radiation, offer the visual angle of a broadness of wearer simultaneously again from all directions.
Content noted earlier is just as a general introduction of the present invention, and scope of the present invention will be by deciding in claims and about its strict language of content of equal value.
Description of drawings
Fig. 1 is the oval figure of a Tscherning;
Fig. 2 is the sectional view of a prior art, high positive diopter " rotoid " lens;
Fig. 3 is the cross-sectional top view of a pair of human eye, and wherein lens dispose according to a preferred embodiment of the invention;
Fig. 4 is a Morris-Spratt figure who has described corresponding to the said series of lenses characteristic of the present invention;
Fig. 5 be one select about front surface curvature with according to the present invention see through dioptric graph of a relation, this figure also is superimposed with the part of the Tscherning ellipse under this particular case thereon;
Fig. 6 (a), (b) and (c), 7,8 and 9 have represented the many aspects of the lens subassembly geometric properties in the embodiment of the invention;
Figure 10 (a), 10 (b), 10 (c) and 10 (d) compare the visual angle of traditional 6D lens example and lens of the present invention and lens subassembly;
Figure 11 (a) and (b) show when on the precipitous crooked sphere lens that is added in the principal meridian shown in (c) that has Figure 11 traditional endless and barrel-shaped toric surface astigmatism;
Figure 12 (a)-(d) is tangential and the figure of radial surface diopter during as the function of annular among Figure 11 and barrel-shaped toric polar angle;
Figure 13 (a), 13 (b), 14 (a) and 14 (b) be tangential and the radial surface diopter as wholecircle shape meridian among the present invention and the average figure the during function of the polar angle on double-curved surface surface;
Figure 15 and 16 has utilized the surface astigmatism equivalent curve figure on lens subassembly of the present invention surface;
Figure 17 (a) (b) and (c) has represented a target gridding and its picture;
Figure 18 is a sectional view that can be used to make a mould of lens subassembly in the embodiment of the invention;
Figure 19 (a), 19 (b), 19 (c), 19 (d), 19 (e) and 19 (f) have comprised these figure: root mean square diopter error, distortion, to the low curved lens of three tradition and three according to precipitous curved lens assembly of the present invention the light grid computing;
Figure 20 (a) and 20 (b) have comprised these figure: root mean square diopter error, distortion and to having the tradition toric precipitous curved lens in back and to the light grid computing of wholecircle shape meridian rear surface;
Figure 21 and 22 has compared traditional 6D progressive lenses and the equivalent curve figure according to 16D progressive lenses of the present invention;
Figure 23,24,25 and 25 (a) have represented outward appearance, side cut, the assembling aspect of lens subassembly of the present invention and used frame;
Glasses embodiment of the present invention planimetric map during Figure 26;
Figure 26 (a) is the detailed view of embodiment among a Figure 26 who shows annex, hinge and a side cut lens arrangement;
Figure 27 (a)-(d) has represented to be applied to a plurality of rims of the lens surface in the preferred embodiment of the present invention;
Figure 28 is the cut edge synoptic diagram of lens of a present invention who has represented edge thickness;
Figure 29 (a)-(c) has represented multiple lens side cut technology; And
Figure 30 (a) is the sectional views of a plurality of lens when having incident ray to be mapped to their front surfaces (b) and (c);
Figure 31 and 32 is the plated films for multiple expression feature of the present invention, and its reflectivity is to the lambda1-wavelength graph of a relation; And
Figure 33 and 34 is examples of the optical density (OD) figure of rejection filter example in the preferred embodiment of the present invention.
Embodiment
Summary
I. the basic geometry of lens.
II. astigmatism is corrected.
That III. amplifies and distort alleviates.
IV. lens manufacturing.
V. the calculating gained characteristic of lens design example.
VI. lens that assembled and frame.
VII. plated film, solar lens and protective spectacles
I. the basic geometry of lens
The basic geometry of the lens that at first discussion are pursuant to the present invention and make.Forward sight, side-looking and the top view of the lens 100 after Fig. 6 (a), 6 (b) and 6 (c) have represented respectively to cut edge according to the present invention.Initial point 102 among Fig. 6 (a) is optical centre places of lens, also is the place, design centre of pupil when wearing.The outline 104 of side cut lens is shown in the front perspective view among Fig. 6 (a).The temple edge 106 and the nose edge 108 of expression lens among Fig. 6 (b).The coboundary 110 and the lower limb 112 of Fig. 6 (c) expression lens.In the lens embodiment of Fig. 6, the front surface of lens is precipitous spherical bendings, and its rightmost is represented with line 114.
The precipitous spherical bending of the embodiment of the invention can be implemented in the lens by a lot of approach designs.In above preferred embodiment, the front surface of lens subassembly is a single radius ball, and its centre of sphere is located on or near the eyes rotation center.As an alternative, the rear surface of lens subassembly series can be a constant precipitous spherical surface, and its centre of sphere is located on or near rotation center.In these embodiments, another surface has variable flexibility, and the selection of flexibility should be able to provide the suitable diopter that sees through at least to the wearer.For example, if lens series has been selected the spherical anterior surface of 16D, for provide-4D see through diopter and-cyl of 2D, the principal meridian of rear surface just should have the flexibility of 20D, and secondary meridian should be 18D.As selection, if the constant radius surface of lens subassembly is positioned at the back face, it just can be front surface that then corresponding selection provides the surface of certain requirement.
In other alternative embodiments, lens subassembly or surface are limited within the spherical shell.Fig. 7 has represented this geometric properties.Centre of sphere P and two radius r 1And r 2Two homocentric spheres 154 and 156 have been defined, wherein r 2>r 1These balls have defined shell S together.Lens 158 are expressed has the most close nose edge point Q and the most close temple marginal point O.A front surface 160 of lens is positioned at shell S.
Front surface according to optical lens module of the present invention can be a sphere, toric or rotate symmetrical aspheric curved surface.In order further to improve visual effect, can depart from spherical so that improved optical appearance and/or aesthetic appearance to be provided according to surface before or after the lens subassembly of the present invention.Before or after above-mentioned can derive by separating of optimization problem in the surface, and this optimization problem is intended to try to achieve the minimum value of the fundamental function (merit function) of representing the optical distortion that lens wearer can see.In addition, as selection, this correction can improve the aesthetic appearance of lens.Replacedly, the surface in the shell can be many focuses progressive lenses, and this will tell about hereinafter in detail.
In a preferred embodiment, radius r 1And r 2Difference be not more than 2mm, and in an embodiment who is more preferably, one in the radius is 33mm, and r 1And r 2Difference be approximately 0.1mm or littler.Front surface subtended angle OPQ is greater than 75 °, and is suitable to 90 °, preferably greater than 100 °.This angle is measuring of the lens visual angle that can provide.
Replacedly, the lens mode that can be defined with similar Fig. 7 is positioned at shell, wherein r entirely 1And r 2Difference less than 6mm.
In addition, and be replacedly, lens may be defined as the sphere that comprises one section precipitous bending, are r as radius among Fig. 7 1The OQ section of ball.Reference sphere can be the ball between the lens subassembly front and rear surfaces.In an embodiment of the present invention, the ball of this precipitous bending can define the adjacent surface of two lens, rather than defines by U.S. Patent No. 5187505, and above-mentioned patent is included in as a reference.In this case, ophthalmic lens or lens mould are that interlayer as the front and back sheet forms.Because the adjacent surface of lens is spherical, can be rotated to realize that desired one of them surperficial cyl that is added in corrects sensing so be appreciated that lens.This is providing the asymptotic expression lens to be particularly useful.
Fig. 8 has represented the others of the novel geometric configuration of lens subassembly of the present invention.One has precipitous spherical crooked lens 170, and the rotation center 172 of the eyes of making peace greatly is homocentric.The spherical anterior surface 174 of frontoparallel plane P and lens is tangent.The optical axis 176 of lens is perpendicular to plane P and the rotation center by eyes.The rear surface is determined with label 178.Lens are extending to temple edge 180 to temporal direction.The novel geometric configuration of lens is partly by hollow degree of depth Z HDefine, this degree of depth refers to the vertical range of lens rear surface 178 between optical axis place and edge 180.A relevant size Z FIt is the distance between frontoparallel plane P and the edge 180.
Edge optical characteristics to lens of the present invention is useful such as the consideration that distorts.In the case, can be in the cone of φ or outer lens peculiarity with reference to the half-angle that becomes with optical axis O among the figure 9.In Fig. 9, θ is expressed as one 30 ° angle.In a preferred embodiment of the invention, lens subassembly series has a surface astigmatism less than 0.125D, and this is to obtain by a taper that is at least 25 ° θ definition.
A lens subassembly of the present invention for the root mean square diopter error (hereinafter providing definition) of foveal vision the eye rotation angle less than 30 ° situation under, can be less than 3/8D.And this lens subassembly for the root-mean-square error of foveal vision the eye rotation angle greater than 30 ° and less than 40 ° situation under, can be less than 1/2D.At last, this lens subassembly for the root-mean-square error of foveal vision the eye rotation angle greater than 40 ° and less than 50 ° situation under, can be less than 3/4D.
In a preferred embodiment, lens subassembly can dispose like this: for the peripheral vision of eyes when rotating and being fixed on 30 ° of angles, root mean square diopter error to point of fixity ± 5 ° the time less than 3/8D; Root mean square diopter error to point of fixity ± 10 ° less than 0.65D; And root mean square diopter error to point of fixity ± 30 ° less than 1.0D.
Figure 10 represented feature of the present invention and with the comparison of conventional lenses.Figure 10 (a) has represented a conventional lenses and according to the plan view profile of a precipitous curved lens of the present invention.Figure 10 (b) has represented traditional 6D lens 200, and Figure 10 (c) has represented one corresponding to 16D lens 202 of the present invention, and the both has the same face profile shown in Figure 10 (a).The apparent visual angle is to be that angle between the marginal ray at center is measured in order to the C of pupil center in the pupil plane.Tradition 6D lens 200 have about 105 ° visual angle and lens 202 have about 130 ° visual angle.If adopt a bigger lens mould and a design profile, can produce the lens 204 of the 16D of size shown in Figure 10 (d).These lens can extend horizontally to the temple edge 208 of eye socket from the nose edge, and this has produced an about visual angle of 170 °.These lens can not have the temple edge that can be seen by the wearer after direct assembling.In addition, temple place rims of the lens thickness 210 is not easy to be observed by other people, and this is that this has also just improved the aesthetic of lens because it is recurvate.At last, the rear surface 212 of lens can not hinder the eyelashes of normal length for the requirement of a wide region.
II. astigmatism is corrected
Precipitous crooked sphere lens according to the present invention has proposed special problem when cyl corrects one of the requirement become the wearer.Common multiple rear curved surface can not provide acceptable performance.Specifically, common multiple rear curved surface can not well be worked at the edge of precipitous curved lens.
For a cyl Rx (ignoring situation about tilting such as light), desirable rear surface should have a constant surface astigmatism that is adapted to require.Such surface is non-existent.Double-curved surface is can make approximate to this ideal situation.Have two kinds of toric types, they are called as annular double-curved surface and barrel-shaped double-curved surface usually.Each all obtains by sweeping a circular arc around a stationary shaft.If radius of a circle is less than its ultimate range to stationary shaft, it is exactly an annular double-curved surface, otherwise is exactly a barrel-shaped double-curved surface.Two kinds of double-curved surface types all have circular cross section along two principal meridian places.Because this point (and symmetry), tangential diopter is correct everywhere on these meridians.In addition, every kind of double-curved surface all has one and makes radially correct " preferably " meridian of diopter.Being exactly low tangential diopter meridian for annular double-curved surface, is exactly high tangential diopter meridian concerning barrel-shaped double-curved surface.It is desirable zero that zero tangential and radial error means in preferred meridian upper surface astigmatism.
Traditional double-curved surface example in precipitous curved lens is shown in Figure 11 (a) and (b).For nominal 2cyl, two examples all under the line 180 degree meridian places have 18diopter (@n=1.530) tangential diopter, and have 20diopter at 90 degree places.The diameter of figure is 45mm, and isoline is 0.1diopter.Figure 11 (c) has schematically represented circular principal meridian curve C 1 and C2.Other " non-master " meridian can be defined as the radiant rays from central point, and this point will be understood.
Preferred axes among Figure 11 is tangible.Apart from center radius about 0,10 and 20mm, the tangential and radial surface diopter at angle 0 to 90 degree place is shown in Figure 12 (a)-(d).
Can notice that from figure annular and barrel-shaped multiple comprehensively spending 0 and 90 all has correct tangential diopter for all radiuses.The annular double-curved surface has correct radially diopter at 0 degree place, but 90 degree places have with radius and increase error.Barrel-shaped double-curved surface has correct radially diopter at 90 degree places, has with radius at 0 degree place to increase error.
About these double-curved surfaces some tangible asymmetry are arranged; They all have a preferred meridian.Yet have such function, it can keep correct diopter along principal meridian, but can handle radially diopter more symmetrically.It all is circle that the method that formation has a function of desirable tangential characteristic is forced along the cross section of every meridian.This function has such form z ( r , θ ) = R ( θ ) - R ( θ ) 2 - r 2
Wherein R (θ) is along the meridianal radius-of-curvature of θ, and r = x 2 + y 2 。The value of R (0) and R (90) is determined by desirable tangential diopter, and the diopter of intermediate angle is obtained by these endpoint value interpolation.A form of interpolation is from such discovery, and promptly above-mentioned diopter curve is a near sinusoidal.So the first approximation of a good R (θ) is
P (θ)=P (0)+(P (90)-P (0)) (1+cos2 θ)/2, and R (θ)=(n-1)/P (θ)
Wherein P is tangential diopter, and n is for diopter being converted into the refractive index of flexibility.In order to add more control, can when interpolation, add more Fourier terms to radial characteristic.In order further to control tangential characteristic, diopter can be expressed as the polynomial expression of r.Do not need the more freedom degree for a simple surfaces.Figure 13 has represented as the tangential of the function of angle in the above-mentioned double-curved surface and diopter radially.The tangential error of noting intermediate angle less than annular greater than barrel-shaped double-curved surface.It is also noted that radially diopter is correct for 0 and 90 degree when the r=0, but increase when radius, all begin to occur deviation more or less symmetrically at two meridians.For one be not axisymmetric surface, have one from of the faint contribution of tangent arc line angle to characteristic.This is because normal vector discord circular section is positioned at same plane.
The method of making the cyl correction surface of " non-deflection " is that traditional annular and barrel-shaped double-curved surface on average are in the same place.The result of this method be with make up with circular meridian surperficial similar.The toric angle figure that Figure 14 has represented average, wherein z=a BZ B+ (1-a B) Z D, Z is the surface elevation of lens, Z BIt is the barrel-shaped toric surface elevation of tradition; Z DIt is the toric surface elevation of traditional endless; And a BBe a weight factor, and 1>a B>0.That Figure 14 represents is a B=0.5 particular case.
Though be difficult for finding out from Figure 14 kind, these circular meridians and average double-curved surface surface tangential and radially diopter very big difference is arranged.Equal-value map among Figure 15 has compared the surface astigmatism of average double-curved surface and circular meridian function.This figure has the isoline of identical 0.1diopter and the 45mm diameter the same with preamble.
The astigmatic behavior on circular meridian surface is simpler than average toric.In order to represent to add to the angle interpolation effect of Fourier terms, an extra factor can be adjusted to " sphering " those oval-shaped isoline.This results are shown in Figure 16.Notice that meridian still has circular cross section, just the angle interpolation is by trickle change.
Circular meridian and average double-curved surface surface also have other famous characteristic.The surface astigmatism of any point beyond the principal meridian is the greater in barrel-shaped double-curved surface or the annular toric surface astigmatism less than same point.In addition, average double-curved surface or circular meridian surface are between the barrel-shaped double-curved surface and annular double-curved surface under the same requirement (Z value in the middle of having).
Although above-mentioned double-curved surface is preferably used the rear surface of lens in a preferred embodiment of the invention, also can in lens, use traditional double-curved surface or broad sense double-curved surface.
As selection, can provide the surface of lens subassembly of the present invention to correct by make the rear surface corresponding to the mathematical description of following symmetric polynomial: z = Σ k = 0,2 . . . n Σ j = 0,2 . . . k c k - j , i x k - j y j ;
The measurement of the optical aberration of some lens is defined as follows: = ( ( mpe ) 2 + 1 4 ( cyl error ) 2 ) 1 / 2
Wherein ε is the focusing error matrix, can write ϵ = ϵ 11 ϵ 12 ϵ 21 ϵ 22
Wherein can make ε by the base of selecting orthonomalization 1221
When the optical property of special consideration lens was calculated these, the average diopter error term of optics, optics Cyl error term and root mean square optical diopter item were suitable for.
According to the concrete application of optimizing lens, can select following fundamental function: M 1 = Σ θ ( rms blur ) θ 2 M 2 = Σ θ ( ( mpe ) 2 + ( cyl error ) 2 ) θ M 3 = Σ θ ( 1 16 ( mpe ) 2 + ( cyl error ) 2 ) θ
Figure A01818197002410
M 5 = Σ θ ( ( mpe ) 2 + 1 16 ( cyl error ) 2 ) θ
Wherein summation is done eye rotation θ.
At M 4In the situation, whether represent there are different fuzzy tolerance in " directly forward " position level, the vertical or rotation of tilting according to sampling point θ.This pattern can provide the popularization of some aspheric surfaces " minimum tangential error " layout strategy.
Pattern M 3And M 5Represented " minimum astigmatism error " and " minimum average B configuration diopter error " strategy respectively.
In a further embodiment, an expression lens item attractive in appearance can be included in the fundamental function.For example, do not use M separately, the fundamental function of a correction can be defined as M * = M + η θ λ 2 ( V πr 2 ) 2
η wherein θRepresent the eye rotation angle θ sample number of considering among the M, r is a specific lens radius, and V is the lens volume to the radius r place.Factor lambda is used for to the weighting of average lens thickness.
That III. amplifies and distort alleviates
Eyeglass lens dwindles or amplifies the object of observing by them.This situation be because the principal plane of traditional eyewear lens very close to lens, and does not overlap with the porch of eye pupil.In general, the positive diopter lens can make object seem bigger, and negative diopter lens can make object seem smaller.Amplify and also can change the object receive direction of visual field, edge, and cause the true visual angle of apparent visual angle and scioptics inequality.
Except amplifying, eyeglass lens also can make the object of seeing by them produce shape distortion.For the eyes of a direct-view, negative lens can produce one so-called " barrel distortion ", and the edge of the object of rectangle can show compressed appearance in this case, and this just looks like bucket.On the contrary, positive lens can produce " pincushion distortion ", and it can be dragged the outer holder of square angle.
These two kinds of effects and object size, shape and the position together can deterioration seen.The textbook of ophthalmic optics aspect thinks that the distortion of correcting eyeglass lens is infeasible, and never refers to the hope that reduces enlarge-effect.Yet an advantage of contact lens is the close enlarge-effect and the distortion effect of having reduced of lens and eyes, and this has just allowed more natural vision to correct.If possible, just wish to go to reduce the amplification and the distortion of eyeglass lens.
For a distant objects, enlarge-effect defines with following equation:
Figure A0181819700252
D (the d among Fig. 3 wherein v) be the distance of lens rear surface to the eye pupil porch, F vBe to be the back vertex power of unit with diopter, t is to be the thickness of unit with rice, and n is a refractive index, and F 1Be to be the front surface diopter of unit with diopter.
Part in the equation in first bracket is called " the diopter factor ", because it has represented to bring how many enlarge-effects by lens strength.If d can be zero, the diopter factor just equals 1 so.In other words, the enlarge-effect of being brought by diopter of the lens of and eye contact is very little, the situation of Here it is contact lens.Eyeglass lens is placed in the place that separates with eyes, avoiding contacting eyes, eyelid or eyelashes, so this to positive lens greater than 1 to negative lens less than 1.In other words, the positive diopter lens can amplify and negative lens can dwindle.Based on context, " enlarge-effect " both described amplification and also described and dwindle.
Part in the equation in second bracket is generally known as " form factor ", because it has represented how enlarge-effect changes with lens thickness and flexibility.If lens do not have thickness, t just equals zero so, and this just is 1.Three desirable rank optics " thin lens " can not have enlarge-effect because of shape.Contact lens is very near this situation, and this is because they can do extremely thinly.In fact eyeglass lens has suitable thickness to break preventing really, and positive front surface bending is always arranged, so this item is always greater than 1.In other words, positive falcate eyeglass lens can produce enlarge-effect owing to their shape.
In order to reduce enlarge-effect, equation must be configured to equal 1, so the product of the diopter factor and form factor is necessary for 1.Since the power factor of positive lens and form factor are all greater than one, their product can not equal 1, so there is not the positive lens of positive falcate can avoid enlarge-effect.In other words, negative lens has the diopter factor less than 1, and its form factor is greater than 1, so these factors are offseted.
In order to reach this target, we must find the solution this equation and satisfy separating of unit amplification.Through this step, we obtain following relation: t = - ndF v F 1 ( 1 - d F v ) . . . . . ( 1 )
This equation has determined to eliminate the lens thickness of glasses enlarge-effect.It is realized by place secondary principal plane in the eye pupil porch.To realize on a feasible thickness that this target needs two things: a negative lens strength and very precipitous camber line.
The III distortion
According to three rank theories, to such an extent as to distortion only just may be eliminated in the lens that very precipitous bending can't realize.Referring to Jalie, the The Principles of OphthalmicLenses 4 of M. ThEdition p.461.
In fact, three rank theories require the rear surface flexibility to surpass 35Diopters, and are promptly just almost homocentric in the porch of eye pupil; Such curved surface in fact is impossible.A real homocentric lens design, if two surfaces are homocentric about the porch of eye pupil, just do not have any distortion, this be because the symmetry of lens can guarantee all light from tilting body can run into from the same surface slope of central object light.Yet, we have found that smooth a little bending when having the combination of lenses of the principal plane that is positioned at the pupil porch, also can reduce distortion widely about the pupil extremely precipitous bending of homocentric needs that enters the mouth.This situation betides the negative diopter lens that design reduces to amplify, and causes lens more homocentric about the eyes rotation center.
In fact, wish very much can to produce,, thereby improve resolution characteristic because this can improve the symmetry of lens when turning to the visual angle, edge for eyes about the homocentric lens of eyes rotation center.If it is homocentric about the rotation center of eyes that we are strict with a surface of lens, we can derive a thickness of eliminating distortion really.In this case, just need be about the equation of a special shape of lens thickness.
For example, a front surface about the homocentric lens of eyes rotation center in, we can solve t, t represents with the distance of front surface radius, mounting distance, refractive index, back vertex power and pupil porch and eyes rotation center.In this case t = [ F v ( r 1 - K e + k 1 ) - 1 ] + ( F v ( r 1 - K e + k 1 ) - 1 ) 2 - 4 F v 2 d f k 1 2 F v . . . . ( 2 )
Wherein k 1 = ( nr 1 n - 1 )
Be a lens shape factor, r 1=front surface radius; d f=lens front surface is to the distance on plane, pupil porch; And K eBe the distance of the rotation center of the eyes shown in Fig. 3 to the eye pupil porch.
Figure 17 (a)-(c) has represented the advantage of this design.Figure 17 (a) is a macroreticular synoptic diagram of watching from great distances, and this grid opens miter angle about to the observer.Figure 17 (b) is a pattern that calculates that the people who wears tradition-5.00D lens can see: grid has diminished and distortion has taken place shape.Figure 17 (c) has represented the pattern that calculates that a people who wears the lens of eliminating distortion according to the present invention can see.This figure is almost the same with the original.
IV. lens manufacturing
Can realize with any suitable material according to ophthalmic lens assembly of the present invention.Can use polymeric material.Polymeric material can be the type of any appropriate.Polymeric material can comprise such as the thermoplastic of polycarbonate or such as the thermosetting material of diallyl diglycol carbonate salt type, for example CR-39 (PPG Industries).
The polymeric material commodity can be by forming by cross-coupled polymkeric substance, and for example described in United States Patent (USP) 4912155 or U.S. Patent Application Serial Number 07/781392, above-mentioned document is included as a reference.
Polymeric material may comprise a dyestuff, comprises for example photochromic dyestuff, and it can be added in the monomer prescription that is used for making polymeric material.
Optical lens module according to the present invention may further include the additional plated film of front and rear surfaces of standard, comprises electrochromic and/or the liquid crystal rete.The lens front surface can comprise an antireflection (AR) film, the type described in the United States Patent (USP) 5704692 for example, and the document is included as a reference.In order to make sunglasses or a desirable aesthetic to be provided, a partial reflection film can be used for lens.Front lens surface can be used as replacement or the additional film that resistance to wears that comprises, the type described in the United States Patent (USP) 4954591 for example, and the document is included as a reference.
Front and rear surfaces also can further comprise one or more traditional treatment method, and this method is used for such as mortifier, comprises thermochromism and photochromic dyestuff, polarization agent for example mentioned above, UV stabilizer and can regulate refractive index materials.
Figure 18 has represented a mould that is suitable for making lens of the present invention.This mould comprises mould part 302 and a closed edge 304 after 300, one of the front mold parts.Lens subassembly can be by being formed at the chamber 306 between the mould two halves to 308 mouthfuls of injection liquid lens materials.Air overflows from 310 mouthfuls.When the lens subassembly hardening, the mould two halves are separated.Can find can have when lens subassembly leaves mould a radial edges 312, this can be removed in later stage technology.
The technology and the equipment that are used for casting lens subassembly of the present invention have description in the U.S. Patent Application Serial Number 09/658496 that belongs to people such as Kingsbury, this patented claim is filed on September 8th, 2000, be entitled as PROCESS FOR MOLDING THERMOPLASTICLENSES AND STEEPLY CURVED AND/OR THIN LENSESPRODUCED THEREBY ", the document is included as a reference.
V. the calculating gained characteristic of lens design example.
Example 1
Table 1 has been represented the comparison according to the calculated performance of polycarbonate lens of the present invention and the low curved lens of tradition
Homocentric form Tradition
Refractive index ????1.586 ??1.586
Diopter ????-3.00 ??-3.00diopters
Thickness ????2.0 ??2.0mm
Front surface flexibility (1.53) processing refractive index ????16.00 ??4.00diopters
Front surface radius ????33.1 ??132.5mm
The anterior optical surface diopter ????17.7 (4.4diopters owing to 1.586 refractive index uprises)
Paraxial amplification ????0.97 ??0.96
The apparent visual angle ????130 For 105 degree of the edge contour among Figure 10 (a)
Optical value when eye rotation 30 is spent:
Distortion ????-1.10% ??-3.10%
Astigmatism ????0.02 ??0.17diopters
Average diopter error ????0.07 ??0.025diopters
Root mean square diopter error ????0.07 ??0.09
The color imbalance ????0.11 0.16 prism diopter
Example 2
Figure 19 represented diopter for-6D ,-3D and+the precipitous crooked sphere lens series of 3D [be respectively Figure 19 (a), (c) and (e)] and corresponding low crooked Sola Perma-Poly TMCalculating between the ordinary lens [be respectively Figure 19 (b), (d) and (f)] relatively.
Precipitous crooked spherical lens assemblies has 16D spherical anterior surface identical, shown in lens cross section 400 in essence.In general, precipitous crooked spherical lens assemblies provides outstanding marginal distortion.Lens among Figure 19 (a) and 19 (c) also show the root-mean-square error that reduces under negative the requirement.
Example 3
Figure 20 has represented that two have 16D front surface-3D through the calculating between the precipitous curved lens assembly of diopter and one-2D rear surface cyl correction relatively.
Lens among Figure 20 (a) have a traditional back annular double-curved surface (conventionaldonut torus back); Lens among Figure 20 (b) have the back wholecircle meridian (all circular meridia back) of the above-mentioned type.The latter shows the distortion that outstanding root mean square diopter sum of errors more or less improves.
Example 4
Last group example (Figure 21 and 22) be a progressive curved lens of tradition and one according to the calculating between the progressive lenses of the present invention relatively.
Figure 21 has compared that conventional bending Sola XL progressive lenses has similar stepped form with one and the long distance vision characteristic of the lens of precipitous bending (16D) baseline.
Figure 22 has compared the closely visual characteristic of the precipitous curved lens among Sola XL progressive lenses and Figure 21.
In general, progressive lenses according to the present invention is characterised in that, and is roughly homocentric with the rotation center of eyes at the reference sphere or the spherical shell of a precipitous bending of wearing position.These lens have one corresponding to going up visual area at a distance; A following visual area has greater than the diopter of last visual area with correspondence closely, and with a mesozone that is connected upper and lower region, its diopter comprises the corridor of a low relatively surface astigmatism between last visual area and following visual area.
In one embodiment, precipitous crooked reference sphere is corresponding to the front surface of last visual area core.In another embodiment, progressive surface is positioned at the front surface of lens and is in the precipitous crooked spherical shell of a thickness less than 2mm.In these two embodiment, the radius-of-curvature of shell or reference sphere can be less than 50mm, be in 30 and 35mm between better, the about 2mm of 33mm ± approximately preferably.Explanation for the suitable front surface design of progressive lenses can be filed on July 10th, 1997 referring to for example patented claim 08/782493, now U.S. Patent number 5861935.
VI. lens that assembled and frame.
The frame that uses among the present invention is adjusted to support lens among the present invention with approximate location shown in Figure 3.Frame can be boundless, the part band edge or full limit.
In a preferred embodiment, lens can not show when packing frame into or cornerite in essence.Frame can comprise that an adjustable mechanism comes corresponding with wearer's direct-view axle in order to the position that changes lens axis.
Figure 23 is one and comprises lens 402 and 404 and the skeleton view of the glasses 400 of frame of the present invention.Lens shape has been created a very attractive object attractive in appearance.Frame shown in Figure 23 has a marginal portion 406 and temple part 408 and 410.Edge around the frame of each lens is adjusted to corresponding closed curve that is located on or near the precipitous reference sphere of lens.Because the consistance of the flexibility in certain claimed range, framework or Frame Design go for any requirement in this scope.
Figure 24 be among Figure 23 glasses at the side view that adorns oneself with on the face.The figure shows another aspect of glasses visual effects, this is because the precipitous bending of lens and the 3D shape of rims of the lens complexity.This figure has represented that also less relatively lens can provide a wide visual angle and well glasses protection.
Figure 25 is a forward direction synoptic diagram according to glasses embodiment 412 of the present invention, and it has represented mechanical aspects more of the present invention.The frame of embodiment comprises the temple part 416 and 418 of a nose bridge 414 and hinge among Figure 25.These parts are formed the boundless frame of one three parts together.
Temple part 416 and 418 comprise hinge 420 and 422 and the assembling tab 424 and 426.In a preferred embodiment, tab 424 and 426 by surface-mounted on the sphere front surface of lens.No matter lens see through that diopter requires and cyl correction requirement, these assembly surfaces can have unified position and with respect to the angular relationship of framework, this point will be understood.With similar mode, the tab 428 of nose bridge 414 and 430 can be by surface-mounted on the front surface edge of lens respectively.
Nose bridge 414 is shown in the sectional view of Figure 25 (a).Advantageously, the nose bridge can be made into and length-adjustablely is common in the different interpupillary distances (P among Fig. 3 among the different wearers with compensation D).This adjustable feature allows the optical axis of lens can carry over the vision axis that adorns oneself with eyes.A physical construction that is fit to this adjustable feature of manufacturing is shown in Figure 25 (a), is appreciated that other removable or varistructured combination also can reach this purpose.Among the embodiment in Figure 25 (a), tab 428 and 430 all has member 432 and 434 respectively, and they are inserted into the opposite end of pipe 436.Screw group 438 and 440 is with member 432 and 434 location.This screw group can be released to allow the adjustment of nose bridge length, and this realizes by think different directions sliding component 432 and 434 in pipe.
Figure 26 is the planimetric map of a glasses embodiment 500 of the present invention.These glasses are boundless types.Left lens 502 and the lens that right lens 504 are precipitous bending, side cut.In a preferred embodiment, they all have a preceding optical surface 506, and this surface generally is the sphere that has less than the 50mm radius, and as noted earlier, radius is better less than 35mm.On the position of having worn, the center of the spherical surface radius-of-curvature of each lens roughly lays respectively at the rotation center of wearer's eyes, P L, P R
Lens 502 and 504 link together to support lens on the face the wearer by nose bridge 508.Left and right sides temple part 510 and 512 is provided and is connected to the temple edge of left and right sides lens.By contact Figure 26 (a), an optimal way of this connection will be discussed now.
Figure 26 (a) is the detail of Figure 26 embodiment, and it has represented that right lens 504 link together by a right annex 514 and hinge 516 with right temple part 512.In a preferred embodiment, right annex is arc and generally is that spherical camber line along lens 504 front surfaces extends.A nose shape part 518 of annex 514 be positioned at the lens front surface above.A threaded fixed system such as screw 520 and nut 522 can be used to annex is fixed on the lens.In a preferred embodiment, it is outstanding 526 that the emargintion 524 in lens can be used for receiving a location of annex, with further protection annex with stop its rotation about the main shaft 528 of screw 520.In a preferred embodiment, the main shaft 528 of fixed system is positioned on the axial line that intersects with lens spherical surface center.
A preferred method for cutting edge of lens subassembly of the present invention also is shown in detail in Figure 26 (a).As shown in the figure, lens edge surface 530 is roughly along the radial line 532 of lens spherical surface.On the position of having worn, this radial line center roughly is positioned at the rotation center P of eyes RThis edge configuration makes that rims of the lens is sightless for the wearer in itself, because when eyes rotated to the visual angle facing to rims of the lens, it is visible that edge surface is only the side to the wearer.In addition, the edge surface size is reduced, and profile observer to external world is reduced to minimum degree.The details of cutting edge is shown in Figure 27 and 28.
Figure 27 (a)-(d) has represented different roughly along the edge isoline of the radius R of lens spherical surface 534.As shown in the figure, the cross section of edge surface is approximately perpendicular to the tangent line T of spherical surface in edge, that is to say sight line roughly with the edge surface coplane.
In Figure 27 (a)-(d), the cross section of each edge surface be in about eyes rotation center P become one of the θ angle among a small circle in, so be visible hardly to the wearer.In the example of Figure 27 (a), the cross section of edge surface is that a straight line 536 and θ are near zero.In the example of Figure 27 (b), a little fillet is used to eliminate the sharp edges that might bring safety problem.In the example of Figure 27 (c), the edge is carved with a groove 538 to coincide mutually with the part 540 of glasses edge respective shapes.At last, in the example of Figure 27 (d), a globule 542 is formed on edge surface and matches with the band trench edges 544 with frame.In the situation of back, it is sightless to the wearer that edge surface remains to a great extent.
At Figure 27 (b), in the situation (c) and (d), advantageously θ in the whole edge extent of lens all less than about 5 °.This situation is shown in Figure 28, and this figure is a synoptic diagram of the lens 546 of cutting edge according to the preferred embodiment of the invention.The edge surface 548 of lens is the ring surfaces perpendicular to lens spherical surface 50 tangent lines.This ring surface is that three-dimensional meaning is that it is not to be in fully in the same plane.Edge surface is between two general tapers 552 and 554, and opening angle θ, and this angle can change at the diverse location of rims of the lens, but typically less than 3 ° ± 1.5 °.
Figure 29 (a)-(c) has represented multiple lens side cut technology.Figure 29 (a) has represented the side cut of use about traditional Ostwalt part lens 560 of the conventional mill 562 of axle 564 rotations, and axle keeps parallel to axis of reference 566 (can be the optical axis of lens mould).Grinding machine axle 564 moves to form edge surface around rims of the lens along arrow 568 indications.Use the side cut of the precipitous curved lens 570 of similar technique to start from Figure 29 (b).The result is lens 572 that have the side cut of sharp edges, and edge surface can open a wide-angle at wearer's visual angle, edge.
Shown in Figure 29 (c), corresponding to a preferred embodiment of the present invention, the edge surface 574 of precipitous curved lens 570 can produce by a grinding machine 562 around axle 576 rotations, and intersect at the camber line C center of the spherical surface of axle 576 and lens.In the past, such device only is used for non-precipitous curved lens is cut edge.
VII. plated film, sunglasses and protective spectacles
A. plated film
Have the lens subassembly on high flexibility surface as among the present invention those, they are carried out plated film can be difficulty especially with the control reflection/transmission.These difficulties to small part is because the geometric properties of typical deposition, evaporation and sputtering system.These systems can form rete relatively uniformly to the lens subassembly of relatively flat from the center to the edge.Yet,, just can find very big variation when surface curvature becomes precipitous.Viewed lens subassembly color can change along with thickness.It also can see through lens and change owing to the variation at visual angle.This effect is more remarkable under the situation of precipitous curved lens.These difficulties are known as " rolling about " sometimes.
Give the technology of the coating of lenses, especially the coating technique to high flexibility lens is disclosed above-mentioned international application No.PCT/AU99/01029, is entitled as " Coated Lens ExhibitingSubstantially Balanced Reflactance ".The various polytypes of being made up of the many oxide films of one " group " also have discussion therein.This film group is shown in Figure 30 (a).In this example, the lens 600 of a precipitous bending have a spherical anterior surface 602 that has multilayer film 604 (figure does not represent true yardstick).
The example of an anti-reflective film, it provides one at the edge from the center to the plated film totally light blue uniformly, and this precipitous curved lens assembly comprises five layers of silicon and the zirconia layer that one group of thickness is different.This film group is illustrated in down Table I.
Table I
Material Thickness (nm)
Air
????SiO 2 ????98.96
????ZrO 2 ????132.79
????SiO 2 ????36.96
????ZrO 2 ????16.61
????SiO 2 ????17.90
Lens
Except reducing " rolling about ", lens also reduce the significance degree of fingerprint, and change more insensitive to other system and nonsystematic manufacturing.
Sputter-deposition technology for aforementioned oxide film is disclosed in the U.S. Patent application sequence 09/605,401 that people such as Burton are filed on June 28th, 2000, and the full content that this paper has comprised it is with as a reference.
Figure 31 and 32 has represented the various aspects of plated film of the present invention.It is the reflectivity percentages figure of function with the nano wave length that Figure 31 is one.It has compared film group and the conventional film group that has green (dotted line) in the Table I.
3% or the variation that more deposits thickness can cause change color significant and that can discover usually.When observing at an angle of inclination, the green of " protuberance " 650 representatives on the reflectance spectrum (Figure 31) can shift to blueness one end of spectrum.When this part incident was given birth to, the reflectivity of the red end of spectrum can become very strong.This will finally cause pink or purple (rather than desired Huang/green).
As a comparison, the film group (blueness) in the Table I produces has the reflectance spectrum of visible light reflection that is positioned at blue region in a large number, and this is illustrated in the peak of the spectrum that is centered close to 480nm or swells 652.Blue plated film produces low-down reflectivity up to the region of ultra-red of spectrum, and is less than .5%, more can be desirably in 720nm less than .25%.
The effect of precipitous lens bending is shown in Figure 32.As can be seen, for the reflectivity of the red end of spectrum in the middle of each lens, green plated film is higher than blue plated film.Yet,, can clearly be seen that the reflectivity of the spectrum red area of green plated film has increased a lot, and blue plated film has kept stable low red reflex rate when the measurement of reflectivity is to carry out at the edge of lens.
The result that red reflex rate during the trend rims of the lens increases is that feasible " green " plated film has become bright purple (green+red=purple).This effect can not take place when blue plated film to a great extent.The direct result of the susceptibility of this reduction that color " is rolled about " is, the demand in order to keep colour consistency when the antireflection plated film to the crooked grouping of standard lens reduces greatly.Clearly, precipitous curved lens surface can keep their color, this maintenance or by whole surface, or the part (comparing with more traditional plated film such as green) by surface increase.
B. solar lens
Tradition generally provides solar lens or the sunglasses that selectivity stops visible light and ultraviolet light simultaneously.These lens have the application of eye protection and fashion design.The light wavelength that sees through lens can realize selecting by the light absorbing dyestuff in the plastic body.As an alternative or additional, the direct reflection plated film can be applied to lens.These technology can be used to precipitous curved lens of the present invention.In addition, they can be used with above-mentioned anti-reflective film.For example, above-mentioned anti-reflective film can be applied to the optical surface of lens eyes one side, and these lens have comprised the dyestuff that partly stops sunshine.As selection, above-mentioned anti-reflective film can be applied to the optical surface of lens eyes one side, and preceding optical surface is coated with specular reflection film, for example a bright-coloured blue reflectance coating.
C. laser protection eyewear
It is very favourable that lens subassembly above-mentioned precipitous bending, spherical surface is used for laser protection eyewear.In a preferred embodiment, the design of glasses makes the center of curve of each lens lay respectively at the rotation center of eyes.Further, the side cut of lens makes lens approximately extend to the temple edge from the nose edge of eye socket, and extends to coboundary from lower limb.As selection, lens can be assemblied in the frame that can extend to described eye socket edge.These dispose many advantages.The first, lens can effectively surround eyes and reduce or prevent the parasitic light leakage at edge.The second, all light on the lens of being incident on that can see through pupil all are in the scope that becomes 25 ° to 30 ° with spherical surface tangent plane normal in essence.Having more, the incident light of wide-angle can not enter pupil.Laser stops the laser that means on lens or can be designed to stop described about 30 ° of scopes of the perpendicular line that is positioned at the spherical surface tangent line in the lens.
People know that band resistance optical filter can be responsive for the incident angle that is stopped light.This wave filter generally uses vertical incidence light as the design centre.The validity of this wave filter along with incident angle from departing from of vertical direction generally be change and also normally descend.This geometrical property is shown in Figure 30 (a), and this figure is about two any light R 1And R 2, they have incident angle φ respectively 1And φ 2Angle φ 1And φ 2Be about light R 1And R 2Measure with the normal at the intersection point place of lens surface.(normal is respectively perpendicular to the section T of loca 1And T 2).In general, for above-mentioned wave filter, φ is big more, and the validity of wave filter is more little.
Precipitous curved lens of the present invention has generally provided a less relevant incident angle φ, and this will allow to have the wave filter that relative normal for example is no more than effective refusal angle of 30 °.This of precipitous curved lens shows in the comparison of two lens examples among Figure 30 (b) and 30 (c) on the one hand.Lens 610 among Figure 30 (b) are Ostwalt parts ,-4D lens.Lens 612 among Figure 30 (c) are one to have-and 4D is through dioptric precipitous curved lens, and its preceding spherical surface 614 is approximately 15.5D.Supposed all that about the analysis of incident ray the refractive index of lens is 1.5, and center thickness is approximately 2mm.The pupil P that has supposed a 1cm diameter in addition is positioned at 2cm place behind rear surface and the optical axis O-O intersection point.
Figure 30 (b) and 30 (c) are decorated with a lot of incident raies.Light be from plane P TSelect plane P in the light family of intersecting TTangent at optical axis O-O place and each lens.Light family is positioned at optical axis O-O up and down 0,5,10,15 and the 20mm distance.The light of selecting from each light family (i) has relatively the maximum angular φ at the normal of lens surface incidence point, and (ii) by after the lens refraction, can arrive the minimum point L of pupil.These selecteed light with they separately in plane P TOn optical axis distance (as 5mm, 10mm etc.) up and down distinguish.
Following table has been represented the φ angle that calculates of each incident ray of lens among Figure 30 (b) and 30 (c):
Table II
Light (mm is to the distance of optical axis) φ is that unit is corresponding to lens among Figure 30 (b) with the degree φ is that unit is corresponding to lens among Figure 30 (c) with the degree
????20 ?????53.3 ?????15.8
????15 ?????46.1 ?????18.9
????10 ?????37.9 ?????22.0
????5 ?????27.2 ?????20.2
????0 ?????16.8 ?????16.1
????-5 ?????3.0 ?????10.9
????-10 ?????-9.4 ?????6.4
????-15 ?????-22.6 ?????3.1
????-20 ?????-33.3 ????2.8
(angle φ is expressed as just negative angle.A positive-angle means a clockwise light rotation about diagram lens normal, and a negative angle means a counterclockwise light rotation about diagram lens normal)
In example, corresponding to the φ of Ostwalt part in a lot of places all greater than 30 °, and along with the distance of distance optical axis increases substantially ,+the 20mm place increases to 53.7 °.On the contrary, for the precipitous curved lens among Figure 30 (c), angle φ is lower than 30 ° always.
Selectivity to laser stops and can realize by one or more optics rejection filters.A method for optimizing of making selectivity obstruction laser is to adopt a film group that the laser of the possibility of causing injury is arranged with obstruction.Be exactly an example that can effectively stop the rejection filter of common wavelengths laser in two communications below, these two wavelength are 1310nm and 1550nm.Composition and thickness that optical filter is every layer are described in Table III.
Table III
Material Thickness (nm)
Air
????SiO 2 ????125.42
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????250.83
????TiO 2 ????161.11
????SiO 2 ????125.42
Polycarbonate
In the optical design term, this film group is described as following form:
“1.12(0.5L?H?0.5L)1.06(0.5L?H?0.5L)1.03(0.5L?H?0.5L)(LHL)^6
1.03(0.5L?H?0.5L)1.06(0.5L?H?0.5L)1.12(0.5L?H?0.5L)”
Wherein H and L represent the quarter-wave optical thickness on the target wavelength in high index of refraction and low-index material respectively.In the example in Table III, low-index material is a silicon dioxide, and high-index material is a titania.Can utilize multiple other film group in the traditional design to provide one to prevent by the rejection filter of laser hazard in order to protective spectacles.
Continue the example in the Table III, optical density (OD) (seeing through the negative logarithm of number percent) as the function representation of incident wavelength in Figure 33.As can be seen from the figure, the frequency band that is stopped is a broadband that is centered close to 1400nm.Most of visible wavelengths can be by (that is to say that optical density (OD) is approximately zero).
Figure 33 has supposed that incident angle φ is zero, incident angle be meant with at the incidence point place with the angle that normal N became (seeing Figure 30 (a)) of the tangent tangent line T of lens surface.The optical density (OD) that can expect the film group can change when φ starts from scratch variation.Expection deviation value for the incident light of S and P polarization and 1310nm and 1550nm wavelength is shown in Figure 34.
Consider more specifically situation, optical density (OD) is the function of from 0 to 60 ° of incident angle θ among Figure 34.Be appreciated that the incident angle when light increases, whole stopband returns and is moved to the left (to blue direction).Because this point, optical density (OD) only increases the 1310nm wavelength.The optical density (OD) of 1550 lines is along with the increase of φ descends.For the film group in the Table III, when angle is lower than 30 when spending, the light less than 0.7% can see through, and when angle is lower than 20 when spending, the light less than 0.2% can see through, and these conclusions are applicable to all polarization states.Although may require harsh more in the military affairs and film group design that has bigger optical density (OD) in special frequency channel of needs, this security for commercial application requirements believes it is enough.
Can find that from Figure 34 in about 33 ° scope, for two kinds of wavelength and polarization, the transmitance of film group all is lower than 1% in incident angle.In the described precipitous curved lens, can not enter into retina greater than the light of the incident angle at this angle here, the center of curve of described lens roughly is positioned at the rotation center of institute's protective spectacles.Yet in order to prevent to reveal the undesirable transmission that causes owing to strong reflection, refraction or light, phacoid also can be with the thermoplastic manufacturing that has absorbing dye.
Accordingly, can provide to have precipitous spherical crooked novel high optical quality lens subassembly, it has correcting through diopter and cyl of requirement, and is assemblied in the frame that thereupon uses.These designs are easy to be used for sunglasses and other protective spectacles such as laser protection eyewear efficiently.
The present invention is by being illustrated with the contact of a plurality of embodiment and example.Yet claimed invention part is that the equivalent description of being admitted by hereinafter claim and law is defined.

Claims (44)

1. be adapted to fit in the lens on the glasses, these lens have the spherical surface of at least one radius-of-curvature less than about 35mm, these lens are conditioned so that the center of lens curved surface roughly is positioned at the rotation center of eyes, wherein lens are enough big, so that the visual angle greater than 55 ° to be provided, this visual angle be forward direction from sight line to the temple direction, and, wherein these lens have an anti-reflective film, by its front surface the observer are presented unified color.
2. in the lens described in the claim 1, front surface is exactly described at least one spherical surface and has the radius-of-curvature of 33.25mm ± 1mm.
3. in the lens described in the claim 1, lens all have an anti-reflective film at the optical surface of front surface and eyes one side.
4. in the lens described in the claim 1, the requirement that lens have a non-zero sees through diopter.
5. in the lens described in the claim 4, eyes one side surface of lens can be used in the astigmatism of correcting the wearer.
6. in the lens described in the claim 1, anti-reflective film is a deielectric-coating group that is added at least one optical surface of lens, and it generally shows blueness.
7. in the lens described in the claim 1, rete is made up of the layer with high and low relatively refractive index, and described rete is that at least one optical surface at lens carries out vacuum sputtering and realizes.
8. in the lens described in the claim 7, surface coating is one group of silicon and zirconia layer, wherein at least one deck zirconia thickness greater than about 100nm.
9. in the lens described in the claim 7, the reflectivity of rete has a local maximum for visible light at the 480nm place.
10. the solar lens of a side cut has one first optical surface, this optical surface is arranged in a spherical shell, this spherical shell is to be defined by the homocentric sphere of two radius differences less than 2mm, little person in the radius is no more than 50mm, and 2 O on the wherein said marginal surface and Q open one greater than 80 ° angle to the center P of shell.
11. in the lens described in the claim 10, first optical surface has the radius-of-curvature of 33.25 ± 1mm.
12. in the lens described in the claim 10, first optical surface has the surface power from 15.5D to 16.5D.
13. in the lens described in the claim 12, first optical surface is a front lens surface, wherein the rear surface of lens is configured to and makes lens have optional the see through diopter of one+2D to-5.75D.
14. in the lens described in the claim 10, the rear surface of lens is configured to and makes lens have an optional astigmatism correction of arriving 2.5D at most.
15. in the lens described in the claim 10, angle OPQ is greater than 90 °.
16. in the lens described in the claim 10, lens are to have greater than the lens mould of 120 ° angle OPQ by one to make.
17. in the lens described in the claim 10, lens are assemblied in the glasses so that the eyes rotation center that the center of curvature of front surface roughly is positioned at the wearer when wearing.
18. in the lens described in the claim 10, lens see through its front surface the observer are presented unified substantially color.
19. in the lens described in the claim 10, front surface is coated with a deielectric-coating group, can reduce when the reflectivity of this film group is higher than about 380nm to lambda1-wavelength, and whole remaining visible range is kept lower value always.
20. a protective spectacles comprises:
Left and right lens all have a spherical surface, and each spherical surface has 31mm to the radius-of-curvature between the 35mm,
Lens are supported in the device of wearer's face, and this method makes the spherical surface center of left and right sides lens roughly lay respectively at the rotation center of right and left eyes; And
Partly stop the lens relevant apparatus that the radiant light that incides lens is transmitted to each eyes.
21. in the glasses described in the claim 20, the transmission arrester is the multilayer film on each lens, each of film layer has different refractive indexes and thickness, selects these refractive indexes and thickness to stop the incident radiation spectra part of choosing at least in part.
22. in the glasses described in the claim 21, glasses are sunglassess, ultraviolet light is partly stopped at least.
23. in the glasses described in the claim 20, the laser emission in certain spectral range of choosing is partly stopped at least.
24. in the glasses described in the claim 23, the infrared laser radiation is partly stopped at least.
25. in the glasses described in the claim 23, incidenting laser radiation frequency band of living in comprises a communication optical maser wavelength at least, this communication laser is stopped fully so that its power drops to the level to eye-safe.
26. in the glasses described in the claim 23, each lens and its device of support extend to the temple edge of eye socket from the nose edge of eye socket, and extend to coboundary from the lower limb of eye socket, so just can stop from all angles and incide laser emission on the pupil.
27. in the glasses described in the claim 23, each lens extends to the temple edge of eye socket from the nose edge of eye socket, and extends to coboundary from the lower limb of eye socket, so just can stop from all angles and incide laser emission on the pupil.
28. in the glasses described in the claim 20, supportive device comprises left and right sides temple part and a nose bridge, and wherein each lens all be enough big with provide respectively one from the forward direction of the sight line of every eyes to the temple direction greater than 55 ° visual angle.
29. in the glasses described in the claim 20, the transmission arrester be one its stop the wave filter that characteristic can be subjected to inciding the incident angle influence of the light on the lens;
Wherein, on the position of having worn, the light that incides wearer's eye pupil can not depart from the normal at lens front surface incidence point place more than 30 °; And
Wherein, wave filter can become the normal with lens front surface incidence point place the power of incident ray of at least 30 ° incident angle to reduce to a security level.
30. glasses comprise:
Having at least one radius-of-curvature is the left and right lens of the spherical surface between about 31mm and the 35mm; And
Be used for supporting in wearer's face the frame that comprises a left and right sides temple part and a nose bridge of lens, this makes the center of spherical surface of left and right sides lens roughly lay respectively at the rotation center of left and right sides eyes;
Wherein each lens is all cut edge, and makes the edge surface of lens be approximately perpendicular to the tangent line of spherical surface.
31. in the glasses described in the claim 30, frame is boundless.
32. in the glasses described in the claim 31, framework further comprises respectively by fitting piece and is connected left and right sides temple annex on the lens of the left and right sides, the main shaft of this fitting piece roughly points to the straight line by the spherical surface center of curvature.
33. in the glasses described in the claim 30, the spherical surface of each lens is front surfaces of each lens.
34. in the glasses described in the claim 30, the edge surface of each lens and the spherical surface of lens intersect at one and in fact are positioned at arbitrary single plane line in addition.
35. in the glasses described in the claim 30, edge surface is to produce by a grinding machine that centers on the axle rotation of intersecting with the spherical surface center of curvature.
36. in the glasses described in the claim 35, the edge surface that grinding machine carves a band ditch with frame on the edge be complementary.
37. in the glasses described in the claim 35, grinding machine stays next globule to be complementary with the frame that has raceway groove at edge surface.
38. in the glasses described in the claim 35, the sharp edges that all grinding machines stay is all removed with beveling.
39. in the glasses described in the claim 30, the edge of at least one lens is thick more a lot of than the lens center, and the cutting on rims of the lens surface wherein makes it open a camber line Θ who is not more than 5 ° about the center of curvature of spherical surface, and this camber line is positioned at the arbitrary plane that comprises lens axis.
40. a manufacturing is fit to be assemblied in the method for the lens subassembly in the glasses, the requirement that this lens subassembly has a non-zero sees through diopter, and described method comprises step:
Make one its in the suitable major part of front surface along the lens mould of principal meridian radius-of-curvature less than 35mm;
The rear surface that makes the lens mould is cut, so and front surface provide the requirement of non-zero through diopter together; And
The lens mould is cut edge so that the lens of the side cut with the maximum hollow degree of depth that is at least 8mm to be provided.
41. in the method described in the claim 40, rear surface and front surface are cut together so that the astigmatism correction of a non-zero to be provided to the wearer.
42. in the method described in the claim 41, when producing the rear surface, used circular meridian double-curved surface to correct so that astigmatism to be provided to the wearer.
43. in the method described in the claim 40, the front surface by lens subassembly provides an additional progressive surface diopter at least.
44. in the method described in the claim 40, the rear surface by lens subassembly provides an additional progressive surface diopter at least.
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US9417460B2 (en) 2007-05-08 2016-08-16 Gunnar Optiks, Llc Eyewear for reducing symptoms of computer vision syndrome
US8469512B2 (en) 2011-05-31 2013-06-25 Gunnar Optiks, Llc Computer eyewear with spectral filtering
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CN109863448A (en) * 2016-10-14 2019-06-07 卡尔蔡司光学国际有限公司 Reduce the eyeglass of distortion
CN109863448B (en) * 2016-10-14 2020-11-10 卡尔蔡司光学国际有限公司 Spectacle lens with reduced distortion
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WO2021042691A1 (en) * 2019-09-06 2021-03-11 广州豪赋医学科技有限公司 Eyeglass lens for myopia correction

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JP2009003464A (en) 2009-01-08
WO2002037169A9 (en) 2003-01-30
AU2007203670A1 (en) 2007-08-23
EP1330676A1 (en) 2003-07-30
BR0115063A (en) 2004-02-03
CN100498428C (en) 2009-06-10
CN1303452C (en) 2007-03-07
EP1330676A4 (en) 2006-10-25
CA2425157A1 (en) 2002-05-10
CN1912689A (en) 2007-02-14
JP2004513388A (en) 2004-04-30
WO2002037169A1 (en) 2002-05-10

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