JP3683093B2 - Multifocal contact lens - Google Patents

Description

[0001]
【Technical field】
The present invention is a lens (hereinafter referred to as an ophthalmic lens) that is attached to or embedded in the surface or inside of an eyeball, such as a contact lens or an intraocular lens, and has a plurality of vision correction regions set at different frequencies. The present invention relates to a multifocal ophthalmic lens having:
[0002]
[Background]
Conventionally, multiple vision corrections that are applied to eyes with inferior visual acuity, such as presbyopic eyes, and are used for supplementing the visual acuity, etc. A multifocal ophthalmic lens in which a region exists is proposed. For example, as described in JP-A-63-95415, JP-A-1-319729, etc., an eye-axis-moving contact lens that uses different vision correction regions with different frequencies depending on the movement of the eye-axis, As described in Japanese Laid-Open Patent Publication No. 59-208524, Japanese Patent Laid-Open No. 2-217818, etc., a simultaneous vision type contact for simultaneously observing vision correction regions having different powers and selecting necessary images based on the judgment of the brain That is the lens.
[0003]
In addition, both the visual axis moving type lens and the simultaneous vision type lens have two different power regions, a near vision correction region for near vision observation and a far vision correction region for far vision observation. A focal lens and a multi-focal lens in which an intermediate vision correction area is formed between a near vision correction area and a distance vision correction area to provide three or more different power areas have been proposed.
[0004]
However, with a bifocal lens, there are only two focal points, so it is difficult to obtain a clear image at an intermediate distance, and image jumping is likely to occur. There was also. On the other hand, with multifocal lenses, a clear image can be obtained even at intermediate distances, but with conventional lenses, the power of the lens changes stepwise with a narrow width in the radial direction. There is a problem that it is difficult to secure a sufficient area in the area and the distance vision correction area, and it is difficult to obtain a clear image, and there is no continuous frequency change on the boundary line where the frequency changes stepwise, and the shape inflection point Since there are also steps and steps, problems such as deterioration of wearing feeling, appearance of a ghost image, and perspective image mutual interference may occur.
[0005]
Therefore, the applicant previously changed the near vision correction area, the intermediate vision area, and the far vision correction area, which are concentrically arranged in JP-A-5-181096, continuously changing in the radial direction. A multifocal ophthalmic lens formed to show a frequency distribution curve is proposed. In the multifocal ophthalmic lens according to this earlier application, the frequency distribution is made continuous at the boundary line between the near vision correction area and the intermediate area and the boundary line between the distance vision correction area and the intermediate area. Since the generation of a boundary having a bent line is prevented, an excellent wearing feeling can be obtained, and inconveniences in observation such as a ghost image can be advantageously avoided.
[0006]
However, as a result of further studies by the present inventors, even with such a multifocal ophthalmic lens according to the earlier application, the user's request is still sufficient depending on the user's special application and environment. It became clear that it might be difficult to satisfy. For example, in the case where particularly clear visibility is required at both a far point and a near point, such as a painter or a survey worker, even if the multifocal ophthalmic lens according to the previous application is used, It has become clear that it is still difficult to obtain sufficient image clarity.
[0007]
[Solution]
Here, the present invention has been made against the background of the circumstances as described above, and the problem to be solved is that it is possible to obtain very clear visibility at both far points and near points. An object of the present invention is to provide a multifocal ophthalmic lens excellent in wearability.
[0008]
Another object of the present invention is to provide a multifocal ophthalmic lens in which the lens power and the design freedom of the lens area can be advantageously secured in the near vision correction range and the distance vision correction range, respectively. .
[0009]
[Solution]
In order to solve such a problem, the present invention is characterized by a multifocal type having a plurality of vision correction areas in which different lens powers are set. contact In the lens, the vision correction area is Used for either near view or far view A central vision correction area and a lens power different from that of the central vision correction area were set and spaced apart on the outer peripheral side of the central vision correction area , Used for either one of the near observation and the far observation An outer peripheral vision correction area and an intermediate area set between the central vision correction area and the outer peripheral vision correction area by setting an intermediate lens power between the central vision correction area and the outer vision correction area. And forming the central vision correction area and the peripheral vision correction area optically concentrically, Further, the outer diameter dimension of the central vision correction area is 0 to 8 mm, the radial width dimension of the intermediate area is 0.1 to 3.5 mm, In addition, the lens powers in the central vision correction area and the peripheral vision correction area are set equal to each other over the entire radial direction. Surely On the other hand, the rate of change gradually increases as the distance from the central vision correction area increases toward the lens power side of the peripheral vision correction area from the lens power of the central vision correction area in contact with the central vision correction area. An inner transition region that changes in frequency to a quadratic curve that increases, and the outer peripheral vision correction region in contact with the outer peripheral vision correction region toward the lens power side of the central vision correction region from the lens power of the outer peripheral vision correction region By changing the lens power at the boundary between the inner transition area and the outer transition area, the power changes on the boundary. Set the inflection point of In addition, the boundary between the inner transition region and the outer transition region in the intermediate region includes the radial center position of the intermediate region, and is more biased toward the vision correction region used for the near-field observation. Configured to It is to have done.
[0010]
In such a multifocal ophthalmic lens structured according to the present invention, since a constant frequency distribution region is provided in each of the central vision correction region and the peripheral vision correction region, the central vision correction region and the outer periphery are provided. In the vision correction area, visibility at specific distance points that are particularly required can be advantageously ensured, and at distance points corresponding to the respective lens powers set in the central vision correction area and the peripheral vision correction area. A clear image can be observed. In addition, the lens power in the intermediate area is set so that the rate of change is small near the central vision correction area and the peripheral vision correction area, and the rate of change increases as the distance increases. In any case, the clarity of the image observed in the vision correction area can be ensured very advantageously without being adversely affected by the intermediate area.
[0011]
Moreover, in the multifocal ophthalmic lens according to the present invention, the intermediate area is composed of an inner transition area and an outer transition area each of which changes in frequency in a quadratic curve, and is connected to the central vision correction area and the outer peripheral vision correction area. Therefore, compared with the case where the frequency change in the intermediate area is set to a curve shape of the inverse function of the cubic function, etc., it is related to the set power and the setting area in the central vision correction area and the peripheral vision correction area. Therefore, it is possible to easily connect the intermediate area to the central vision correction area and the peripheral vision correction area with a smooth power change, thus avoiding the occurrence of steps and large bending points, etc. Improvements in design flexibility such as lens power and lens area in the central vision correction area and the peripheral vision correction area can be achieved.
[0012]
Furthermore, in the multifocal ophthalmic lens according to the present invention, the lens power set in the central vision correction area is Pa, the lens power set in the outer peripheral vision correction area is Pc, and in the intermediate area The lens power at the boundary between the inner transition area and the outer transition area is Pb, the distance from the optical center axis of the vision correction area to the boundary between the central vision correction area and the intermediate area is Wa, and from the optical center axis of the vision correction area If the distance to the boundary between the inner transition area and the outer transition area in the intermediate area is Wb, and the distance from the optical central axis of the vision correction area to the boundary between the outer peripheral vision correction area and the intermediate area is Wc, The lens power in the inner transition area: y is expressed by the following (Equation 1), where x is the distance from the optical center axis of the vision correction area, and the lens power in the outer transition area in the intermediate area: y , The distance from the optical center axis of the vision correction area as x, structure represented by the following equation (2) is preferably employed.
y = Pa− (Pa−Pb) × (Wa−x) ² / (Wa-Wb) ² ... (Formula 1)
y = Pc− (Pc−Pb) × (Wc−x) ² / (Wc-Wb) ² ... (Formula 2)
[0013]
If such a configuration is adopted, an intermediate region that smoothly connects the central vision correction region and the outer peripheral vision correction region can be advantageously set, and in particular, the central vision correction region, the intermediate region (inner transition region), and the outer periphery The lens surface shape is determined so that the lens power distribution curve is continuous at each contact point in the vision correction area and the intermediate area (outer transition area). In other words, the lens power distribution curve is connected to any of them. point In this case, it is set with a curved shape having one common tangent, so that an excellent wearing feeling is realized and the occurrence of a ghost image or the like is advantageously prevented.
[0014]
Also before Record When adopting the configuration according to (Expression 1) and (Expression 2), in addition, the distance from the optical center axis of the vision correction area to the boundary between the inner transition area and the outer transition area in the intermediate area: Wb Is preferably employed in accordance with the following equation.
Wb = ((Pa−Pb) Wc− (Pc−Pb) Wa) / (Pa−Pc)
If the boundary position between the inner transition region and the outer transition region is set in this manner, the lens surface shape is determined so that the lens power distribution curve is continuous even at the boundary position. Further improvement in visual clarity and the like can be achieved.
[0015]
Further, in particular, in the present invention, for example, a central optical unit for near-viewing is formed including the central vision correction region, and an outer peripheral optical unit for far-viewing is configured including the outer visual correction region. In addition, a configuration in which the values giving the respective lens powers in the central vision correction area, the outer vision correction area, and the intermediate area are set as shown in the following (Expression 3) to (Expression 9) is preferably employed. The
Pa = P + ADD (Formula 3)
P + (1/6) ADD ≦ Pb ≦ P + (2/3) ADD (Formula 4)
Pc = P (Formula 5)
Wa = (1/2) SD (Formula 6)
(1/2) SD + (1/8) IM ≦ Wb ≦ (1/2) SD + (1/2) IM (Expression 7)
Wc = (1/2) SD + IM (Formula 8)
0.1 mm ≦ IM ≦ 3.5 mm (Formula 9)
0 ≦ SD ≦ 8.0 mm (Formula 10)
However, in the above formula, ADD is the added power, IM is the radial width dimension of the intermediate region, SD is the outer diameter dimension (seg diamond) of the central optical part, and OZ is the outer diameter dimension of the outer peripheral optical part. is there.
[0016]
Alternatively, in the present invention, for example, a central optical unit for distant observation including the central vision correction region and a peripheral optical unit for near observation including the outer visual correction region are configured, In addition, a configuration in which the values giving the respective lens powers in the central vision correction area, the outer vision correction area, and the intermediate area are set as shown in the following (formula 11) to (formula 18) is preferably employed. .
Pa = P (Formula 11)
P + (1/6) ADD ≦ Pb ≦ P + (2/3) ADD (Formula 12)
Pc = P + ADD (Formula 13)
Wa = (1/2) SD (Formula 14)
(1/2) SD + (1/2) IM ≦ Wb ≦ (1/2) SD + (7/8) IM (Expression 15)
Wc = (1/2) SD + IM (Expression 16)
0.1 mm ≦ IM ≦ 3.5 mm (Expression 17)
0 ≦ SD ≦ 8.0 mm (Expression 18)
[0017]
That is, by setting the lens shape according to the above (Equation 3) to (Equation 10), the central optical unit provides a lens power for visual acuity correction suitable for near-point observation, and the outer-side optical unit observes a far point. A multifocal ophthalmic lens that provides a suitable lens power for correcting eyesight can be advantageously realized, while the lens shape is set according to the above (Expression 11) to (Expression 18), so that a far point is formed by the central optical unit. Thus, a multifocal ophthalmic lens can be advantageously realized that provides a lens power for correcting eyesight suitable for the observation of the eye and a lens power for correcting eyesight suitable for the observation of the near point by the peripheral optical unit. In particular, the boundary between the inner transition region and the outer transition region in the intermediate region (the inflection point of the frequency change) is set to be biased toward the near observation optical unit side than the radial intermediate position of the intermediate region. As a result, under general usage conditions, both visual clarity during near-point observation and visual clarity during far-point observation can be advantageously ensured.
[0018]
Further, in the multifocal ophthalmic lens structured according to the present invention, the central optical unit for near-viewing is formed including the central vision correction area, and the far-sight observation lens including the outer vision correction area is included. When configuring the outer periphery optical unit, the optical center points of the central vision correction area and the outer vision correction area are biased downward with respect to the lens outer shape center point, and the deviation amount is set to 7.0 mm or less. It is desirable. Alternatively, in the multifocal ophthalmic lens having a structure according to the present invention, the central optical unit for distant observation is configured including the central vision correction region, and the near vision observation is included including the outer vision correction region. When configuring the outer periphery optical unit, the optical center points of the central vision correction area and the outer vision correction area are biased upward with respect to the lens outer shape center point, and the deviation amount is set to 7.0 mm or less. It is desirable.
[0019]
In this way, the optical center point of the vision correction area is deviated in a specific direction with respect to the center point of the outer shape of the lens, so that the near-viewing optical unit and the far-viewing optical unit are optically coaxial with each other. However, in the distance vision and the near vision where the line of sight is directed downward, the fact that the stable position of the lens is different is used, in other words, the relative positional relationship between the pupil and each observation optical unit is different. Thus, a visual axis moving type multifocal ophthalmic lens that selectively uses the near observation optical unit and the far observation optical unit can be advantageously realized.
[0020]
In the multifocal ophthalmic lens according to the present invention, spherical surfaces are preferably employed as the surface shapes for determining the power in the central vision correction area and the peripheral vision correction area. If a spherical surface is adopted as the basic surface shape in this way, the lens surface shape can be easily designed and excellent optical characteristics can be easily imparted.
[0021]
Furthermore, in the multifocal ophthalmic lens according to the present invention, a toric surface may be employed as one of the lens surfaces in the vision correction region. The toric surface may be adopted on either side of the ophthalmic lens.For example, in the case of a contact lens in which one surface is formed with a spherical concave surface corresponding to the eyeball surface shape, It is also possible to set a toric surface together on the spherical convex surface side that is designed to give a central vision correction region, a peripheral vision correction region, and an intermediate region of the target lens power. And when a toric surface is adopted, the lens power in the central vision correction area and the outer peripheral vision correction area differs depending on the cylinder axis in the circumferential direction around the optical central axis, but in each radial direction A constant lens power can be ensured throughout.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, in order to clarify the present invention more specifically, embodiments of the present invention will be described in detail with reference to the drawings.
[0023]
Specifically, the multifocal ophthalmic lens having a structure according to the present invention is formed as, for example, a contact lens 10 for presbyopia having a structure as shown in FIG. The contact lens 10 has a visual acuity correction region 12 in which a geometric central axis O with respect to the outer shape of the lens is an optical central axis P. The outer peripheral side of the vision correction area 12 does not give optical characteristics because it is not located on the pupil during wearing, but is formed as an outer peripheral area necessary for wearing, and slab-off processing or the like is performed as necessary. Is given. The visual acuity correction area 12 includes a central visual acuity correction area 14, an outer peripheral visual acuity correction area 16, and an intermediate area 18 in which different lens powers are set. The central vision correction area 14 has a circular shape centered on the optical central axis P, and the outer peripheral vision correction area 16 is a concentric annular shape that is spaced apart from the central vision correction area 14. have. Further, the intermediate area 18 has an annular shape that is concentrically positioned so as to fill between the central vision correction area 16 and the peripheral vision correction area 16.
[0024]
Further, the central vision correction area 14 and the outer peripheral vision correction area 16 are set to have different lens powers, so that one of these vision correction areas is generally used to adjust the user's vision for near-point observation. It is a near vision correction area that has a certain lens power enough to compensate for power over the entire radial direction, and the other vision correction area only supplements the user's vision adjustment power for far point observation This is a distance vision correction region having a certain lens power over the entire radial direction. Note that which of the central vision correction area and the peripheral vision correction area is determined as appropriate in consideration of the user's demands, living conditions, environment, and the like. Further, the intermediate area 18 spans between the central vision correction area 14 and the peripheral vision correction area 16 so as to connect the different lens powers set in the respective vision correction areas 14 and 16 as smoothly as possible. A lens power that gradually changes in the radial direction is set. In particular, the intermediate region 18 is divided into two radially inner and outer peripheries in terms of lens shape, and an inner transition region 20 connected to the central vision correction region 14 and an outer connection connected to the outer vision correction region 16. And a transition area 22.
[0025]
Therefore, in the central vision correction area 14 and the outer peripheral vision correction area 16, the radial frequency distribution is expressed by a zero-order expression related to the distance from the optical central axis: P, while in the intermediate area 18, the radial distribution In each of the inner transition area 20 connected to the central vision correction area 14 and the outer transition area 22 connected to the outer vision correction area 16, the frequency distribution is reversed so that the sign of the secondary term is reversed. The lens power in the vision correction area 12 is set as represented by a quadratic expression relating to the set distance from the optical center axis.
[0026]
More specifically, for example, when the central vision correction area 14 is a near vision correction area and the outer vision correction area 16 is a distance vision correction area, preferably, (Formula 1) to (Formula 10) are preferably used. ), The lens power distribution in each vision correction area is designed. A specific example of the result of actually designing the lens power distribution according to these equations is shown in FIG. As is clear from the results shown in FIG. 2, many portions of the central optical unit 24 that are advantageously used for near-field observation are constituted by the central vision correction region 14 in which a constant lens power: Pa is set. Therefore, many portions of the outer optical part 26 that are advantageously used for far-distance observation are constituted by the outer peripheral vision correction region 16 in which a constant lens power: Pc is set. As a result, a clear image can be advantageously recognized in both the near-field observation and the far-field observation. In addition, the radial dimension of each vision correction area 14, 16, 18 is within the range satisfying the above (Expression 1) to (Expression 10), and is appropriate in consideration of the user's preference and use environment. Can be set to
[0027]
In determining the specific shape of the contact lens 10 that gives the lens power designed as described above, for example, the inner surface of the contact lens 10 is formed with a spherical shape corresponding to the cornea shape of the user, The outer surface of the contact lens 10 can be advantageously designed by determining to provide the desired lens power, such as by using ray tracing.
[0028]
As shown in FIG. 2, the radial lens power distribution in the central vision correction region 14 is expressed as a quadratic curve in each of the inner transition region 20 and the outer transition region 22. Since the connection of the lens power to the central vision correction area 14 and the peripheral vision correction area 16 is designed to be extremely smooth, the lens surface shape can also be smoothed and an excellent wearing feeling is realized. At the same time, the occurrence of light scattering, ghosting and the like at the boundary between the central vision correction area 14 and the peripheral vision correction area 16 and the intermediate area 18 is advantageously prevented, and clear visibility can be realized.
[0029]
On the other hand, when the central vision correction area 14 is the distance vision correction area and the peripheral vision correction area 16 is the near vision correction area, preferably, the above (Expression 1) to (Expression 2) and (Expression 11) are used. ) To (Equation 18), the lens power distribution in each vision correction region is designed. A specific example of the result of actually designing the lens power distribution according to these equations is shown in FIG. As is apparent from the results shown in FIG. 3, many portions of the central optical unit 24 that are advantageously used for far-field observation are constituted by the central vision correction region 14 in which a constant lens power: Pc is set. In addition, many parts of the outer optical part 26 that are advantageously used for near-field observation are constituted by the outer peripheral vision correction region 16 in which a constant lens power: Pa is set. In the example, similarly to the specific example shown in FIG. 2, a clear image can be advantageously recognized in both the near and far observations, and the central vision correction area 14 and the outer peripheral vision correction area. 16 is smoothly connected in the intermediate region 18, and excellent wearing feeling and visibility can be advantageously realized.
[0030]
In the contact lens 10 shown in FIG. 1, the optical center axis P of the vision correction area 12 is matched with the geometric center axis O of the lens outer shape. It is not always necessary to match the optical central axis P of the lens with respect to the geometric central axis O of the lens outer shape. The vision correction area 12 depends on the amount of deviation between the optical center axis P of the vision correction area 12 and the geometric center axis O of the lens outer shape, the size of each vision correction area 14, 16, 18, and the like. When a part of 12 is removed from the outer shape of the lens, a circular central vision correction region 14 with a part of the outer periphery cut out, or an annular or arcuate shape with a part of the outer periphery cut out Area 18 and peripheral vision correction area 16 may also be employed.
[0031]
Specifically, for example, as shown in FIG. 4, the optical central axis P of the vision correction region 12 is set to the nose side (see FIG. It is also effective to set the position so as to be biased downward (in the middle, right side). That is, the corneal surface of the human eye generally has a larger curvature on the ear side than the curvature on the nose side. Therefore, when the contact lens is worn, the geometrical central axis O of the contact lens is on the ear side. In addition to the tendency to shift, the human gaze tends to be slightly viewed downward for reasons such as the living environment. Therefore, when the above-described deviation is set, the optical center axis P of the contact lens can easily coincide with the center of the pupil at the time of wearing, and the usability of the contact lens can be further improved. is there. In FIG. 4, for easy understanding, the contact lens 10 shown in FIG. 1 is shown for each of the parts having the same structure as the contact lens 10 shown in FIG. 1. The same reference numerals are assigned.
[0032]
Further, in the above description, the simultaneous vision type contact lens has been described. However, the multifocal ophthalmic lens having the structure according to the present invention has a geometrical structure with respect to the optical central axis and the lens outer shape of each vision correction region. By appropriately setting the amount of deviation from the central axis, the size of each vision correction area, etc., the present invention can be advantageously applied to a visual axis moving type ophthalmic lens.
[0033]
FIG. 5 shows a contact lens 30 as a specific example in which the present invention is applied to a visual axis moving type ophthalmic lens. In the contact lens 30, the central vision correction area 14 is a near vision correction area, the outer vision correction area 16 is a distance vision correction area, and the central vision correction area 14 and the outer vision correction. The optical center axis P of the vision correction area 12 including the area 16 is set so as to be deviated downward with respect to the geometric center axis O of the lens outer shape. In FIG. 5, L is a horizontal line at the time of wearing through the geometrical central axis O of the lens outer shape, and M is a vertical line.
[0034]
In the contact lens 30 having such a structure, when the wearer moves his / her line of sight downward during reading or the like, a wide portion on the pupil is covered with the central vision correction area 14. Depending on the frequency, near vision correction can be effectively performed, and visibility of near points can be ensured. On the other hand, when the wearer moves his / her line of sight from the center to the upper side when driving a car or the like, a wide area on the pupil is covered with the outer peripheral vision correction area 16, and the distance vision correction is performed by the lens power of the outer peripheral vision correction area 16. This is done effectively to ensure the visibility of far points.
[0035]
In the contact lens 30, the optical center axis of the vision correction region 12: the geometric center axis of the lens outer shape of P: the amount of deviation vertically downward with respect to O: e is set to e ≦ 7.0 mm. It is desirable. Thereby, both near vision and far vision can be advantageously ensured under general living conditions. Further, in the contact lens 30, in consideration of the lens position shift at the time of wearing, etc., preferably, as shown in FIG. 5, the optical central axis P of the vision correction region 12 is the geometry of the lens outer shape. Target central axis: set to be inclined obliquely downward to the nose side (right side in the figure) with respect to O. Further, in the contact lens 30, more preferably, the lens power distribution in the vision correction region 12 is set according to the above (Expression 1) to (Expression 10).
[0036]
Further, FIG. 6 shows a contact lens 32 as another specific example in which the present invention is applied to a visual axis moving type ophthalmic lens. In such a contact lens 32, the central vision correction area 14 is a distance vision correction area, the outer vision correction area 16 is a near vision correction area, and the central vision correction area 14 and the outer vision correction. The optical center axis P of the visual acuity correction area 12 including the area 16 is set to be deviated upward with respect to the geometric center axis O of the lens outer shape.
[0037]
In the contact lens 32 having such a structure as well, as in the contact lens 30 shown in FIG. 5, the distance vision correction range and the near vision acuity according to the movement of the wearer's line of sight, that is, the position of the pupil center. By selectively using the correction area, both the far and near visual clarity can be advantageously ensured. In the contact lens 32, the optical center axis of the vision correction region 12: the geometric center axis of the lens outer shape of P: the amount of deviation vertically upward with respect to O: e ′ is set to e ′ ≦ 7.0 mm. It is desirable that both near vision and distance vision can be advantageously ensured under general living conditions.
[0038]
In addition, in the contact lens 32 as well, in the same manner as the contact lens 30 shown in FIG. 5, it is preferable to take into account the lens position shift at the time of wearing, etc. The central axis P is set to be deviated obliquely upward on the nose side with respect to the geometrical central axis O of the lens outer shape. Further, in the contact lens 32, more preferably, the lens power distribution of the vision correction region 12 is set according to the above (Expression 1) to (Expression 2) and (Expression 11) to (Expression 18).
[0039]
As mentioned above, although embodiment of this invention was explained in full detail, these are literal illustrations, Comprising: This invention is not limited at all by the specific description regarding these embodiment.
[0040]
For example, in the vision correction area, the lens power may be set differently in different radial directions by combining cylindrical lenses (toric surfaces), and in the intermediate area, the change in the lens power in the radial direction may be set. The rate may be different in each radial direction.
[0041]
Further, the central vision correction area, the outer peripheral vision correction area, and the intermediate area do not have to be completely circular or annular, and an elliptical shape or the like can be adopted.
[0042]
Furthermore, the present invention is particularly advantageously applied to a presbyopic contact lens, but is not limited thereto and can be applied to various contact lenses, intraocular lenses, and the like.
[0043]
In addition, although not enumerated one by one, the present invention can be carried out in a mode to which various changes, modifications, improvements and the like are added based on the knowledge of those skilled in the art. It goes without saying that all are included in the scope of the present invention without departing from the spirit of the present invention.
[0044]
【The invention's effect】
As is clear from the above description, in the multifocal ophthalmic lens structured according to the present invention, there are two particularly required two types of eyesight correction areas, a central vision correction area and a peripheral vision correction area that do not change in power in the radial direction. Visibility at distance points (near and far points) is extremely advantageously ensured, and the central vision correction area and the peripheral vision correction area are connected with a smooth frequency change by the intermediate area. As a result, the occurrence of image jumps, ghosts, and the like is suppressed, and excellent clarity and usability can be obtained.
[Brief description of the drawings]
FIG. 1 is an explanatory front view showing a specific example of a contact lens as an embodiment of the present invention.
FIG. 2 is a graph for explaining a specific setting example of a lens power distribution in a contact lens as an embodiment of the present invention.
FIG. 3 is a graph for explaining another specific setting example of the lens power distribution in the contact lens as the embodiment of the present invention.
FIG. 4 is an explanatory front view showing another specific example of a contact lens as an embodiment of the present invention.
FIG. 5 is a front explanatory view showing still another specific example of a contact lens as an embodiment of the present invention.
FIG. 6 is a front explanatory view showing still another specific example of a contact lens as an embodiment of the present invention.
[Explanation of symbols]
10, 30, 32 Contact lens
12 Vision correction area
14 Central vision correction area
16 Peripheral vision correction area
18 Intermediate area
20 Inner transition area
22 Outer transition area

Claims (6)

In a multifocal contact lens having a plurality of vision correction regions set with different lens powers,
The vision correction area is separated from the central vision correction area used for either the near vision observation or the far vision observation, and a lens power different from the central vision correction area is set to the outer peripheral side of the central vision correction area. The outer peripheral vision correction area used for either one of the near vision observation and the far vision observation , and the lens power intermediate between the central vision correction area and the outer vision correction area are set to the center. An intermediate area positioned between the vision correction area and the peripheral vision correction area is configured, and the central vision correction area and the peripheral vision correction area are optically concentric, and the central vision correction The outer diameter dimension of the area is 0 to 8 mm, the radial width dimension of the intermediate area is 0.1 to 3.5 mm, and the lens power in the central vision correction area and the outer peripheral vision correction area is set to the entire radial direction. respectively and a constant throughout On the other hand, the rate of change gradually increases as the distance from the central vision correction area increases toward the lens power side of the outer peripheral vision correction area from the lens power of the central vision correction area in contact with the central vision correction area. An inner transition region that changes in frequency to a quadratic curve, and from the outer peripheral vision correction region toward the lens power side of the central vision correction region from the lens power of the outer peripheral vision correction region in contact with the outer peripheral vision correction region It consists of an outer transition area that changes in frequency in a quadratic curve with the rate of change gradually increasing as it moves away, and by matching the lens power at the boundary between the inner transition area and the outer transition area, the frequency change on this boundary sets the inflection point, the boundary of the inner transition region and the outer transition area in the intermediate region it is, contains radial center position of the intermediate region, the proximal observation than Multifocal contact lens which is characterized by being configured so as to bias the side of the vision correction area that is. The lens power set in the central vision correction area is Pa, the lens power set in the outer peripheral vision correction area is Pc, and the lens power at the boundary between the inner transition area and the outer transition area in the intermediate area is Pb, the distance from the optical center axis of the vision correction area to the boundary between the central vision correction area and the intermediate area, Wa, from the optical center axis of the vision correction area to the boundary between the inner transition area and the outer transition area in the intermediate area If the distance is Wb and the distance from the optical center axis of the vision correction area to the boundary between the outer vision correction area and the intermediate area is Wc, the lens power in the inner transition area of the intermediate area: y is the vision correction area X is the distance from the optical center axis of
y = Pa− (Pa−Pb) × (Wa−x) ² / (Wa−Wb) ²
And the lens power in the outer transition area of the intermediate area: y is
y = Pc− (Pc−Pb) × (Wc−x) ² / (Wc−Wb) ²
The multifocal contact lens according to claim 1 represented by: A central optical unit for near viewing is configured including the central vision correction area, and an outer peripheral optical unit for far viewing is configured including the outer vision correction area, and these central vision correction areas 3. The multifocal contact lens according to claim 1, wherein an optical center point of the outer vision correction area is deviated downward with respect to a lens outer shape center point, and a deviation amount thereof is 7.0 mm or less. . A central optical unit for distant observation is configured including the central vision correction region, and an outer peripheral optical unit for near observation is configured including the outer visual correction region, and these central vision correction regions and the optical center point of the outer vision correction region, along with is offset upward with respect to the lens outline center point, multifocal according to any one of claims 1 to 3 that bias amount is equal to or less than 7.0mm Type contact lens. The multifocal contact lens according to any one of claims 1 to 4 , wherein in the central vision correction area and the outer peripheral vision correction area, the surface shape for determining the power is a spherical surface. Wherein the vision correction area, multifocal contact lens according to any one of claims 1 to 5 or one of the lens surfaces is a toric surface.

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