JPH05181096A - Multifocal eye lens and its production - Google Patents

Abstract

PURPOSE:To enable the observation of brighter images at any of a far point, near point and intermediate point and to facilitate fitting to respective individual wearing persons. CONSTITUTION:This lens is provided with a far sight correcting area, near sight correcting area and intermediate sight correcting area concentrically with each other by having prescribed widths in the respective diametral directions. On the other hand, the lens is formed to such a face shape that the respective correcting areas exhibit frequency distribution curves continuously changing in the respective diametral directions and that the frequency distribution curves are continuous at the boundaries between the respective correcting areas. In addition, the frequency change rates in the diametral directions in the far sight correcting area and the near sight correcting area are set smaller than the frequency change rate in the diametral direction in the intermediate sight correcting area.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an eyeball such as a contact lens or an intraocular lens, which is attached to or implanted in the eye (hereinafter referred to as an ophthalmic lens), and has a plurality of diopters on a concentric circle. The present invention relates to an observation-type multifocal ophthalmic lens and a method for manufacturing the same.

[0002]

BACKGROUND ART Conventionally, a multifocal lens, which has been applied to eyes having poor eyesight adjusting ability such as presbyopia, and has many powers in one lens as an eye lens for supplementing the eyesight adjusting ability. Eye lenses have been proposed.

Such a multifocal ophthalmic lens can be roughly classified into two types, and the distance vision correction area and the near vision correction area set in the lens are separately used according to need and are separated. Of the type that observes the distance vision correction area and the near vision correction area at the same time, and according to the judgment of the wearer's (observer) 's brain, the one with the desired distance is selected and observed. However, in the field of ophthalmic lenses, it is difficult to reliably observe multiple correction areas, so the latter type (simultaneous observation type) of each correction area is observed at the same time. However, it is becoming mainstream.

Further, this simultaneous observation type ophthalmic lens also has a so-called two focus, that is, a distance vision correction region and a near vision correction region, as disclosed in Japanese Patent Laid-Open No. 60-91327. Bifocal type and JP-A-59
As disclosed in Japanese Unexamined Patent Publication (Kokai) -208524, there is a so-called multifocal type having a multifocal point whose dioptric power continuously changes from a distance vision correction area to a near vision correction area.

However, since the former bifocal type ophthalmic lens has only two focal points, the wearer is
When a point at an intermediate distance between the far point and the near point is visually recognized, a clear image cannot be obtained, and it becomes difficult for the brain to make a judgment, and a phenomenon such as ghost or double vision is likely to occur.

On the other hand, in the latter multifocal type ophthalmic lens, although a clear image can be obtained at the intermediate point, the power of the lens changes in the radial direction at a substantially constant rate of change, which is clear. Since the distance and near vision correction areas are not secured, the visibility at the far point and near point, which requires a particularly clear image, cannot be sufficiently obtained, and the image is blurred. There was a risk of causing inconvenience, and it was not suitable for practical use.

[0007] In order to secure a distance vision correction area or a near vision correction area, some combinations of a multifocal lens and a monofocal spherical lens have been proposed, but all of them have been proposed. , The focus shift due to the spherical aberration of the spherical lens part is ignored, and the smooth diopter change is not obtained at the boundary part between the spherical lens part and the multifocal lens part. Like a lens, it has a risk of causing a phenomenon such as ghost or double vision.

Moreover, in all of the conventional multifocal type ophthalmic lenses, the aspherical shape in which the lens power changes in the radial direction at a substantially constant rate of change is adopted, so that the eye of the wearer's individual It is not possible to satisfactorily adjust the intelligibility between the far point, the near point, and the midpoint, which are required depending on the degree of refractive power adjustment ability and living conditions, etc., and the optical effect is limited. There was also the problem of problems.

[0009]

The present invention has been made in view of the above circumstances, and the problem to be solved is to obtain a clearer image at any of a far point, a near point, and an intermediate point. You can observe the bokeh and ghost of the image,
A phenomenon such as double vision can be prevented as much as possible, and it is possible to perform optical adjustment of the lens according to each individual wearer, and a multifocal ophthalmic lens that is easy to fit to each individual, It is to provide the manufacturing method.

[0010]

In order to solve such a problem, the present invention provides a multifocal ophthalmic lens having a plurality of dioptric powers on a concentric circle, the distance vision correction region and the near vision correction region. And an intermediate visual acuity correction area between them are provided concentrically with each other with a predetermined width in the radial direction, while each of these correction areas shows a power distribution curve that continuously changes in the radial direction and each correction area. The lens surface shape is such that the power distribution curve is continuous at the boundary between them, and the radial diopter change rate in the distance vision correction region and the near vision correction region is defined as the radial diopter in the intermediate vision correction region. A multifocal eye lens that is smaller than the rate of change,
This is the summary.

According to the present invention, in such a multifocal ophthalmic lens, the rate of change in the radial direction in the distance vision correction region and the near vision correction region is set to 1 D (diopter) / mm or less. Is also the gist.

Furthermore, according to the present invention, when manufacturing the above-mentioned multifocal ophthalmic lens, the power distribution curves in the distance vision correction area, the near vision correction area and the intermediate vision correction area are determined. In addition, after determining the surface shape on one side of the lens, the surface shape on the other side of the lens is determined by the ray tracing method so that the frequency corresponding to the frequency distribution curve can be obtained. A method of manufacturing a multifocal ophthalmic lens is also the gist thereof.

[0013]

[Detailed Description of Configuration] First, as a specific form of the multifocal ophthalmic lens according to the present invention, a distance vision correction region is provided at the center of the lens, and a near vision correction region is provided at the outer periphery of the lens. Each of them is provided with an intermediate vision correction area between the distance vision correction area and the near vision correction area, and a near vision correction area is provided at the center of the lens and a distance vision area is provided at the outer periphery of the lens. There are two modes, that is, a visual acuity correction region is provided, and an intermediate visual acuity correction region is provided between the near vision correction region and the distance vision correction region.

In any of these forms, the distance vision correction area, the near vision correction area and the intermediate vision correction area are:
It is sufficient that they are formed concentrically with each other. That is, the center (optical axis) of the concentric circle may be decentered from the center of the lens, or each correction area may not be a perfect circle,
It may be oval or the like. In this sense, it should be understood that the radial direction in each visual acuity correction region does not necessarily match the lens radial direction.

When the distance vision correction area is set at the center of the lens and the near vision correction area is set at the outer circumference, the distance vision correction area is equal to or smaller than the pupil diameter under dim light. It is preferable to set as follows, and specifically, it is preferable to set the diameter to be 2 to 6 mm. Furthermore, more preferably, in addition to such conditions, the distance vision correction area is 10 to 3 of the total area of the optical portion of the lens.
The near vision correction area is set to occupy 0% and the near vision correction area occupies 20 to 50% of the entire area of the optical portion of the lens.

This enables observation by the distance vision correction area and the near vision correction area even when the pupil diameter changes.
This is to prevent image blurring at each point from the far point to the near point. However, under the dimly lit condition, it is acceptable to set the distance vision correction region to the same extent as the pupil diameter under the dimly lit condition because of the fact that there are generally many far point observations.

On the other hand, when the near vision correction area is set in the central portion of the lens and the distance vision correction area is set in the outer peripheral portion,
The near vision correction area is preferably set smaller than the pupil diameter under dim conditions, and specifically, the diameter is preferably set to 1 to 5 mm. Furthermore, more preferably, in addition to such conditions, the near vision correction area occupies 5 to 20% of the total area of the optical portion of the lens, and the distance vision correction area covers the area of the entire optical portion of the lens. Of 60-9
Each of them is set to occupy 0%. This is for the same reason as the above case.

The intermediate visual acuity correction area is defined as a transition portion between the distance visual acuity correction area and the near visual acuity correction area, and the distance visual acuity correction area and the near visual acuity correction area determined as described above. It will be formed over the entire area between the area.

Each of the distance vision correction area, the near vision correction area and the intermediate vision correction area is formed to have a shape showing a power distribution curve which continuously changes in the radial direction. In other words, the power distribution curve in each of the visual acuity correction areas is set to have a curve shape having one tangent line at any point. The power distribution curve represents the relationship between the distance from the optical axis of the lens and the power at that distance.

Moreover, the lens surface shape is determined so that the power distribution curves in the respective visual acuity correction areas are continuous even at the boundaries between these visual acuity correction areas. That is, the power distribution curve is set to have a curve shape having one tangent line even between the visual acuity correction areas.

Further, there, the radial power change rate in the distance vision correction area and the near vision correction area is set to be smaller than the radial power change rate in the intermediate vision correction area. More preferably, the radial power change rate in the distance vision correction area and the near vision correction area is 1D.
(Diopter) / mm or less is set. Thereby, it becomes possible to more advantageously obtain the sharpness of the image at the time of observing the far point and at the time of observing the near point.

In short, in the distance vision correction area and the near vision correction area, the dioptric power is not constant in the radial direction, but the rate of change is small, and the two vision correction areas are connected to each other. An intermediate visual acuity correction area having a relatively large radial power change rate is formed. As a result, the intermediate visual acuity correction area is formed in such a manner as to complement the distance visual acuity correction area and the near visual acuity correction area.

The preferred method for producing the multifocal ophthalmic lens according to the present invention having the above-mentioned shape will be further described below.

In manufacturing the multifocal ophthalmic lens according to the present invention, first, the power distribution (power distribution curve) of the target lens is determined.

To this end, first, the required distance vision correction power and the required maximum near vision correction power are respectively determined in accordance with the visual acuity adjustment ability of the wearer. Then, by adding the additional power to the required maximum distance vision correction power, the power distribution curve is set so that the maximum required near vision correction power at the center of the optical axis or the outer peripheral portion can be obtained. ..

Here, the frequency distribution curve can be set by a single or a plurality of first-order or second-order or higher polynomials. In particular, if the frequency distribution curve is set by using two or three quadratic polynomials, the setting (calculation) becomes easy, and even if a more complicated polynomial is used, there is a large difference. It is preferable because a lens having no optical characteristics can be obtained.

More specifically, for example, as shown in FIG. 1, in a multifocal ophthalmic lens having a distance vision correction area in the lens center portion, a distance vision correction area,
When the intermediate visual acuity correction area and the near visual acuity correction area are each set by a quadratic polynomial, first, the following values are determined according to the visual acuity adjustment ability of the wearer.

X ₁ : Radius of distance vision correction area X ₂ : Radius of intermediate vision correction area X ₃ : Radius of near vision correction area Y ₀ : Target minimum refractive power (the required maximum distance vision correction) Diopter) Y ₁ : Additional power at the boundary between the distance vision correction area and the intermediate vision correction area Y ₂ : Additional power at the boundary between the intermediate vision correction area and the near vision correction area Y ₃ : Maximum required near vision Additional power to obtain the correction power

First, when the power distribution curve in the distance vision correction region is set to Y = A ₁ .X ² , A ₁ = Y ₁ / X ₁ ² (1) ), The power distribution curve in the distance vision correction area is determined.

Next, assuming that the power distribution curve in the intermediate visual acuity correction region is Y = A ₂ · X ² + B ₂ · X + C ₂ , A ₂ · X ₁ ² + B ₂ · X ₁ + C ₂ = Y ₁ · .. (1) A ₂ .X ₂ ² + B ₂ .X ₂ + C ₂ = Y ₂ ... (2) 3A ₁ .X ₁ ² = 2A ₂ .X ₁ + B ₂ ... (3) From these (1), (2) and (3), the power distribution curve in the intermediate visual acuity correction region is determined.

Further, assuming that the power distribution curve in the near vision correction range is Y = A ₃ · X ² + B ₃ · X + C ₃ , 2A ₂ · X ₂ + B ₂ = 2A ₃ · X ₂ + B ₃ ··· is _{· (1) A 3 · X} 2 2 + B 3 · X 2 + C 3 = Y 2 ··· (2) A 3 · X 3 2 + B 3 · X 3 + C 3 = Y 3 ··· (3) Therefore, the frequency distribution curve in the near vision correction region is determined from these (1), (2), and (3).

Next, as described above, after the power distribution curve of the objective lens is determined, the shape of the lens surface is determined.

To this end, first, the surface on either side of the lens is set to a desired shape. In the case of a contact lens, in particular, in order to ensure the ease and goodness of wearing, it is preferable that the inner surface (concave surface) is shaped to match the shape of the eye (cornea) of the wearer. Therefore, first of all, the inner surface is a suitable spherical surface or aspherical surface (for example,
It is set as an elliptic surface or a combined surface of an elliptic surface and a spherical surface.

Then, the surface shape on the other side of the lens is determined by using the ray tracing method so that the frequency corresponding to the frequency distribution curve determined as described above can be obtained.

More specifically, for example, as shown in FIG. 2, in the contact lens material 10 in which the concave surface is set to a predetermined shape, an arbitrary point on the convex surface: A
Assuming that the target refractive power at (X ₁ , Y ₁ ) is P ₁ , the curve passing through the point A has an aspherical surface parameter: s
It is expressed by the following equation using (s <-1).

[0036]

[Equation 1]

Therefore, when the angle formed by the normal line at the point A and the X axis (optical axis) is θ ₁ , this θ ₁ is expressed by the following equation.

[0038]

[Equation 2]

Further, the angle formed by the emitted light at the point A with the normal is θ
_{When set to 4} , the following formula is established from Snell's law. n ′ · sin θ ₄ = n · sin θ ₁ where n: refractive index of air n ′: refractive index of lens material

Further, if the angle formed by the emitted light at the point A and the X axis is θ ₅ , this θ ₅ is expressed by the following equation. θ ₅ = θ ₁ − θ ₄

On the other hand, if the straight line representing the emitted light at point A is y = c ₁ · x + d ₁ , then c ₁ and d ₁ are respectively given by the following equations.
expressed. c ₁ = tan θ ₅ d ₁ = Y ₁ −c ₁ · X ₁

If the point at which the emitted light intersects the concave surface is B (X ₁₁ , Y ₁₁ ), the curve representing the concave surface is (X−K ₁₁ ) ² + Y ² = BC ² (BC: concave surface However, since K ₁₁ = BC + TH (TH: thickness at the center of the lens optical axis) is expressed, the coordinates (X ₁₁ , Y ₁₁ ) of the point B can be expressed by the following equations, respectively. To be done.

[0043]

[Equation 3]

Therefore, when the angle formed by the normal line at the point B and the X axis is θ ₁₁ , this θ ₁₁ is expressed by the following equation. tan θ ₁₁ = Y ₁₁ / (X ₁₁ −K ₁₁ )

Further, the incident light at the point B is the emitted light at the point A, and the angle formed by the incident light at the point B with the X axis: θ ₁₂ is the angle formed by the emitted light at the point A with the X axis. : Θ ₅ is equal to θ ₅ , and the angle formed by the incident light at the point B with the normal line: θ ₁₃ is represented by the following equation. θ ₁₃ = θ ₁₁ −θ ₁₂

Further, the angle formed by the emitted light at the point B with the normal is θ
_{When set to 14} , the following formula is established from Snell's law. n ・ sinθ ₁₄ = n ′ ・ sinθ ₁₃

Further, when the angle formed by the emitted light at the point B and the X axis is θ ₁₅ , this θ ₁₅ is expressed by the following equation. θ ₁₅ = θ ₁₁ − θ ₁₄

On the other hand, assuming that the straight line representing the emitted light at the point B is y = c ₁₁ · x + d ₁₁ , then c ₁₁ and d ₁₁ are respectively given by the following equations.
expressed. c ₁₁ = tan θ ₁₅ d ₁₁ = Y ₁₁ − c ₁₁ · X ₁₁

Therefore, the X of the point where this emitted light intersects the X axis
The coordinate: XP ₀ can be expressed as the following equation. XP ₀ = -d ₁₁ / c ₁₁

Therefore, calculation is performed by changing the aspherical surface parameter: s until this XP ₀ becomes equal to 1000 / P ₁ . Then, from the coordinates of the point A at the time of convergence, the radius of curvature R of the convex surface of the lens at that point can be obtained based on the following equation.

[0051]

[Equation 4]

Then, the surface shape of the lens is determined by such a ray tracing method, and based on the result, the lens material is cut by using a numerical control cutting device or the like to obtain the object as described above. A multifocal ophthalmic lens will be manufactured.

[0053]

As described above, in the multifocal ophthalmic lens according to the present invention, as described above, the dioptric power distribution curve is continuous in the radial direction centered on the optical axis of the lens, whereby the dioptric power changes. It is possible to prevent blurring of an observed image, ghost, double vision, and the like due to optical discontinuity at points as much as possible.

Further, since the distance vision correction area and the near vision correction area having a large power difference are continuously and smoothly connected by the intermediate vision correction area, it is clear even at the intermediate point. The image can be viewed, which facilitates mid-point viewing.

Moreover, since the power change rate of the distance vision correction area and the near vision correction area is set smaller than that of the intermediate vision correction area, even under various conditions, at the time of far point observation and near point observation. It is possible to obtain a clear image advantageously, and therefore, it is possible to obtain a particularly large effect that the far point observation and the near point observation that are particularly required become easy without sacrificing the clarity of the image at the intermediate point. To get.

Further, since the intermediate visual acuity correction area is formed with a continuous power distribution curve in the distance visual acuity correction area and the near visual acuity correction area, by adjusting the power distribution form in the intermediate visual acuity correction area. The image obtained during distant point observation or near point observation can be complemented by the intermediate visual acuity correction area for easier visual recognition, and the intermediate visual acuity correction area can be adjusted according to the wearer. The optical characteristics as an excellent multifocal ophthalmic lens can be exhibited.

Further, according to the present invention, if the surface shape of the lens is determined by the ray tracing method, the multifocal ophthalmic lens having various arbitrary power distribution curves can be easily designed and manufactured. Of.

[0058]

EXAMPLES A specific description will be given below of one example of manufacturing a contact lens according to the present invention. The present invention should not be construed as being limited by the specific description in the above detailed description or the description of the following examples, and various changes and modifications based on the knowledge of those skilled in the art. , Improvements, etc.,
Furthermore, it goes without saying that any of the embodiments to which such changes are added are also included in the scope of the present invention without departing from the spirit of the present invention.

In this embodiment, a contact lens having a distance vision correction area in the central portion, a near vision correction area in the outer peripheral portion, and an intermediate vision correction area between them is manufactured. ..

First, when manufacturing such a contact lens, the target maximum distance vision correction power is -6.00.
In D, the maximum value of the addition power was determined to be +1.6 D, and it was decided to adopt an aspherical surface (curvature of vertex: 8.00 mm) with an eccentricity of 0.4 for the lens concave surface.

Further, the radius of the distance vision correction area: X ₁ , the radius of the intermediate vision correction area: X ₂ , the radius of the near vision correction area:
X ₃ , addition power at the boundary between the distance vision correction region and the intermediate vision correction region: Y ₁ , addition power at the boundary between the intermediate vision correction region and the near vision correction region: Y ₂ , maximum addition power: Y ₃
Was determined as follows. (X ₁ , Y ₁ ) = (1.5 mm, +0.4 D) (X ₂ , Y ₂ ) = (3.0 mm, +1.4 D) (X ₃ , Y ₃ ) = (4.0 mm, +1.6 D) )

Then, the radial power distribution curves in the distance vision correction area, the intermediate vision correction area and the near vision correction area are set by quadratic polynomials, respectively, according to the above-mentioned method. The frequency distribution curve in the correction area was obtained. The calculated frequency distribution curve,
It will be shown in FIG.

Then, based on the obtained power distribution curve, the surface shape of the contact lens on the convex surface side was obtained by the ray tracing method as described above. The results are shown in Table 1 below.

[0064]

[Table 1]

In Table 1, in the central portion (X = 0 to 0.80 mm) of the distance vision correction region, the change of the radius of curvature R within the range shown in the table is not recognized. ,
As described above, since the power distribution curve of the distance vision correction region is set by a quadratic polynomial, and the radius of curvature is determined based on it, even in this portion,
It should be recognized that there is a continuous frequency change.
Further, in this embodiment, the radius of curvature on the convex surface side is constant in the central portion as described above, because the amount of change in the radius of curvature is within the range of the error due to the calculated effective number, or It is considered that this is due to the fact that the diopter of the lens as a whole changes due to the change of the radius of curvature in the radial direction on the concave side set to the spherical shape.

Then, based on the values thus obtained, the lens material was cut using a numerical control cutting device to obtain the target multifocal type contact lens.

The obtained contact lens (Example)
Table 2 below shows the clinical results of the above together with the clinical results of the simultaneous observation type bifocal type contact lens (comparative example).

[0068]

[Table 2]

From these clinical results, the multifocal type contact lens having the structure according to the present invention can give a very clear image to the wearer in both of the far point observation and the near point observation. It is clear that it has an excellent optical effect.

[Brief description of drawings]

FIG. 1 is a graph showing a specific example of a power distribution curve used in an ophthalmic lens according to the present invention.

FIG. 2 is an explanatory diagram for explaining an operation for obtaining a lens surface shape having a power corresponding to a target power distribution curve by using a ray tracing method.

FIG. 3 is a graph showing a frequency distribution curve obtained in an example.

[Explanation of symbols]

 10 Contact lens material

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tadashi Sawano 3-4-15 Sakae, Naka-ku, Nagoya Kagamiei Building Co., Ltd. Menicon Clinical Center (72) Inventor Shingo Hibino 3 Shinsama, Seki City, Gifu Prefecture Co., Ltd. Menicon Seki Factory (72) Inventor Hiroshi Iwai 3-12-7 Biwajima, Nishi-ku, Nagoya City Stock of Menicon Biwajima Research Institute

Claims (3)

[Claims] 1. A multifocal ophthalmic lens having a plurality of dioptric powers on a concentric circle, wherein a distance vision correction area, a near vision correction area, and an intermediate vision correction area therebetween are predetermined in a radial direction. While providing the widths concentrically with each other, each of the correction areas is formed as a lens surface shape in which a frequency distribution curve that continuously changes in the radial direction is shown and the power distribution curve is continuous at the boundary between the correction areas. A multifocal ophthalmic lens, characterized in that a radial diopter change rate in the distance vision correction region and the near vision correction region is set to be smaller than a radial diopter change rate in the intermediate vision correction region. .. 2. The multifocal eye according to claim 1, wherein the rate of change in the radial direction in the distance vision correction region and the near vision correction region is 1 D (diopter) / mm or less. lens. 3. The power distribution curves in the distance vision correction area, the near vision correction area and the intermediate vision correction area are determined, and after the surface shape on one side of the lens is determined,
The method for manufacturing a multifocal ophthalmic lens according to claim 1, wherein the surface shape on the other side of the lens is determined by a ray tracing method so that a power corresponding to the power distribution curve can be obtained.