JPH05168598A - Opthalmic apparatus - Google Patents

Abstract

PURPOSE:To rapidly obtain the optimum operation distance by performing alignment operation by together using first and second index optical systems. CONSTITUTION:A reticle 13 for collimation is formed on the anterior eye part image of an eye 2 to be examined while said image is observed by a TV monitor. A first index optical system is adjusted so that the vertex V of the cornea is positioned on an optical axis. That is, a first index is projected on the eye 2 to be examined from the front thereof and the reflected light of the cornea 11 reflected to the front of the eye 2 to be examined is formed into an image on an anterior eye part image. A second index optical system adjusts the distance l1(operation distance) between the vertex V of the cornea and the tip 3a of a nozzle. That is, a second index is projected on the eye 2 to be examined at a predetermined angle and the reflected light of the cornea 11 reflected in the direction almost symmetric with respect to the optical axis of the first index optical system is detected to superpose light detection data on the anterior eye part image. Then, said reflected light is formed into an image on the imaging surface 7a of CCD camera 7. By this constitution, the optimum operation distance can be rapidly obtained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-contact tonometer for measuring the intraocular pressure based on the deformation of a cornea by blowing a gas for deforming the cornea toward the cornea, and particularly to the eye to be examined. The present invention relates to an alignment adjustment system for performing alignment adjustment with a non-contact tonometer.

[0002]

2. Description of the Related Art As a conventional non-contact tonometer, for example,
The one shown in Japanese Examined Patent Publication No. 56-6772 is known. The alignment adjustment system of this non-contact tonometer projects the index so as to form an image on the center of curvature of the cornea via the objective lens, and the reflected light by the specular reflection of the cornea of the projected light is again passed through the objective lens. It is configured to return to the observation optical system and form an image on the sighting plate. The alignment between the device and the cornea of the eye to be inspected is performed by the position and sharpness of the index image on the aiming plate.

[0003]

However, this alignment system has a drawback that the working distance depends on the radius of the corneal curvature of the eye to be inspected, in order to form an image of the index on the center of the corneal curvature, and has an error. In addition, because the adjustment of the working distance between the non-contact tonometer and the cornea of the eye is performed only by the sharpness of the index image at one point, it cannot be distinguished whether it is too far or too close. There is also a drawback that it is difficult to determine if there is.

An object of the present invention is, firstly, to provide an alignment adjusting system for a non-contact tonometer which can obtain a working distance without depending on the radius of curvature of the cornea of the eye to be examined. Secondly, when adjusting the working distance, the examiner can judge whether the distance between the cornea of the eye to be inspected and the non-contact tonometer is too far or too close, and how much it is. An object is to provide an alignment adjustment system for a tonometer.

[0005]

In order to achieve the above object, the ophthalmologic apparatus of the present invention has the following features. (1) In an ophthalmologic apparatus that requires the eye to be inspected and the device to be aligned in a predetermined relationship, an observation unit for observing an anterior segment image of the eye and aiming on the anterior segment image by the observation unit. Forming means for forming a reticle for use, first index means for projecting a first index from the front of the eye to be inspected and forming corneal reflected light reflected on the front on the anterior segment image, and to the eye to be inspected Correspondingly, the second index is projected from a predetermined angle, corneal reflected light reflected in a direction substantially symmetrical with respect to the optical axis of the first index means is received, and the received light information is superimposed on the anterior segment image.
It is characterized by having an index display means.

(2) The display means for the second index of (1) is characterized by having an image forming optical system for optically superimposing the corneal reflection image on the anterior segment image.

(3) An optical element for rotating the image direction is arranged in the image forming optical system of (2).

(4) The image forming optical system of (2) is characterized in that an optical element that transmits the light of the second index but does not transmit the observation light of the anterior segment and the light of the first index is arranged.

(5) The display means of the second index of (1) is a light receiving means for receiving the reflected light of the cornea, and a pattern generator for electrically generating positional information of the eye to be inspected and the device based on the light receiving result. It is characterized by

(6) The first index means of (1) is characterized in that an optical element that transmits the anterior ocular segment observation light and the light of the first index but does not transmit the light of the second index is arranged.

(7) The ophthalmologic apparatus of (1) is a non-contact tonometer having a nozzle that blows fluid from the front of the cornea, and the light of the first index passes through the nozzle and is projected onto the eye to be examined. It is characterized by

(8) In the ophthalmologic apparatus of (1), the second index is provided with display position regulating means for displaying the second index as a vertical component with respect to the eye image to be inspected on the display means.

(9) The display position restricting means of (8) is a light receiving means for receiving the corneal reflected light, and a pattern for moving the positions of the eye to be inspected and the device in the vertical direction of the eye image based on the light receiving result. The feature is that it is a pattern generator that is electrically generated as a generator.

(10) The display position regulating means of (8) is
A field diaphragm having a slit, a first optical system in which the second index image is defocused in the width direction of the slit of the field diaphragm in the longitudinal direction, and a longitudinal direction of the slit of the field diaphragm in the eye to be examined. It is characterized by comprising an image moving optical system that moves in the vertical direction with respect to the image, and an image forming optical system that forms the field stop image.

[0015]

Embodiment 1 An embodiment of the non-contact tonometer according to the present invention will be described below with reference to the drawings. FIG. 1 is a view of the optical system of the apparatus as viewed from above. The optical system is roughly composed of an observation optical system, a first index optical system for aligning the eye to be inspected with the measurement axis, and a second index optical system for adjusting the working distance.

[Observation optical system] The illumination light source 1 includes an eye 2 to be inspected.
The anterior segment of the eye. A nozzle 3 for injecting gas is arranged on the optical axis 1 of the observation optical system with their axes aligned, and the reflected light flux of the eye 2 to be examined passes through the inside of the nozzle 3. Reference numeral 4 denotes a filter having a property of transmitting the light fluxes of the observation optical system and the first index optical system and not transmitting the light fluxes of the second index optical system. Reference numerals 5 and 6 are objective lenses for forming an anterior segment image on the imaging surface of the CCD camera 7. The eye 2 to be inspected is illuminated by the light source 1 for illumination, is imaged on the imaging surface 7a of the CCD camera 7 by the objective lenses 5 and 6, and is displayed on the TV monitor.

[First Index Optical System] The first index optical system adjusts the corneal apex v on the optical axis 1 (see FIG. 2). Reference numeral 8 denotes a light emitting diode as an index light source, and a light emitting diode that emits light having a wavelength similar to that of the illumination light source 1 is selected. The collimator lens 9 collimates the light flux, and after the light flux is limited in width, it is reflected by the half mirror 10 toward the eye to be examined and is coaxial with the observation optical system. The light flux passes through the nozzle 3 and is projected onto the cornea 11 from the front. The virtual image i ₁ of the index generated by the specular reflection of the cornea is formed on the image pickup surface 7a by the observation optical system. Since the corneal reflected light is limited in the width of the light flux by the end 3b of the nozzle 3 near the objective lens 5, the object depth becomes deep, and the virtual image i ₁ is clearly imaged on the imaging surface 7a in a relatively wide range. Therefore, the index does not largely deviate when the working distance is adjusted by the second index optical system described later. Reference numeral 12 denotes a reticle light source, which illuminates a reticle 13 formed of a ring slit, reflects it by a half mirror 14, and picks up an image pickup surface 7a of the CCD camera 7.
A reticle image is formed on the.

[Second Index Optical System] The second index optical system is for adjusting the distance between the corneal vertex v and the tip 3a of the nozzle 3 from the cornea 11, that is, the working distance WD ₀ . A light beam from an index light source 15 which is a light emitting diode having a wavelength different from that of the light emitting diode 8 is collimated by a collimator lens 16 and is projected onto the cornea 11 obliquely from the front. The projected light flux forms a virtual image i _{2 of} an index generated by the corneal specular reflection of the eye 2 to be inspected.

The index image forming optical system includes objective lenses 19 and 2.
0, a mirror 21, a filter 22, and an image rotator 23. The virtual image i ₂ of the light emitting diode 15 generated by the corneal mirror reflection is imaged on the imaging surface 7a by the index imaging optical system. On the image pickup surface of the CCD camera 7, the optical axis 1 intersects the optical axis of the second index optical system. The optical axes of the second index projection optical system and the second index imaging optical system intersect each other at a point having a working distance WD ₀ from the tip 3a of the nozzle 3 and are symmetrical with respect to the optical axis l. Are arranged as follows. Further, the plane including the optical axis 1 and the optical axis of the second index optical system is aligned with the lateral direction of the subject's eye 2.
This is to prevent the projection light of the second index optical system and its corneal reflection light from being blocked by the upper and lower eyelashes and eyelids of the eye 2. The filter 22 is for preventing the subject's eye 2 and the virtual image i ₁ from being reflected on the imaging surface 7a through the index imaging optical system.

As the image rotator, a combination of generally known mirrors having three reflecting surfaces or a cemented prism is used. The image is installed so that the image rotates about the optical axis by 90 ° in the clockwise direction with respect to the traveling direction of the light. FIG. 3 shows an example of the image rotator, and FIG. 4 shows the installation position of the image rotator. With this arrangement, the change in the position of the virtual image i ₂ due to the distance-near change of the distance l ₁ between the cornea 11 of the eye 2 to be examined and the tip of the nozzle 3 is different from the image of the eye 2 on the imaging surface 7 a. It is possible to correspond to the movement of the lower-upper index image. The second index optical system can be shared with the detection optical system that detects the deformation state of the eye to be inspected.

The operation of the apparatus having the optical system for alignment adjustment as described above will be described below. FIG. 5 is an external view of an example of a non-contact tonometer incorporating an alignment adjustment system. After fixing the subject's face to the chin rest 30, the examiner operates the operating rod 31 to move the housing 33 (which houses the alignment adjustment system and the measuring unit) relative to the sliding base 32, and the TV The positions of the eye to be inspected and the housing 33 are adjusted so that the anterior segment of the eye to be inspected is displayed on the monitor 34. Subsequently, the examiner finely adjusts the alignment while observing the image on the TV monitor 34. In FIG. 6A, 35 is a reticle image, 3
6 is an anterior segment image of the subject's eye, S ₁ is an index image of the first index optical system, and S ₂ is an index image of the second index optical system. Corneal vertex V
Comes in front of the nozzle 3, the index image S ₁ formed by the first index optical system and the index image S of the second index optical system are formed as shown in FIG. ₂ appears.
The examiner operates the operating rod 31 to insert S ₁ into the circle of the reticle image 35. When the position of S ₁ is determined, it means that the device and the eye to be inspected can be aligned vertically and horizontally. That is,
The corneal vertex v is on the optical axis l.

At this time, the index image S of the second index optical system
₂ is positioned above or below the reticle image 35 by the image rotator 23, as shown in (c) and (d).
If S ₂ is on the reticle image 35, the nozzle tip 3
The distance l ₁ between a and the corneal apex v is shorter than the predetermined working distance WD ₀ , and is longer when it is below. The examiner can determine the length of the distance l _{1 based on} the position of S ₂ , and by moving the operating rod 31 in the directions indicated by the arrows in (c) and (d), the S ₂ is moved to the first position in the reticle image 35. It is matched with the index image S ₁ of the index optical system. After the alignment operation is completed in this way, measurement is started by a measurement system (not shown).

Although the reticle image is optically formed in this embodiment, the figure generated by the electronic circuit may be combined with the image taken by the CCD camera 7 by the combining circuit to be shown to the examiner. Good. In addition, although the index image of the second index optical system is optically formed on the TV monitor, a light receiving element (for example, a two-divided element) is arranged (preferably at the image formation position of the corneal reflection image) and detected. Position of the index image (and light intensity)
It is also possible to detect the moving direction (and the moving amount) by a microcomputer from the above and display it as a character or a figure on the monitor by an electronic circuit (pattern generator) or the like. In this case, there is an advantage that the display can be performed in consideration of human sense and operability.

[0024]

Second Embodiment A second embodiment is a modification of the first embodiment. In each of the first embodiment, the first index image and the second index image, which are bright spot images, are displayed on the TV monitor. However, in the second embodiment, the first index image and the second index image displayed are distinguished. Clarify and improve operability. FIG. 7 is an optical system layout showing an embodiment of the second alignment adjustment system. Since the same reference numerals are given to the respective parts of the second embodiment that are substantially equivalent to the parts of the first embodiment, duplicated description thereof will be omitted. The difference from the apparatus of the first embodiment is the configuration of the index imaging optical system in the second index optical system. An objective lens 37, a cylindrical lens 38, a field stop 39, and a relay lens 40 are provided instead of the objective lenses 19 and 20 of FIG.

The objective lens 37 is a cylindrical lens 3.
Virtual image i ₂ generated by corneal specular reflection in the absence of 8
The field stop 39 and the field stop 39 are installed so as to be conjugate with each other at a predetermined magnification when the alignment is completed. The cylindrical lens 38 has a refracting power only for a light beam in the direction perpendicular to the plane of the drawing, and a field stop 39 in the direction perpendicular to the plane of the paper.
Designed to be the default above. As shown in FIG. 8, the field stop 39 has a slit 41 as a stop and is arranged such that the longitudinal direction of the slit 41 is parallel to the paper surface of FIG. 7. The relay lens 40 is installed so that the field stop 39 and the image pickup surface 7a of the CCD camera are conjugated at a predetermined magnification. Therefore, the light flux from the virtual image i ₂ passes through the mirror -21 by the objective lens 37 and the cylindrical lens 38, and on the field stop 39, as shown in FIG. 9, a rod-shaped intermediate image B perpendicular to the slit 41.
make o. The length of the intermediate image Bo at this time is the slit 4
The optical system is designed to be longer than the width of 1. The intermediate image Bo of the portion passing through the slit 41 is released.
An image is formed on the image pickup surface 7a by the lens 40.

The image-rotor 23 is installed so that the image rotates 90 degrees counterclockwise about the optical axis in the light traveling direction. As a result, the slit 39 is projected on the imaging surface 7a in a vertically long direction with respect to the image of the subject's eye 2. Further, the change in the position of the virtual image i ₂ due to the change in the distance l ₁ between the cornea 11 of the eye 2 to be examined and the tip of the nozzle 3 is lower-upper than the image of the eye 2 on the imaging surface 7 a. It can correspond to the movement of the index image.

The arrangement is as described above. Next, the alignment operation will be described. The examiner performs the coarse position adjustment as in the first embodiment, and then finely adjusts the alignment while observing the index image on the TV monitor 34. 10A to 10E are images on the TV monitor 34 (the anterior eye image is b.
35 is a reticle image, 36 is an anterior segment image of the subject's eye, S ₁ is an index image formed by the first index optical system, and B ₁ is an index image of the second index optical system. Show. Three
Reference numeral 1 denotes an operating stick, which is shown to explain the relationship between the image on the monitor 34 and the movement of the operating stick. When the apex V of the cornea comes in front of the nozzle 3, as shown in (a), an index image S ₁ formed by the first index optical system appears. Figure 10 (a)
As described above, when S ₁ is largely displaced vertically from the reticle image, the index image B ₁ does not appear. The range in which the index image B ₁ appears is determined by the defocus amount by the cylindrical lens 38, and the defocus amount is determined by the correlation with the brightness of the index image B ₁ and the operability. In this embodiment, if S ₁ falls within the range of the reticle image 35 in the vertical direction of the circle, as shown in FIG.
₁ appears within the projected range of the field stop 39. When S ₁ enters the circle of the reticle image 35, the vertical alignment between the device and the eye is completed.

At this time, the index image B ₁ of the second index optical system is positioned above or below the reticle image 35 as shown in (c) or (d). When B ₁ is above the reticle image 35, the distance l ₁ between the nozzle tip 3a and the corneal vertex v is shorter than the predetermined working distance WD ₀ , and when it is below it, it is long. The examiner can judge the length of the distance l ₁ by the position of S ₂ ,
Operation rod 31 in the directions indicated by the arrows in (c) and (d), respectively.
By moving B ₁ to the _{first position} in the reticle image 35.
It is matched with the index image S ₁ of the index optical system (e in FIG. 10).
During this time, even if moving the eye up and down right and left by the involuntary eye movement, etc., of appearing range B ₁ represents, since limited to a range obtained by projecting the field stop 39 shown in dotted line in FIG. 11, S ₁ both observation of B ₁ Will be easier.

The above embodiment can be variously modified as mentioned in the description of the first embodiment, but such modifications are also included in the present invention as long as the technical idea is the same. Is.

[0030]

According to the present invention, since the alignment operation is performed by using the first index means and the second index means in combination, the optimum working distance can be quickly obtained without depending on the radius of curvature of the cornea of the eye to be examined. It has become possible.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a first alignment adjustment system.

FIG. 2 is a diagram showing a position of an eye to be inspected when alignment is completed.

FIG. 3 is a schematic diagram of an image rotator.

FIG. 4 is a diagram showing an installation position of an image rotator.

FIG. 5 is a diagram showing an external view of an embodiment of a non-contact tonometer.

FIG. 6 is a diagram showing an image displayed on a TV monitor.

FIG. 7 is a diagram showing an example of a second alignment adjustment system.

8 is a diagram showing the structure of a field stop 39. FIG.

FIG. 9 is a diagram illustrating how an intermediate image is formed by the field stop 39.

FIG. 10 is a diagram showing an image of Example 2 displayed on a TV monitor.

FIG. 11 is a diagram showing a range in which an index image B ₁ is formed in Example 2.

[Explanation of symbols]

 1 Light Source for Illumination 2 Eye to be Inspected 3 Gas Injection Nozzle 4, 22 Filter 7 CCD Camera 7a CCD Camera 7 Imaging Surface 8 Light Emitting Diode 10 Half Mirror 11 Corneal of Eye 2 12 Reticle Light Source 13 Reticle 14 Half Mirror 31 Operation Rod 32 Sliding table 34 TV monitor 35 Reticle image 36 Image of eye 2

Claims (10)

[Claims] 1. In an ophthalmologic apparatus that requires aligning an eye to be inspected and a device in a predetermined relationship, an observation means for observing an anterior eye image of the eye to be inspected, and an anterior eye image by the observation means. Reticle forming means for forming a sighting reticle, first index means for projecting a first index from the front of the subject's eye and forming corneal reflected light reflected on the front on the anterior segment image, and A second index is projected onto the optometry from a predetermined angle, corneal reflected light reflected in a direction substantially symmetrical with respect to the optical axis of the first index means is received, and light reception information is superimposed on the anterior segment image. An ophthalmologic apparatus comprising display means for displaying two indexes. 2. The ophthalmologic apparatus according to claim 1, wherein the display means for the second index has an image forming optical system that optically superimposes the corneal reflection image on the anterior segment image. 3. An ophthalmologic apparatus, wherein the image forming optical system according to claim 2 is provided with an optical element for rotating an image direction. 4. An ophthalmologic apparatus, wherein the imaging optical system according to claim 2 is provided with an optical element that transmits the light of the second index and does not transmit the anterior ocular segment observation light and the light of the first index. 5. The display means for the second index according to claim 1 is a light receiving means for receiving the corneal reflected light, and a pattern generator for electrically generating positional information between the eye to be inspected and the device based on the light receiving result. An ophthalmologic device characterized by being present. 6. The ophthalmologic apparatus according to claim 1, wherein an optical element that transmits the anterior ocular segment observation light and the light of the first index but does not transmit the light of the second index is arranged in the first index means of claim 1. 7. The ophthalmologic apparatus according to claim 1, which is a non-contact tonometer having a nozzle for spraying a fluid from the front of the cornea, and the light of the first index is projected onto the eye to be examined through the inside of the nozzle. An ophthalmologic apparatus characterized by the above. 8. The ophthalmic apparatus according to claim 1, wherein the second
An ophthalmologic apparatus characterized in that display means is provided for displaying the index as a vertical component with respect to the eye image on the display means. 9. The display position restricting means according to claim 8, wherein the light receiving means receives the light reflected by the cornea, and the pattern for moving the positions of the eye to be inspected and the device in the vertical direction of the eye image based on the light receiving result.
An ophthalmologic device characterized in that it is a pattern generator that is electrically produced as a computer. 10. The display position regulating means according to claim 8, wherein the field stop having a slit and the second index image defocuses in the width direction of the slit of the field stop in the longitudinal direction. An optical system, and an image moving optical system that makes the longitudinal direction of the slit of the field stop vertical with respect to the image of the eye to be inspected,
An ophthalmologic apparatus comprising an imaging optical system for forming the field stop image.