JPH0614134B2 - Indirect optometry lens device - Google Patents

Description

The present invention relates to an indirect optometry lens apparatus.

(Prior Art) Generally, a lens for indirect optometry has two functions, and the first is to collect light from an ophthalmoscope light source as a condenser lens to illuminate the fundus of the eye, At the same time, the second is to form an aerial image of the fundus by utilizing the light that emerges from the eye as an imaging lens. The image is observed monocularly using a monocular indirect ophthalmoscope or binocularly and stereoscopically using a binocular indirect ophthalmoscope.

Traditionally, Sudarsky and Volk
"Aspherical of the Objective Lenses
As An Aid In Indirect Off Of Salmoskopy, A Preliminary Report (Aspheric
al Objective Lenses As an Aid in Indirect Ophthalm
oscopy, A Preliminary Report) ", reports a study conducted using a conical lens designed for abnormal vision as a concentrating lens for indirect optometry.

As a result of their research, they found that for use in indirect optometry, three types of refracting power of a conic lens, each lens having one aspherical surface and the other surface being a flat or spherical surface, namely 15, 20 and It is recommended to use a lens with 3 diopters. When used, the aspherical surface on the front surface faces the examiner.

Around 1969, Nikon of Japan introduced an aspherical lens for indirect optometry whose front surface was aspherical and whose rear surface was spherical.

In the late 1970s, Kowa and Topcon (Topco)
Other Japanese manufacturers such as n) have launched aspherical lenses for indirect optometry. These lenses likewise have an aspherical front surface and a spherical rear surface. In the United States, American Optical Comp.
any) or Younger Lens Company
Manufactures and sells indirect optometry lenses, one of which is an aspherical surface and the opposite surface is a spherical surface.

Recently, the German company Zeiss has launched an indirect optometry lens with one aspherical surface and opposite spherical surface.

(Problems to be Solved) In all the above-mentioned conventional techniques, only one of the two surfaces of the indirect optometry lens is aspheric. Although the aspherical indirect optometry lens is a much improved version of the spherical indirect optometry lens, lens aberrations still exist, and therefore light from the opthalmoscope light source, such as a condenser lens, is the pupil of the eye or The image is not collected as a sharp outline at the entrance pupil, and the fundus aerial image is curved to the examiner like an imaging lens, and astigmatism is increased toward the peripheral direction.

The present invention has been made in view of the above problems, and an object thereof is to use a biconvex aspherical lens that can be inexpensively manufactured by geometrically and mathematically specifying both lens surfaces. An object is to provide an optometry lens apparatus.

Further, an object of the present invention is to observe the entire fundus of the eye to be examined clearly with various aberrations such as field curvature, astigmatism, and distortion that can be substantially ignored by a simple alignment operation with respect to the eye to be examined. An object of the present invention is to provide an indirect optometry lens device that enables the above.

(Structure of the present invention) An indirect optometry lens device of the present invention comprises a biconvex conoid type aspherical lens which is made of a homogeneous transparent optical material and has opposite colloidal rotating aspherical surfaces on both sides, and the biconvex conoid type. An indirect optometry lens device comprising a lens holding means for movably holding an aspherical lens by an examiner's hand, wherein the top refraction of the front surface of one of the biconvex aspherical lenses facing the optometer. The power is 6.666 to 36.666 diopters, the apex power of the rear surface on the side facing the other eye to be examined is 3.333 to 18.333 diopters, and the apex power of the anterior surface and the posterior surface is expressed as a sum of the diopters. The biconvex aspherical lens has a nominal lens power of 10 to 55 diopters,
The front refractive power of the front surface is 1.5 times that of the rear surface.
.About.2 times, the eccentricity of the front surface is 0.80 to 1.45, and the eccentricity of the rear surface is 0.50 to 3.80, and the biconvex conoid aspherical lens is moved by moving the lens holding means. The optical axis of the lens is made to pass through the center of the entrance pupil of the eye to be inspected and is arranged in front of the eye to be inspected at an interval equal to the back focal length of the biconvex conoid aspherical lens. The fundus aerial image of the optometry is formed so that the entire area of the fundus aerial image can be clearly observed by the optometer.

The eccentricity is a mathematical expression as is well known, and it is defined as the ratio of the distance from the point on the conical section curve to the focal point and the distance to the quasi line.

The diameter of the indirect optometry lens is generally 52 mm to 31 mm, and the low refractive power lens has a large diameter.

In Table 1, the first column lists those having a nominal refractive power in the range of 10 to 55 diopters, the second column has a large diameter, and the third column has a small diameter. The lens diameter is shown in millimeters.

Generally, a lens having a diameter of 31 mm is quite satisfactory as a lens having a refractive power of 50 and 55 diopters. One type of diameter has been proposed for these lenses, but diameters other than 31 mm can be used.

Hereinafter, the present invention will be described with reference to the accompanying drawings showing embodiments.

(Example) In FIG. 1, the graph shows the nominal refractive power with respect to the diameter of the indirect optometry lens expressed in millimeter units. The upper curve in the graph represents the correspondence between the lens diameter and the lens diameter for a lens called a large lens. The lower curve in FIG. 1 is for a small lens of an indirect optometry lens. FIG. 1 is merely an example,
Lenses larger or smaller than those of the diameter indicated by the middle or upper curve and the lower curve between the two curves can be utilized. The dotted line in FIG. 1 represents a practical lens having a lens power and diameter that are considered to be within the scope of the present invention, and the solid line represents a lens having a preferred lens power and diameter. A lens of 10 to 15 diopters is used when an aerial image having an extreme magnification is desired, and the occupancy of the fundus image in the aerial image is increased, that is, the angle of view of the fundus image is increased to 50.
A ~ 55 diopter lens is utilized.

In designing a lens applicable to the present invention, the first feature of the design principle is that the lens and the eyeball form a telecentric system as shown in FIG. 2, and the secondary focus of the lens is located at the center of the pupil of the eyeball. As described above, the concentric bundle of coaxial plane rays incident on the front surface of the lens in this way converges or concentrates again at the secondary focal point of the lens, which is the center of the pupil of the eyeball.

FIG. 2 shows a lens-eye telecentric system in the device of the present invention, in which light rays travel beyond the pupil,
Illuminate the inner back of the eyeball. At the same time, each illuminating point in the posterior part of the eye emits light in all directions, and a concentric bundle of rays passes through the pupil of the eye. Assuming that the eyeball is a perfect normal eye, each ray bundle emerging from the eyeball is a ray bundle parallel to the principal ray bundle passing through the center of the pupil of the eyeball and is incident on the indirect eye examination lens as shown in FIG. Then, it is refracted by the lens and travels parallel to the lens axis.

The second feature of the lens design principle applicable to the present invention is
The objective is to design the indirect optometry lens as follows. That is, as shown in FIG. 3, the lens is arranged at a position that forms a telecentric system with respect to the eyeball, and the indirect optometry lens refracts it as a concentric exit parallel ray bundle that surrounds each principal ray, and substantially refracts in the front focal plane. This is to form a fundus aerial image in which various aberrations such as field curvature, astigmatism and distortion can be ignored. FIG. 3 shows the second characteristic item.

Since the telecentric system as shown in FIGS. 2 and 3 is used, both the ophthalmoscope light source and the observation system are arranged at infinity with respect to the eyeball to be observed. At the time of use, the light source and the observation system for the eyeball should be placed as close to the eyeball as possible.
The light rays are made to diverge from the imaginary light source toward the indirect optometry lens. Therefore, the virtual light source image formed by the indirect optometry lens is formed slightly further than the secondary focal plane of the indirect optometry lens.

As a result, the lens must be moved slightly forward so that the virtual source image is formed at the center of the entrance pupil of the eye. FIG. 4 shows that the light rays emitted from the small filament F in the ophthalmoscope are refracted by the lens C and then reflected from the mirror M toward the indirect optometry lens I as a divergent ray bundle. is there.

FIG. 5 shows an image formed by an indirect optometry lens, in which the fundus image is substantially flat, has no distortion and no astigmatism, and is formed on the front focal plane of the indirect optometry lens, and is the chief ray of the ray bundle emerging from the lens. Are concentrated.

FIG. 6 shows the optical principle of the observation system of the indirect optometry lens apparatus for binoculars. Each ray bundle traveling from the fundus aerial image toward the ophthalmoscope is divided by the central mirror into the left and right prisms. To the observer's eye. An indirect optometry lens that deviates from the ideal telecentric model in which the chief ray from the aerial image travels to infinity was also considered in the design of the lens applied to the present invention.

In the research on lenses applied to the present invention, various lens designs in which both surfaces of each lens are convex conoidal shapes (conical conical shape) and both lens surfaces have a wide range of vertex refractive power and a wide range of eccentricity The parameters have been defined. An ophthalmic crown glass with a refractive index of 1.523 is used as the first example of the optical material studied in this study.
As a second example, an ophthalmic plastic having a refractive index of 1.498 was used. The glass material is preferable because it has scratch resistance and can be processed by a multilayer coating to improve the light transmittance to 99% abnormally to reduce the reflection on the lens surface.

The indirect optometry lens applied to the present invention has a transparent or white color that transmits the entire visible spectrum, has a yellow color that transmits light in the green-yellow-orange-red part of the visible spectrum, and has an orange-red color of the visible spectrum. Of various colors, such as having an orange-red color that transmits light in the visible part, having a green color that transmits light in the green part of the visible spectrum, and having a blue color that transmits light in the purple-blue part and green-yellow part of the visible spectrum. It is a glass lens.

In designing the above lens, it has been found that the following relationships exist among various parameters.

The lens material is a homogeneous transparent optical material molded from glass or plastic, has two positive or convex rotating aspherical surfaces on opposite sides thereof, and the rotational axes of both aspherical surfaces are coaxial. The lens is held in front of the patient's eye at a distance substantially equal to the secondary focal length of the lens and the optical axis of the lens is passed through the center of the pupil of the patient's eye. One rotating aspherical surface faces the examiner as the front surface of the lens, and the other rotating aspherical surface faces the eye to be inspected as the rear surface of the lens.

The nominal lens power is defined as the sum of the apex powers on both sides and can be varied in the range of approximately 15-50 diopters. The apex refractive power of the front surface of the lens is approximately 6.666.
~ 36.666 diopters can be varied, while the apex power of the lens back surface is approximately 3.333 ~.
Variable within the range of 18.333 diopters.

The refractive power of the lens is in the range given above, but preferably has a useful nominal refractive power of approximately 10-5.
It is within the range of 5 diopters. Furthermore, in any of the lenses of the present invention, the refractive power of the front apex is selected to be 1.5 to 2 times the refractive power of the rear apex.

The eccentricity of the front surface can be selected to a value within the range of 0.80 to 1.45.

The eccentricity of the rear surface may be in the range of 0.50 to 3.80, and the eccentricity of the rear surface is set to a value within the above range with respect to the eccentricity of the front surface selected within the above range. We have selected and have virtually no astigmatism and distortion,
A spatial fundus image with a slight curvature of field can be obtained, and an examiner can clearly observe almost the entire fundus of the eyeball to be examined.

The lens applied to the present invention can be used for forming an optical system combined with an illumination system and an observation system of a suitable eye to be inspected, as schematically shown in FIGS. 4 and 6.

In the indirect optometry lens device of the present invention, the biconvex aspherical lens, in front of the eyeball to be inspected, is held by the optometer in a relationship with a distance substantially equal to the secondary focal length of the lens, The optical axis of the lens exists in a plane including the pupil of the eye to be inspected and the pupil of the observer, passes through the center of the pupil of the eye to be inspected, and passes through an intermediate portion between the pupils of both eyes of the observer. .

(Advantageous Effects) According to the indirect optometry lens apparatus of the present invention, the biconvex aspherical lens that can be manufactured at a low cost is substantially flat, and the astigmatism and distortion are substantially nonexistent in the fundus space of the non-optometric eye. An image is obtained, and the eye examiner can observe a clear fundus space image of the eyeball to be inspected.

[Brief description of drawings]

FIG. 1 is a graph of the nominal refractive power against the proposed millimeter diameter of a lens applied to the present invention. FIG. 2 is a schematic explanatory view of an indirect optometry lens apparatus of the present invention arranged so as to form a telecentric system with a lens and an optometry eyeball applied to the present invention. FIG. 3 is a schematic explanatory view showing how an indirect eye examination lens is combined with the eyeball to form a telecentric system in the apparatus of the present invention to form a fundus aerial image of the eyeball. FIG. 4 shows that the ray bundles emitted from the ophthalmoscope mirror are matched with the lens of the present invention, the reflected ray bundles of these rays are condensed as a light source image at the center of the entrance pupil, and the inner rear portion of the eye to be inspected. It is a schematic explanatory drawing of the ophthalmoscope irradiation system made to irradiate. FIG. 5 is a schematic explanatory view showing formation of a fundus aerial image by the indirect optometry lens in the device of the present invention. FIG. 6 is a schematic explanatory diagram of an ophthalmoscope observation system for binocularly and stereoscopically observing an aerial image formed by the indirect optometry lens in the device of the present invention. C ... Objective lens of ophthalmoscope, E ... Pupil of eyeball, I ... Indirect eye examination lens applied to the device of the present invention, F ... Observation light source light source (filament), M ... Reflection mirror.

Claims (8)

[Claims] 1. A biconvex conoid type aspherical lens made of a homogeneous transparent optical material and having conical conoidal rotational aspherical surfaces on opposite sides, and the biconvex conoidal aspherical lens is moved by an eye examiner's hand. An indirect optometry lens device configured to freely hold a lens holding means, wherein the birefringent aspherical lens has a top apex power of 6.666 to 36.666 diopters on the front side facing the optometer. , The nominal refractive power of the biconvex aspherical lens, which is represented by the sum of the refractive powers of the rear surface on the side facing the other eye to be inspected 3.333 to 18.333 diopters, and the total refractive power of the front surface and the rear surface. 10-55 diopters,
The front refractive power of the front surface is 1.5 times that of the rear surface.
.About.2 times, the eccentricity of the front surface is 0.80 to 1.45, and the eccentricity of the rear surface is 0.50 to 3.80, and the biconvex conoid aspherical lens is moved by moving the lens holding means. The optical axis of is passed through the center of the entrance pupil of the eye to be examined and is arranged in front of the eye to be examined with a distance equal to the back focal length of the biconvex conoid aspherical lens, whereby a substantially aberration-free object is obtained. An indirect optometry lens apparatus, which is capable of forming a fundus aerial image of an optometer so that the entire area of the fundus aerial image can be clearly observed by an optometer. 2. A homogeneous transparent optical material is glass.
Indirect optometry lens device according to the paragraph. 3. The indirect optometry lens apparatus according to claim 1, wherein the homogeneous transparent optical material is plastic. 4. An indirect optometry lens apparatus according to claim 1, wherein the spectral transparency of the homogeneous transparent optical material is high in the orange-red range and is limited to almost the orange-red part of the visible spectrum. 5. The indirect optometry lens apparatus according to claim 1, wherein the spectral transparency of the homogeneous transparent optical material is high in green and is limited to almost the green part of the visible spectrum. 6. An indirect optometry lens apparatus according to claim 1, wherein the spectral transmission of the homogeneous optical material is high in the yellow and limited to the green-yellow-orange-red part of the visible spectrum. 7. The indirect optometry lens system according to claim 1, wherein the spectral transparency of the homogeneous transparent optical material is high in the blue color and is limited to the violet-blue part and the green-yellow part of the visible spectrum. 8. The indirect optometry lens apparatus of claim 1, wherein the homogeneous transparent optical material is transparent to the entire visible spectrum.