US20130335702A1

US20130335702A1 - Ophthalmic image sensing apparatus

Info

Publication number: US20130335702A1
Application number: US13/947,502
Authority: US
Inventors: Kazuhiro Matsumoto
Original assignee: Canon Inc
Current assignee: Canon Inc
Priority date: 2004-09-24
Filing date: 2013-07-22
Publication date: 2013-12-19
Also published as: US20080018854A1; US8506081B2; US20060077346A1; US7347553B2

Abstract

A focusing unit is constituted of a prism base, deflection prisms, and a slit chart having a slit opening, and the deflection prisms are arranged so that deflecting directions may become reverse. The slit opening is made equally to spread across the deflection prisms approximately and is impermeable except the slit opening, and light incident on the deflection prisms passes only this slit opening. In addition, the light which is emitted by a focus index illumination light source illuminates the slit opening through the deflection prisms. As to an image of the illuminated slit opening, two slit images are formed on a fundus of eye by actions of the deflection prisms. Focus adjustment is made by aligning these slit images in a straight line.

Description

This is a continuation of prior application Ser. No. 11/233/628, filed Sep. 22, 2005, which is hereby incorporated by reference in its entirety as if fully set forth herein.
This application claims priority from Japanese Patent Application Nos. 2004-276724 filed on Sep. 24, 2004 and 2004-300968 filed on Oct. 15, 2004, which are hereby incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention
The present invention relates to an ophthalmic image sensing apparatus used in an ophthalmologist's office etc.
2. Related Background Art
Up to now, in fundus cameras, what are disclosed in Japanese Patent Application Laid-open No. H05-095902, Japanese Patent Application Laid-Open No. H08-033610, and Japanese Patent Application Laid-Open No. H08-150121 are methods of providing a mechanism of providing a focus index projection barrel which, is constituted of an index for focusing detection, a light source illuminating this index, and a projection optical, system which has a deflection prism for projecting index images on a fundus of an eye to be examined from different locations of a pupil, and a micro mirror which branches an optical path with a fundus illumination optical system, and of both the micro mirror and focus index projection barrel moving in a direction of an optical axis with interlocking with the focus adjustment of an image sensing optical system, and a mechanism of the micro mirror retreats out of the optical path at the moment of image sensing, and of focusing the fundus of eye with looking at the index images projected on the fundus of eye.
In addition, methods of providing a minute prism in an illumination optical system, projecting a slit image illuminated by fundus observation light on the fundus of eye, and performing focus adjustment are disclosed in Japanese Patent Applicant Laid-Open No. H06-142050 and Japanese Patent Application Laid-Open No. S54-054494.
Since the above-mentioned conventional methods each must move a whole focus index projection barrel, which is provided with being branched from a fundus illumination optical system, in a direction of an optical axis, it is necessary to secure a large space, and hence, it is difficult to downside an apparatus. In addition, there are problems that cost is high because of necessity of long adjustment time due to a large parts count, and assembly operation, such as angle adjustment of a micro mirror, and alignment between an index image and a micro mirror, is complicated. Furthermore, there is another problem that a slack wire is worn because the light source where wires are connected is moved.
Moreover, the method of providing a minute prism in the above-mentioned illumination optical system has a problem that it is hard to perform focus adjustment since a focus index portion becomes darker than a surrounding fundus region because of decentering the fund illumination light by a prism and projecting a focus index, or it is user-unfriendly since it is not possible to adjust light intensity independently because fundus illumination and focus index illumination are performed by one light source.
In addition, in fundus image sensing in a mass health examination, an examinee's look is adjusted and image sensed so that a just middle position between an optic disk and a yellow spot may become a center of a screen. Hence, it is necessary to guide this yellow spot in a position, which is decentered from an optical axis, and to take a picture. Nevertheless, it is necessary to change a position of a fixation target at the time of taking a picture of a right eye and at the time of taking a picture of a left eye since the structure of fundi of the right and left eyes is left-right symmetric.
Hence, in fundus cameras, as disclosed in Japanese Patent Application Laid-Open No. S60-060831, Japanese Patent Application Laid-Open No. H06-217941, and Japanese Patent Application Laid-Open No. H09-271464, it has been performed up to now to present to a person to be examined a fixation target according to right and left eyes by providing an optical path which branches from an image sensing optical system, providing a plurality of light sources in conjugation positions with an image sensing plane in the optical path as fixation targets, and turning on the light sources selectively. Since image sensing light and a fixation target are visible light, a flip-up mirror, a half-mirror, or the like which branches an optical path is used.
In addition, what is also known, is a method of Japanese Patent Application Laid-Open No. S51-137413 of arranging detachably a light source in an illumination optical system, and presenting a fixation target.
However, in the above-described conventional methods, there are problems that an optical system becomes large because of providing a branch optical path, and that a mechanism becomes complicated in the case of using a flip-up mirror, or a light source with a larger volume is needed since a utilization efficiency of light intensity falls in the case of using a half-mirror, and further, the dazzle of a person to be examined increases.
Furthermore, the method of arranging a light source as a fixation target in an illumination optical system has a problem that the image quality of a fundus observation image deteriorates since illumination unevenness arises because fundus illumination light is disturbed by parts for supporting the light source, the light source itself, a cable, and the like.

SUMMARY OF THE INVENTION

The present invention aims at solving the above-described subjects, and providing an ophthalmic image sensing apparatus which makes it possible to obtain a fundus image with good image quality without illumination unevenness.
An ophthalmic image sensing apparatus according to one aspect of the present invention for attaining the above-mentioned object has the following structure.
Namely, the ophthalmic image sensing apparatus has:
a fundus image sensing optical system for sensing an image of a fundus of eye to be examined;
focus adjustment means of adjusting a focus of the above-mentioned fundus image sensing optical system;
an illumination optical system for illuminating the above-mentioned eye to be examined;
a perforated mirror which branches an optical path into an optical path of the fundus image sensing optical system, and an optical path of the above-mentioned illumination optical system;
first and second relay lenses having focal points near an opening of the above-mentioned perforated mirror;
a slit index of being arranged between the first and second relay lenses, and its image being projected on the above-mentioned fundus of eye;
a deflection prism arranged around the slit index;
a focusing unit movable in a direction of an optical axis with interlocking with the above-mentioned focus adjustment means;
a light shielding member arranged in an approximately focal position of the above-mentioned second relay lens; and
illumination means of illuminating the above-mentioned slit index.
Other features and advantages of the present invention will be apparent from the following description taken in conjunction with the accompanying drawings, in which like reference characters designate the same or similar parts throughout the figures thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with:

FIG. 1 is a structural diagram of a fundus camera of a first embodiment;

FIG. 2 is a front elevation of a crystalline lens diaphragm;

FIG. 3 is a front elevation of a ring diaphragm;

FIG. 4 is an explanatory drawing of arrangement of an observation light source and a focus index illumination light source;

FIG. 5 is a sectional view of a focusing unit;

FIG. 6 is a plan view of the focusing unit;

FIG. 7 is a rear view of the focusing unit;

FIG. 8 is an explanatory drawing of an incidence position of an optical slit image on a pupil;

FIGS. 9A, 9B and 9C are explanatory drawings of states that a slit image separates;

FIG. 10 is a structural diagram of the fundus camera of the first embodiment;

FIG. 11 is a layout drawing of an opening of a ring diaphragm, and LED light sources;

FIG. 12 is a layout drawing of an opening of a ring diaphragm, and visible light sources;

FIG. 13 is a plan of minute openings of an infrared filter;

FIG. 14 is a sectional view of the minute openings of the infrared filter;

FIG. 15 is an explanatory drawing of luminous flux which passes through a minute opening;

FIG. 16 is a structural diagram of a fixation target unit of a second embodiment;

FIG. 17 is a plan of minute openings of an infrared filter;

FIG. 18 is an explanatory drawing of luminous flux which passes through the minute openings;

FIG. 19 is a layout drawing of an opening of a ring diaphragm, and light sources of a third embodiment;

FIG. 20 is a structural diagram of a fixation target unit; and

FIG. 21 is an explanatory drawing of luminous flux which passes through a minute opening.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
The present invention will be described in detail on the basis of embodiments shown.

First Embodiment

FIG. 1 is a structural diagram of a fundus camera of this embodiment. Fundus examination and sensing means has the structure that an image sensing mechanism comprising an objective lens 1, a perforated mirror 2, an image sensing diaphragm 3 arranged inside an opening of this perforated mirror 2, a focus lens 4, an image sensing lens 5, a color separation prism 6, and image sensing devices 7 r, 7 g and 7 b is arranged in front of an eye E to be examined.
What are arranged in the fundus illumination system located in an incident direction of the perforated mirror 2 are in view of the perforated mirror 2 a cornea diaphragm 8 having a ring-like opening projected near a cornea, a first relay lens 9, a black spot plate 10 on which black spots for removing reflection by the objective lens 1 are formed near an optical axis, a focusing unit 11 which has a prism and a focus index, moves in a direction of the optical axis with interlocking with the focus lens 4, and retreats out of an optical path at the time of still image sensing, a second relay lens 12, an optical path branching mirror 13 which reflects visible light and transmits infrared light, a crystalline lens diaphragm 14 which has a ring-like opening 14 a projected near a rear surface of a crystalline lens of an eye to be examined, has a small opening 14 b in a center portion, and is shown in FIG. 2, a ring diaphragm 15 which has a ring-like opening 15 a projected near a pupil Ep of the eye E to be examined, and id shown in FIG. 3, a plurality of observation light sources 16 a to 16 f which consist of LEDs, which emit infrared light, and are arranged circumferentially as shown in FIG. 4, and a focus index illumination light source 17 arranged in a central portion.
A crystalline lens diaphragm 18 having a ring-like opening projected near the rear surface of a crystalline lens of an eye to be examined, a ring diaphragm 19 having a ring-like opening projected near the pupil of the eye E to be examined, and a sensing light source 20 are arranged in a reflecting direction of the optical path branching mirror 13.
The image sensing diaphragm 3 in the opening of the perforated mirror 2 is located in an approximately focal position of the first relay lens 9. In addition, the diaphragm 15 and diaphragm 19 are arranged in an approximately focal position of the second relay lens 12. Furthermore, the ring-like opening 15 a of the ring diaphragm 15 is illuminated by the illumination light sources 16 a to 16 f. The small opening 15 b is illuminated by the index illumination light source 17.
The focusing unit 11 is constituted of a prism base 11 a, deflection prisms 11 b and 11 c, and a slit chart 11 e having a slit opening 11 d, as shown in a sectional view of FIG. 5. As shown in FIG. 6, the deflection prisms 11 b and 11 c are arranged in a central portion of the prism base 11 a so that deflecting directions may become reverse directions. In addition, the slit chart 11 e is arranged in a central portion of the prism base 11 a, and the slit opening 11 d is arranged so as to spread across the deflection prisms 11 b and 11 c approximately equally, as shown in FIG. 7. Since portions except the slit opening 11 d of the slit chart 11 e are impermeable, light incident into prism portions passes only this slit opening 11 d.
Each output of the image sensing elements 7 r, 7 g, and 7 b is connected to an image board 22 through amplifying circuits 21 r, 21 g, and 21 b. The image board 22 has an A/D converter 23 and memory 24. Further, an output of the image board 22 is connected to image control means 25, a television monitor 27, and a system bus 26. What are connected to the system bus 26 are a CPU 28, a sensing switch 29, recording means 30, a focus switch 31, an observation light intensity adjustment knob 32, a focus index brightness adjustment switch 33, and a drive circuit 34 of the sensing light source 20.
In order to sense a fundus image of a person to be examined using this fundus camera, a camera person sits the person to be examined in front of the fundus camera, and performs the alignment of an eye E to be examined and the fundus camera, and focusing, with observing moving images of a fundus Er of the eye E to be examined.
In the focusing, infrared light emitted by the observation light sources 16 a to 16 f passes through the ring-like opening 15 a of the ring diaphragm 15, and the ring-like opening 14 a of the crystalline lens diaphragm 14, and permeates the optical path branching mirror 13. Further, the infrared light passes through the second relay lens 12, focusing unit 11, black spot plate 10, first relay lens 9, and opening of the cornea diaphragm 8, and is reflected toward the left by the perforated mirror 2 to illuminate the fundus Er of eye through the pupil Ep of the eye E to be examined through the objective lens 1. An image of the fundus Er of eye illuminated in this way passes through the objective lens 1, image sensing diaphragm 3, focus lens 4, and image pickup lens 5 again, and is guided by the color separation prism 7 to the image sensing element 7 r which receives red and infrared light.
A signal of the image sensing element 7 r is converted into a video signal by the amplifying circuit 21 r, and is inputted into the image board 22 further to be displayed on the television monitor 27 through the image control means 25. A camera person observes the fundus image displayed on this television monitor 27 to perform the check of a sensed portion, and the like. When the brightness of this fundus image is not suitable, the camera person operates the observation light intensity adjustment knob 32. Since the amount of a current which flows into the observation light sources 16 a to 16 f is adjusted according to the operation of this knob 32 and luminescence intensity changes, the camera person can observe the fundus image in suitable brightness.
In addition, light emitted by the focus index illumination light source 17 passes through the small opening 15 b of the ring diaphragm 15, and the small opening 14 b of the crystalline lens diaphragm 14, and permeates the optical path branching mirror 13 to illuminate the slit opening 15 d through the deflection prisms 11 b and 11 c of the focusing unit 11 through the second relay lens 12. An image of the slit opening 11 d which is illuminated in this way passes through the black spot plate 10, first relay lens 9, and an opening portion of the cornea diaphragm 8 by an action of the deflection prisms 11 b and 11 c, and is reflected toward the left by a peripheral mirror portion of the perforated mirror 2 to be projected on the fundus Er of the eye E to be examined through the objective lens 1.
Since the swell opening 15 b of the ring diaphragm 15 and the perforated mirror 2 are made approximately conjugated with the pupil Ep, all the light outgoing from the small opening 15 b is never reflected by the peripheral mirror portion since incident on the opening of the perforated mirror 2 unless the deflection prisms 11 b and 11 c act. However, the image of the small opening 15 b is formed in positions decentered from the optical axis, i.e., an opening position of the perforated mirror 2, as two slit images because of the existence of the deflection prisms 11 b and 11 c.
In addition, since a right half and a left half of the slit image are deflected in different directions respectively, the image in the small opening 15 b is formed in two symmetrical places which sandwich the opening of the perforated mirror 2. Because of this, as shown in FIG. 8, left and right slit images are projected on the fundus Er of eye from the two positions with up-and-down symmetry which sandwich the optical axis on the pupil Ep.
Because of this, as shown in FIGS. 9A and 9B, when the projected positions of the slit images S1 and S2 axe shifted from the fundus Er of eye, the slit images S1 and S2 are projected with being separated up and down from each other. In addition, as shown in FIG. 9C, when coinciding with the fundus Er of eye, the slit images S1 and S2 are aligned in a line.
As mentioned above, since the small opening 15 b is arranged in the focal position of the second relay lens 12, the light outgoing from the second relay lens 12 is approximately parallel light. Hence, even if the focusing unit 11 moves on the optical axis, a deflected angle is always constant and eccentricity on the pupil Ep is also always constant, and hence, focus precision is not spoiled.
The slit images S1 and S2 which are projected on this fundus Er of eye pass through the pupil Ep, objective lens 1, image sensing diaphragm 3, and focus lens 5 again, and enter into the color separation prism 7 to be guided into the image sensing element 7 r. This signal is converted into a video signal by the amplifying circuit 21 r, and is inputted into the image board 22 to be displayed on the television monitor 27 with a fundus image. The camera person can perform focus adjustment by operating the focus switch 31 so that these two slit images may be aligned in a straight line.
At this time, when the brightness of a focus index image is not suitable, the brightness adjustment switch 33 of the slit images S1 and S2 is operated. Thereby, since a current flowing in the index illumination light source 17 is adjusted and emitted energy changes, the brightness of the slit images S1 and S2 can be adjusted. Thus, since the observation light sources 16 a to 16 f and the focus index illumination light source 17 are provided separately, it is possible adequately to adjust also the brightness of the focus index with keeping the brightness of the fundus image suitably. Hence, it is possible to observe always the index image with suitable contrast.
As mentioned above, since the ring diaphragm 15 and the perforated mirror 2 are conjugated approximately, the small opening 15 b which is opened on the optical axis of the ring diaphragm 15 is imaged in an opening portion of the perforated mirror 2. That is, the other light than the light which is deflected through the deflection prisms 11 b and 11 c among the light which outgoes from the index illumination light source 17 and passes through the opening 15 b enters into the opening of the perforated mirror 2 and is not reflected in a direction of the objective lens 1. Hence, it does not become ghost light.
If a camera person operates the focus switch 31 as mentioned above so that the slit images S1 and S2 may become in a straight line, the focus lens 4 and focusing unit 11 move in a direction of the optical axis respectively. Then, as shown in FIG. 9C, the slit images S1 and S2 are projected in conjugation on the fundus Er of eye. So long as the left and right slit images S1 and S2 are sensed at the time of being in a straight line, a focused image is obtained since the focus lens 4 is adjusted so that the image sensing elements 7 b, 7 g, and 7 r may keep always conjugation with a focus index projection plane.
Thus, when a camera person operates the sensing switch 29 after image sensing preparation is completed, the CPU 28 detecting this input turns off the observation light sources 16 a to 16 f and the index illumination light source 17, retreats the focusing unit 11 out of the optical path, sets the amplifying circuits 21 r, 21 g, and 21 b as amplification factors for still image sensing, and turns on the sensing light source 20 with starting the accumulation of the image sensing elements 7 b, 7 g, and 7 r.
The light which is emitted by the sensing light source 20 passes an opening of the ring diaphragm 19, and an opening of the crystalline lens diaphragm 18, and is reflected upward by the optical path branching mirror 13. Then, the light passes through the second relay lens 12, black spot plate 10, first relay lens 9, and an opening portion of the cornea diaphragm 8, and is reflected toward the left in a mirror portion of the perforated mirror 2 to illuminate the fundus Er of eye through the objective lens 1 and pupil Ep.
The fundus image illuminated in this way passes through the pupil Ep, objective lens 1, image sensing diaphragm 3, focus lens 4, and image sensing lens 5 again, and is dispersed into three colors of blue (B), green (G), and red (R) by a spectrum prism 6. Then, three colors are imaged on the image sensing elements 7 b, 7 g, and 7 r respectively to be converted into electric signals, and are converted into digital data by the A/D converter 23 of the image board 22 to be displayed on the television monitor 27 and to be recorded on a recording medium D by the recording means 30. Then, the focusing unit 11 is again arranged in the optical path, the observation light sources 16 a to 16 f and index illumination light source 17 are turned on, and a series of image sensing operations are ended.

Second Embodiment

FIG. 10 is a structural diagram of a fundus camera in which the present invention is implemented. Fundus examination and sensing means has the structure that an image sensing mechanism comprising the objective lens 101, perforated mirror 102, image sensing diaphragm 103 arranged inside an opening of this perforated mirror 102, focus lens 104, image sensing lens 105, color separation prism 106, and image sensing devices 107 r, 107 g and 107 b is arranged in front of an eye E to be examined.
What are arranged in a fundus illumination system in an incident direction of the perforated mirror 102 are in view of the perforated mirror 102 the cornea diaphragm 108 having a ring-like opening projected near a cornea, first relay lens 109, black spot plate 110 on which black spots for removing reflection by the objective lens 101 are formed near an optical axis, fixation target unit 111 which moves in a direction of the optical axis with interlocking with the focus lens 104, and retreats out of an optical path at the time of still image sensing, second relay lens 112, optical path branching mirror 113 which reflects visible light and transmits infrared light, crystalline lens diaphragm 114 having a ring-like opening projected near a rear surface of a crystalline lens of an eye to be examined, ring diaphragm 115 having a ring-like opening 115 a projected near a pupil Ep of the eye E to be examined, and observation light sources 116 a to 116 f which emit infrared light and are arranged circumferentially along the ring-like opening 115 a as shown in FIG. 11.
What are arranged In a reflect lag direction of the optical path branching mirror 113 are a crystal line lens diaphragm 117 having a ring-like opening projected near the rear surface of the crystalline lens of the eye E to be examined, a ring diaphragm 118 having a ring-like opening 118 a projected near a pupil Ep of the eye E to be examined, and visible light sources 119 a to 119 f for image sensing, such as white LEDs, along an opening 118 a as shown in FIG. 12.
An optical system portion of the fixation target unit 111 arranged between the first and second relay lenses 109 and 112 is constituted of an infrared filter 111 a which transmits visible light and interrupts infrared light. Minute openings 111 b and 111 c are pierced in a central portion of the filter 111 a in positions, which are decentered left-right symmetrically, as shown in FIG. 13. These minute openings 111 b and 111 c incline in different directions respectively as shown in FIG. 14, and penetrate the filter 111 a.
An opening of the perforated mirror 102 is conjugated approximately about the objective lens 101 with an anterior segment of the eye E to be examined, and also focal positions of the first relay lens 109 and second relay lens 112 are approximately conjugated with the anterior segment of the eye E to be examined. Hence, the diaphragm 115 and diaphragm 118 are arranged in the approximately focal position of the second relay lens 112.
Each output of the image sensing elements 107 r, 107 g, and 107 b is connected to the image board 122 through the amplifying circuits 121 r, 121 g, and 121 b. The image board 122 has the A/D converter 123 and memory 124, and its output is connected to the image control moans 125, a television monitor 126, and a system bus 127. Furthermore, what are connected to the system bus 127 are the fixation target unit 111, CPU 128, sensing switch 129, recording means 130, a focusing switch 131, an observation light intensity dimmer knob 132, a selecting switch 133 which selects a fixation target presenting position according to the right and left of the eye E to be examined, and a lamp drive circuit 134 to drive the visible light sources 119 a to 119 f.
In order to sense an image of the fundus Er of eye to be examined using this fundus camera, a camera person sits a person to be examined in front of the fundus camera, and performs the alignment of the eye E to be examined and the fundus camera, and focusing, with observing moving images of the fundus Er of eye of the person to be examined.
The light which is emitted by the LED light sources 116 a to 116 f passes the ring-like opening 115 a of the diaphragm 115, and a ring-like opening of the diaphragm 114, and passes through the optical path branching mirror 113. Then, the light passes through the second relay lens 112, the fixation target unit 111, black spot plate 110, first relay lens 109, and an opening of a diaphragm 108, and is reflected toward the left by the perforated mirror 102 to illuminate the fundus Er of eye through the objective lens 101 and pupil Ep of the eye E to be examined.
A reflected image of the fundus Er of eye illuminated in this way passes through the objective lens 101, image sensing diaphragm 103, focus lens 104, and image sensing lens 105 again, and is guided by the color separation prism 106 to the image sensing element 107 r which receives red and infrared light. This signal is converted into a video signal by the amplifying circuit 121 r, and is inputted into the image board 122 further to be displayed on the television monitor 126 through the image control means 125.
A camera person observes the fundus image displayed on this television monitor 120 to perform the check of a sensed portion, and the like. When the brightness of this fundus image is not suitable, the camera person operates the observation light intensity dimmer knob 132. Since the amount of a current which flows into the LED light sources 116 a to 116 f is adjusted according to the operation of this knob 132 and luminescence intensity changes, the camera person can observe the fundus image in suitable brightness.
As shown in FIG. 12, only a light source 119 b among the visible light sources 119 a to 119 f for fixation target presentation arranged circumferentially along the opening 118 a of the diaphragm 118 is turned on in stationary light in luminance darker than that at the time of image sensing. Visible light emitted by the light source 119 b is reflected upward by the optical path branching mirror 113 through the opening 118 a of the diaphragm 118, and illuminates the fixation target unit 111 through the second relay lens 112.
Since the light source 119 b is arranged in an approximately focal plane of the second relay lens 112, as shown in FIG. 15, the light which is emitted by the light source 119 b becomes parallel light going toward the prism 111 a by the second relay lens 112, and all the light progresses with the same inclination. The opening 111 b of the filter 111 a has an inclination equal to an angle of this light, and the other opening 111 c has an inclination which coincides with an angle of the light which is emitted by the light source 119 e.
Hence, the light incident on the opening 111 b among the light being emitted by the light source 119 b permeates the opening 111 b, passes through the black spot plate 110, first relay lens 109, and an opening portion of the diaphragm 108, and is reflected toward the left by a peripheral mirror portion of the perforated mirror 102 to be projected on the fundus Er of eye through the pupil Ep. On the other hand, since the light incident on the opening 111 c is interrupted by the oblique opening, only an image of the opening 111 b is shown to the eye E to be examined as a fixation target for the person to be examined.
Similarly, when the light source 119 e turns on, the light which is emitted by the light source 119 e becomes parallel light oblique in a direction reverse to the light which is emitted by the light source 119 b, by the second relay lens 112 to illuminate the filter 111 a. Hence, luminous flux incident on the opening 111 c passes this opening 111 c, and passes the black spot plate 110, first relay lens 109, and an opening of the diaphragm 108 to reach the fundus Er of the eye E to be examined. But, luminous flux incident on the opening 111 b is interrupted by the oblique conning of this opening 111 b.
Thereby, a person to be examined can recognize only an image of the opening 111 c as a fixation target. That is, it is possible to switch a position of the fixation target by switching the light source 119 to turn on.
In addition, the fixation target unit 111 moves in a direction of the optical axis with interlocking with the focus lens 400 so that an image forming position of the opening 111 b or opening 111 c which is the fixation target may always coincide with an image sensing plane. Hence, when a camera person operates the focusing switch 131 with looking at the fundus image displayed on the television monitor 126 and focuses on the fundus Er of eye, it is possible to sense always an image of the fixation target with contrast good to the eye E to be examined.
A camera person observes the fundus image displayed on the television monitor 126, and operates the sensing switch 129 after confirming that a person to be examined gazes at the fixation target and image sensing coverage is suitable. The CPU 128 which detects an input into the sensing switch 129 turns off the light sources 116 a to 116 f, and once turns off the light source 119 b to retreat the fixation target unit 111 out of the optical path. While changing amplification factors of the amplifying circuits 121 b, 121 g, and 121 r for still image sensing and starting accumulation, the CPU 128 makes the sensing light sources 119 a to 119 f emit light for a short time in the luminance for image sensing.
The light which is emitted by the sensing light sources 119 a to 119 f passes an opening 118 a of the diaphragm 118, and an opening of the diaphragm 117, and is reflected upward by the optical path branching mirror 113. Then, the light passes through the second relay lens 112, black spot plate 110, first relay lens 109, and an opening portion of the diaphragm 108, and is reflected toward the left in a mirror portion of the perforated mirror 102 to illuminate the fundus Er of eye through the objective lens 101 and pupil Ep.
The fundus image illuminated in this way passes through the pupil Ep, objective lens 101, image sensing diaphragm 103, focus lens 104, and image sensing lens 105 again, and is dispersed into three colors of blue (B), green (G), and red (R) by the color separation prism 106 to be imaged on the image sensing elements 107 b, 107 g, and 107 r, respectively. Then, the images are converted into electric signals, and are amplified so as to become proper color balance by the amplifying circuits 121 b, 121 g, and 121 r to be converted into digital data by the A/D converter 123. While being displayed on the television monitor 126, the data is recorded on a recording medium D by the record means 130. Then, the fixation target unit 111 is again arranged in the optical path, the light sources 116 a to 116 f and light source 119 b are turned on, and a series of image sensing operations are ended.
Next, when sensing an image of another eye, the right and left eye selecting switch 133 is operated. Then, the CPU 128 which detects as input of the switch 133 turns on the light source 119 b or 119 e corresponding to a direction selected through the lamp drive circuit 134.
Similarly to the above, when the light source 119 b turns on, since the light which is emitted by the light source 119 b can pass only through the opening 111 b, it is possible to show the image of the opening 111 b as the fixation target to a person to be examined.
Although the fixation target presenting positions corresponding to right and left eyes are switched with the selecting switch 133 in the above-mentioned embodiment, the fixation target may be switched on the basis of detected information by detecting the right or left of the eye E to be examined using known detecting means.

Third Embodiment

In addition, although the example of using the openings 111 b and 111 c, which are slantly pierced in the infrared filter 111 a as the fixation targets in the fixation target unit 111 of the second embodiment, it is also good to arrange a prism, which deflects an optical path, near an opening used as a fixation target. FIGS. 16, 17 and 18 show the third embodiment in that case.
FIG. 16 is a structural diagram of the fixation target unit 111 which uses prisms, and an infrared filter 141 which transmits infrared light and interrupts visible light is sandwiched between transparent plates 140 a and 140 b. In this third embodiment, since oblique openings are never provided, a sheet-like low-cost filter is used as the infrared filter 141. In addition, as shown in FIG. 17, openings 141 a and 141 b are provided near a center of this infrared filter 141 as fixation targets. Prisms 142 a and 142 b are formed in portions of a transparent sheet 140 a which correspond to these openings 141 a and 141 b.
Thereby, as shown in FIG. 18, the light which is emitted by the light source 119 b becomes parallel light with the second relay lens 112 similarly to the second embodiment to illuminate the openings 141 a and 141 b of the infrared filter 141 through the transparent plate 140 b. The luminous flux incident on the opening 141 a is deflected at an angle reverse to the optical axis by the prism 142 a. This luminous flux passes the first relay lens 109 and the opening of the diaphragm 108 through the black spot plate 110, and proceeds to the peripheral mirror part of the perforated mirror 102. Further, the luminous flux reaches the fundus Er of the eye E to be examined, and the person to be examined can recognize an image of the opening 141 a as a fixation target.
On the other hand, the luminous flux incident on the opening 141 b is deflected in a direction having an angle larger to the optical axis by the prism 142 b. Therefore, this light never enters into the first relay lens 109 after passing through the black spot plate 110. Alternatively, since being interrupted by the diaphragm 108 even if being incident on the first relay lens 109, the light never reaches one fundus Er of eye of a person to be examined.
Thereby, the person to be examined can recognize only the opening 141 a as a fixation target. When the light source 119 e is turned on, on the contrary, the light incident on the opening 141 a is interrupted by being deflected out of the optical path by an action of the prism 142 a. The light incident on the opening 141 b is deflected in a direction symmetric to the optical axis by an action of the prism 142 b, and is projected on the eye E to be examined through the black spot plate 110, first relay lens 109, and the opening of the diaphragm 108.
Hence, when the light source 119 e is turned on, a person to be examined can recognize only the opening 141 b as a fixation target. Thus, it is possible to show a fixation target according to the right and left of the eye E to be examined by switching the lighting of the light sources 119 b and 119 e.

Fourth Embodiment

In addition, it is possible to provide a light source for fixation target illumination near a fund illumination light source, and FIGS. 19 and 20 show this fourth embodiment. FIG. 19 shows the arrangement of sensing light sources 119 g to 119 l on a circumference to the opening 118 a of the diaphragm 118. Two light sources 145 a and 145 b for fixation target illumination are on the same plane as the sensing light sources 119 g to 119 l, and are arranged nearer to the optical axis than the light sources 119 g to 119 l.
FIG. 19 is a structural diagram of the fixation target unit 111 of a fourth embodiment. The sheet-like infrared filter 141 in which the minute openings 141 a and 141 b are formed in symmetric positions near its center similarly to the previous embodiment is sandwiched between the transparent sheets 146 a and 146 b.
As shown in FIG. 20, the luminous flux which is emitted by the light source 145 a passes through the opening 115 a of the ring diaphragm 115, and becomes parallel light by the second relay lens 112 further through the opening of the crystalline lens diaphragm 114. The light which illuminates the opening 141 a of the infrared filter 141 of the fixation target unit 111 and passes through the opening 141 a passes through the transparent plate 143, black spot plate 110, first lens 109, and the opening of the diaphragm 108 to be projected on the fundus Er of the eye E to be examined.
However, since the light which should illuminate the opening 141 b is interrupted by a light shielding portion of the diaphragm 118 around the optical axis as shown by a short dashes line in FIG. 20 because the light source 145 a is arranged nearer to the optical axis than the light sources 119 g to 119 l, the opening 141 b is never illuminated. Hence, a person to be examined can recognize only an image of the opening 141 a as a fixation target.
Similarly, since the light which is emitted by the light source 145 b can illuminate the opening 141 b, but never illuminates the opening 141 a because of being interrupted by the light shielding portion of the diaphragm 118. Thus, it is possible to show a fixation target according to the right and left of the eye E to be examined by switching the lighting of the light sources 145 a and 145 b.
According to the above embodiment, since it is possible to show a fixation target according to a right or left eye just by selectively turning on a light source in an illumination optical system fixedly arranged. Hence, since it is not necessary to provide a branch optical path, it is possible to downside an optical system.
In addition, since it is also possible to use a light source, used for image sensing, for the illumination of a fixation target, it is possible to reduce a parts count and to simplify structure.
According to the above-mentioned invention, it is possible to provide an ophthalmic image sensing apparatus which makes it possible to obtain a fundus image with good image quality without illumination unevenness.
As many apparently widely different embodiments of the present invention can be made without departing from the spirit and scope thereof, it is to be understood that the invention is not limited to the specific embodiments thereof except as defined in the claims.

Claims

1-8. (canceled)

9. An ophthalmic image sensing apparatus comprising:

a plurality of visible light sources located in conjugation positions with an anterior segment of an eye to be examined; and

a projection unit for projecting a fixation target at a different position on a fundus of the eye to be examined, in accordance with one selected among the plurality of visible light sources.

10. The ophthalmic image sensing apparatus according to claim 9, further comprising a light source for emitting an infrared light to illuminate the fundus,

wherein the projection unit transmits the infrared light.

11. The ophthalmic image sensing apparatus according to claim 10, wherein the projection unit has as the fixation target, a plurality of openings slantly pierced in a direction different from an optical axis.

12. The ophthalmic image sensing apparatus according to claim 10, wherein the projection unit has an opening which transmits a visible light, and prisms each of which is located in accordance with the opening and deflects the visible light in a direction different from others.

13. The ophthalmic image sensing apparatus according to claim 10, wherein the plurality of visible light sources include a plurality of white LED light sources.

14. The ophthalmic image sensing apparatus according to claim 9, further comprising a first relay lens and a second relay lens each of which has a focal position conjugating with an anterior segment of the eye to be examined,

wherein the plurality of visible light sources are arranged circumferentially on a focal plane of the second relay lens, and

the projection unit is provided between the first relay lens and the second relay lens.

15. The ophthalmic image sensing apparatus according to claim 9, further comprising a selection unit for selecting one visible light source among the plurality of visible light sources,

wherein the projection unit projects the fixation target at the different position on the fundus by using the one visible light source selected by the selection unit.

16. The ophthalmic image sensing apparatus according to claim 15, wherein the selection unit selects the one visible light source among the plurality of visible light sources in accordance with the right and left of the eye to be examined.

17. The ophthalmic image sensing apparatus according to claim 15, further comprising a control unit for controlling the plurality of visible light sources so as to turn on the selected visible light source with luminance darker than that at a time of image sensing of the eye to be examined, to emit a stationary light.

18. The ophthalmic image sensing apparatus according to claim 15, further comprising a control unit for controlling the plurality of visible light sources so as to turn on the selected visible light source at a time of image sensing of the eye to be examined, with luminance brighter than that at a time of projecting the fixation target.

19. The ophthalmic image sensing apparatus according to claim 18, wherein the plurality of visible light sources and the projection unit are provided on an illumination optical system for illuminating the eye to be examined, and

the control unit causes, at the time of image sensing of the eye to be examined, once the selected visible light source is turned off, the projection unit to remove from an optical path of the illumination optical system, and the selected visible light source to turn on with luminance brighter than that at the time of projecting the fixation target.

20. The ophthalmic image sensing apparatus according to claim 9, wherein the plurality of visible light sources and the projection unit are provided on an illumination optical system for illuminating the eye to be examined,

the ophthalmic image sensing apparatus further comprising a control unit for causing the projection unit to remove from an optical path of the illumination optical system at a time of image sensing of the eye to be examined.

21. The ophthalmic image sensing apparatus according to claim 9, further comprising a right-left eye selection unit for selecting a right eye or a left eye as the eye to be examined,

wherein the projection unit projects the fixation target at the different position on the fundus in accordance with a selection result of the right-left eye selection unit.