JPH02203833A - Cubic eyeground camera - Google Patents

Abstract

PURPOSE:To make it possible to photograph the marks to show the common fixed points together with the eyeground by providing a mark projection optical system to project at least three marks not lining up on a straight line at the eyeground. CONSTITUTION:When an eyeground Er is photographed, a reflection mirror 38 is taken out from the optical passage as well as a light source 62 for photographing is lighted. The light flux radiated from the light source 62 for photographing is injected to an eye E to examine passing through a condenser lens 63, a half mirror 61, a ring aperture plate 53, a relay lens 56, a reflection mirror 52, a pinhole plate 48, a relay lens 51, a holed mirror 49, and an object lens 31. As a result, bright point images 48a'-48d' are formed on the eyeground Er. And the reflection light flux reflected by the eyeground Er reaches to a photograph film H passing through the object lens 31, the holed mirror 49, an aperture throttle plate 35, a poroprism 36 for image rightly standing purpose, focus lenses 37a and 37b, half mirrors 41a and 41b, relay lenses 46a and 46b, and poroprismes 47a and 47b for image rightly standing purpose, and bright point images 48a'-48d', and 48a''-48d'', together with eyeground images Er' and Er'' are formed on the photograph film H.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a stereoscopic fundus camera for stereoscopically photographing the fundus of the eye.

(Prior Art) Conventionally, as a stereoscopic fundus camera, those shown in FIGS. 8 and 9 are known. This consists of an objective lens 2 facing the eye 1 to be examined, a photographing system 3 for photographing the fundus, and an illumination optical system 4 for illuminating the fundus.The photographing system 3 passes through the objective lens 2 for stereoscopic viewing. It has a beam splitting optical system 5 that divides the beam into two, a photographing optical system 7 that photographs the fundus, and an observation optical system.

The beam splitting optical system 5 includes a beam splitter 8 that divides the beam into two, a circular aperture diaphragm 9 installed in front of the beam splitter 8 and having circular apertures (not shown) at symmetrical positions, and a relay. It consists of a lens 10.

The photographing optical system 7 includes an image forming Porro prism 16 and the like. 17 is a photographic film.

The observation optical system includes reflective mirrors 11 and 12, an image forming prism 13, a relay lens 14, an eyepiece 15, and the like.

The illumination optical system 4 includes a perforated mirror V having a long hole (not shown), a condenser lens 18, a reflection mirror 19,
There is a light shielding part (
The light shielding plate 21 includes a light shielding plate 21 (not shown), a half mirror 22, an illumination light source 24, and the like. 23 and 25 are condenser lenses, and 26 is a light source for photographing.

The light beam emitted from the illumination light source 24 passes through the lens 23,
The fundus of the eye 1 to be examined is illuminated through the half mirror 22, the light shielding plate 21, the relay lens 20, the reflective mirror 19, the condenser lens 18, the perforated mirror (2), and the objective lens 2. By the way, the light shielding plate 21 is installed at a position conjugate with the pupil 1a of the eye 1 to be examined, so that the image of the light shielding plate 2 is formed on the pupil la, and the illumination light is incident on the vicinity of the center of the pupil 1a. It is recommended not to do so.

The light reflected from the fundus of the eye passes through the objective lens 2 and the long hole of the oblique perforated mirror V, and is split into two by the beam splitting optical system 5. Then, the light beam divided into two is transmitted to the relay lens 1
0a, 10b, reflective mirror 11a, 1 lb, 12
a, 12b, the image erecting prism 13a13b, the relay lenses 14a, 14b, and the eyepieces 15a, 15b, and reach the observation eyes Ql, Q12, where the fundus 1b is stereoscopically observed.

When taking a photograph, the reflecting mirrors 11a and 11b are removed from the optical path and the photographing light source 26 is turned on. Then, two images of the fundus when the fundus is viewed from the left and right sides are captured on the photographic film 17.

When performing a three-dimensional analysis of the fundus from the binocular images captured on the film 17, first plot at least three fixed points common to both images on both screens so that they are not on the same straight line, and then Based on this, the deviation of the image at the analysis point is determined, and the height of the nipple, etc. is analyzed from that deviation. The reason why the three fixed points are not arranged in a straight line is because the vertical and horizontal magnifications of the image may be different.

(Problem to be Solved by the Invention) However, in the above-mentioned stereoscopic fundus camera, the examiner manually plots the fixed points, which is cumbersome, and the fixed points are plotted on the blood vessels that are common to both images. Although the intersection position and the edge of the nipple were taken, there were many problems such as it was very difficult to find the same position.

<Object of the Invention> This invention was made in view of the above-mentioned problems, and its purpose is to provide a stereoscopic fundus camera capable of photographing a mark indicating a common fixed point together with the fundus. There is a particular thing.

(Means for Solving the Problems) In order to achieve the above object, the present invention includes an illumination optical system that illuminates the fundus of the eye through an objective lens, and a photographic optical system that photographs the fundus of the eye through the objective lens. The stereoscopic fundus camera is characterized in that a mark projection optical system is provided for projecting at least three marks onto the fundus so that they are not aligned on the same straight line.

Further, the present invention is characterized in that a mark projection optical system is provided at a conjugate position of the fundus between the objective lens and the photographing optical system, for forming projected images of at least three marks so that they are not on the same straight line.

(Function) Three marks are formed on the fundus by the mark projection system,
The mark is photographed together with the fundus by the photographic optical system.

Further, three mark projection images are formed at positions conjugate with the fundus by the mark projection optical system, and the marks are photographed together with the fundus by the photographing optical system.

(Example) Embodiments of the present invention will be described below based on the drawings.

FIG. 1 is a side view showing the arrangement of the optical system of a stereoscopic fundus camera according to the present invention, and FIG. 2 is a plan view thereof. In the figure, 30 is an observation system for observing the fundus Er of the subject's eye E; 50 is an illumination optical system that illuminates the fundus Er.

The observation system 30 includes an objective lens 31 facing the eye E to be examined;
A splitting optical system 32 that divides the light flux passing through the objective lens 31 into two, a stereoscopic imaging optical system (photography optical system) 33 that stereoscopically photographs the fundus Er with the two divided light fluxes, a monitor optical system 34, and a stereoscopic viewing optical system. It consists of 45.

The dividing optical system 32 includes an aperture diaphragm plate 35 having two apertures (not shown), an image erecting Porro prism 36 that divides the light beam into two, and focusing lenses 37a and 37b. Note that the aperture diaphragm plate 35 is installed at a position conjugate with the pupil Ea.

The stereoscopic photographing optical system 33 includes a relay lens 46a.

48b, and image erecting prisms 47a and 47b, and H is a photographic film.

Further, the stereoscopic optical system 45 includes reflective mirrors 38°39,
It consists of eyepiece lenses 40a, 40b, etc. reflective mirror 3
8 jumps up to the position indicated by the broken line and deviates from the optical path when photographing.

The monitor optical system 34 is a half mirror 41a.

41b, relay lenses 42a and 42b, reflection mirrors 43a and 43b, and CCDs 44a and 44b. D is a display for monitoring the fundus image.

The illumination optical system 50 includes an aperture mirror 49 having a long hole P, a relay lens 51, a pinhole plate 48 installed at a position conjugate with the fundus Er, a reflection mirror 52, a relay lens 56, and a ring aperture 53a. It consists of a ring aperture plate 53 which has a circular aperture and is installed at a position conjugate with the pupil Ea, a condenser lens 54, and an illumination light source 55. Further, the illumination optical system 50 includes a half mirror in order to photograph the fundus Er.
61, a lens 63, and a photographing light source 62.

57 is a concave reflecting mirror.

The pinhole plate 48 can be moved to the position shown by the broken line to remove it from the optical path if necessary, and can also be moved in the direction of the arrow in conjunction with the focusing lens 37 to correct nearsightedness or farsightedness of the subject. Regardless of the situation, a bright spot image, which will be described later, is formed in focus on the fundus Er.

Further, as shown in FIG. 3, the pinhole plate 48 is constructed by providing four pinholes (marks) 48a to 48d with a transmittance of 100% on a disk 48k with a transmittance of 30% to 50%. .

The pinhole plate 48, the illumination light source 55, the relay lens 51, the perforated mirror 49, etc. constitute a mark projection optical system.

Now, when the illumination light source 55 is turned on, the light beam emitted from the illumination light source 55 passes through the condenser lens 54, the half mirror 61, the ring aperture plate 53, and so on. Relay lens 561 reflective mirror 52. Pinhole plate 48, relay lens 51. The subject's eye E passes through the perforated mirror 49 and the objective lens 31.
is incident on the

By the way, since the ring aperture plate 53 is installed at a position conjugate with the pupil Ea, a ring aperture image (not shown) of the ring aperture 53a is formed on the pupil Ea, and illumination light is directed from the ring aperture image to the fundus. The light will be incident on Er.

On the other hand, the pinhole plate 48 and the fundus Er have a nearly conjugate relationship.Furthermore, since the light beam of the illumination light source 55 passes through the pinhole plate 48, the pinhole plate 48 appears on the fundus Er as shown in FIG. Bright spot images 48a to 48d' are formed by the pinhole portions 488 to 48d. N is the nipple.

Then, the light beam reflected by the fundus Er passes through the objective lens 31,
Perforated mirror 49, aperture diaphragm plate 35, image erecting Porro prism 36, focusing lenses 37a, 37b1 half mirror
41a, 41b, relay lenses 42a, 42b,
The light passes through mirrors 43a and 43b and reaches CCDs 44a and 44b, and a fundus image is displayed on display D.

On the other hand, the light flux passing through the half mirrors 41a and 41b is
The light reaches the eyepiece lens 40 through the relay lenses 46a, 46b, the image erecting Porro prisms 47a, 47b, and the mirrors 38, 39, so that the fundus Er can be viewed stereoscopically.

When photographing the fundus Er, the photographing light source 62 is turned on and the reflecting mirror 38 is removed from the optical path.

The light beam emitted from the photographing light source 62 passes through the condenser lens 63. Half mirror 61, ring aperture plate 53, relay lens 569 reflecting mirror 52. Pinhole plate 48, relay lens 51. The light passes through the perforated mirror 49 and the objective lens 31 and enters the eye E to be examined. Therefore, similarly to the above, bright spot images 48a' to 48d' are formed on the fundus Er.

The reflected light flux by the fundus Er is composed of the objective lens 31, the perforated mirror 49, the aperture diaphragm plate 35, the image erecting Porro prism 36, and the focusing lenses 37a and 37b.
, half mirror 41a, 4 lb, relay lens 4
6 a, 46b, image erecting Porro prism 47a, 47
b, reaches the photographic film H, and the photographic film H
As shown in FIG.
d-- is formed.

The bright spot images 48a' to 48d' of the fundus image Er' and the bright spot images 48a to 48d'' of the fundus image Er=- indicate the same position on the fundus Er, so the binocular image Er-
, Er--, and therefore there is no need to plot a common fixed point on both images on the film H, as is the case in the past.

In the above embodiment, the pinhole plate 48 is installed between the relay lens 51 and the mirror 52, but the invention is not limited to this. For example, a half mirror F may be interposed between the mirror 52 and the relay lens 56. A pinhole plate G may be installed at a conjugate position with the pinhole plate 48, and the light from the illumination light source 55 may be guided to the pinhole portion Ga of the pinhole plate G through an optical fiber (not shown). J is a relay lens.

In addition, as shown in the second embodiment of FIG. 6, a light source (1) and a condenser lens (N) are provided so that the difference in the luminous flux emitted from the pinhole Ga is smaller than the illumination luminous flux (observation and photographing luminous flux). With this configuration, the depth of field of the bright spot image formed on the fundus Er becomes deeper than that of the entire illumination light.

FIG. 7 shows the third embodiment, which shows the fundus Er.
A mark projection optical system is provided to form a bright spot image before the light beam reflected by the CCD 44a, 44 is divided into two.
b and a photographic film H in which a bright spot image appears.

In FIG. 7, 71 is a half mirror with a transmittance of about 90% or more installed between the perforated mirror 49 and the aperture diaphragm plate 35, 72 is a relay lens, and 73 is installed at a position conjugate with the fundus Er. Binhole board, 74 is a diffuser board, 75
is a light source. In this embodiment, the relay lens 72 allows the image of the pinhole plate 73 to be placed at a position conjugate with the fundus image formed by the objective lens 31. The half mirror 71, relay lens 72, pinhole plate 73, and light source 75 constitute a mark projection optical system.

The pinhole plate 73 has a transmittance of 0% as in the above embodiment.
It is constructed by providing four pinholes (see Fig. 3) with 100% transmittance in a disc, which moves in the direction of the arrow in conjunction with the focusing lenses 37a and 37b, as described above. However, a pinhole image is always formed at a position conjugate to the fundus image.

In the above embodiment, a bright spot or a virtual image of a bright spot is formed at the fundus Er or a conjugate position of the fundus Er, but a black spot may be formed instead of a bright spot. The point is not limited to a point, but may be a mark such as a square or a triangle. When analyzing using the display D, a mark image may be formed on the fundus Er using infrared light instead of forming a bright spot image on the fundus Er using visible light.

In addition, in the above embodiment, the pinhole plate 48.74 has four
Although four pinhole portions are provided, the number is not limited to this, and the number may be four or more, or may be three. In the case of three points, it is only necessary that the three points are not lined up in a straight line.

(Effects of the Invention) As explained above, according to the present invention, a mark projection optical system that projects at least three marks onto the fundus so that they are not on the same straight line is provided, and an objective lens and Since the mark projection optical system is provided at a conjugate position of the fundus between the photographing optical system and the photographic optical system, the mark projection optical system forms projection images of at least three marks so that they are not on the same straight line.
Marks indicating the common fixed points of both images can be photographed together with the fundus, eliminating the need to manually plot the common points of both images of the fundus, increasing the work efficiency of stereoscopic analysis. Can be done.

[Brief explanation of the drawing]

Fig. 1 is a side view showing the arrangement of the optical system of the stereoscopic fundus camera according to the present invention, Fig. 2 is its plan view, Fig. 3 is a plan view of the pinhole plate, and Fig. 4 is an explanatory diagram of the fundus image. , FIG. 5 is an explanatory diagram of a fundus image formed on a photographic film, FIG. 6 is an explanatory diagram of the second embodiment, FIG. 7 is an explanatory diagram of the third embodiment, and FIG.
9 and 9 are explanatory diagrams showing the configuration of a conventional stereoscopic fundus camera. 1... Objective lens 3... Stereo photography optical system (photography optical system) O... Illumination optical system 8... Pinhole plate 9... Hole mirror... Relay lens 5... Illumination light source 1... Half mirror 2... Relay lens 3... Pinhole plate 5... Light source Er... Fundus mark projection optical system Mark projection optical system 22〇-

Claims (2)

[Claims] (1) In a stereoscopic fundus camera comprising an illumination optical system that illuminates the fundus through an objective lens, and a photographic optical system that photographs the fundus through the objective lens, at least three marks are placed on the fundus. A stereoscopic fundus camera characterized by being provided with a mark projection optical system that projects marks so as not to be on the same straight line. (2) A stereoscopic fundus camera comprising an illumination optical system that illuminates the fundus through an objective lens, and a photographic optical system that photographs the fundus through the objective lens, wherein the objective lens and the photographic optical system A stereoscopic fundus camera characterized in that a mark projection optical system is provided for forming projected images of at least three marks at conjugate positions of the fundus between them so that they are not on the same straight line.