JP2003290147A - Fundus camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fundus camera capable of removing a flare easily. <P>SOLUTION: This fundus camera comprises an illuminating optical system 1 having a flare-removing light shielding means 6 and a photographic optical system 10. The fundus camera is further provided with an auto-alignment mechanism for aligning a camera body equipped with the optical systems 1 and 10 automatically with the eye E to be examined, an arithmetic control circuit 20 for controlling the movement of the auto-alignment mechanism, TV cameras 16 and 19 for detecting the flare entering into the photographic optical system 10, and a Z alignment detecting means for detecting the alignment state by the auto-alignment mechanism in the optical axis direction of the eye to be examined. The light shielding means 6 is arranged so that its movement can be adjusted in the optical axis direction of the illuminating optical system 1 by driving motors M1 and M2. The arithmetic control circuit 20 detects the completion of the alignment by the auto-alignment mechanism based on the detection signal from the Z alignment detecting means. When the TV cameras 16 and 19 detect the flare concurrently with the completion of the alignment, the arithmetic control circuit 20 moves the light shielding means 6 finely by a predetermined amount in the optical axis direction of the illuminating optical system 1 by controlling the movement of the driving motors M1 and M2. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fundus camera provided with a light shielding means for removing flare (harmful light) from the anterior segment of an eye to be examined.

[0002]

2. Description of the Related Art Conventional fundus cameras include, for example, Japanese Patent Publication Sho 6
No. 1-5729, the illumination light is projected from the illumination optical system to the subject's eye to illuminate the fundus, and the reflected light from the fundus is guided to the photographing means by the photographing optical system and the fundus image is photographed by the photographing means. In addition, in order to prevent flare from the cornea of the eye to be inspected, the crystalline lens or the like from entering the photographing optical system, there is a system in which a light shielding plate conjugate with the cornea and the rear surface of the crystalline lens is provided in the illumination optical system. Some of these fundus cameras are provided with an optical finder for observing the subject's eye, and some are provided with a monitor for observing the subject's eye.

Before photographing a fundus with such a fundus camera, it is necessary to align the fundus camera with the eye to be examined. This alignment is performed by the photographer manually operating the device main body having the optical system of the fundus camera built therein using a joystick. Then, when the alignment is completed, the photographer confirms whether or not there is flare while observing the eye to be inspected using the optical finder or the monitor. If there is flare, the operator manually operates the device body of the fundus camera using a joystick to move the flare to an optimal position where the flare cannot be removed any more, and shoots. Was there.

[0004]

By the way, in the subject's eye imaged by such a fundus camera, the distance between the cornea and the posterior surface of the crystalline lens differs because the thickness of the cornea and the crystalline lens differs depending on the person. Moreover, in this fundus camera, the flare cannot be completely removed because the light shielding plate is fixed. Furthermore, recently, IOL (intrao) used for cataract surgery etc.
Due to the widespread use of a cular lens, the number of eyes to be inspected with an IOL has also increased, and since the shape and refractive index of the crystalline lens are different from those of the original crystalline lens, it tends to increase even when it is difficult to remove flare at the conventional diaphragm position.

Moreover, since the flare removing work is manually performed by the photographer, the work efficiency is poor.

Therefore, an object of the present invention is to provide a fundus camera which can easily perform a flare removing operation.

[0007]

In order to achieve this object, the invention of claim 1 uses the light-shielding means for flare removal which is conjugated with at least one of the cornea, the iris, and the posterior surface of the crystalline lens of the eye to be examined. With an illumination optical system that illuminates the fundus of the optometry, and an imaging optical system that images the subject's eye,
In an eye fundus camera including an auto-alignment mechanism that automatically aligns a device body including the optical system with respect to the eye to be inspected, a flare that detects flare incident on the photographing optical system in a fundus camera. Detection means is provided, Z alignment detection means for detecting the alignment state in the optical axis direction of the eye to be inspected by the auto alignment mechanism is provided, and drive means for driving the light shielding means in the optical axis direction of the illumination optical system is provided. At the same time, the control circuit detects that the alignment by the automatic alignment mechanism is completed by the detection signal from the Z alignment detecting means, and at the same time, when the flare detecting means detects flare, operates the driving means. Control the shading means by a preset amount Characterized in that only the said illumination optical system of the fundus camera that is set so as to be finely moved in the optical axis direction.

According to a second aspect of the present invention, in the fundus camera according to the first aspect, the control circuit detects that the alignment by the automatic alignment mechanism has been completed by a detection signal from the Z alignment detecting means. At the same time, when the flare detecting means detects flare, the driving means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a predetermined amount set by the flare detecting means. The flare detection state is determined, and when it is determined that the flare detection unit has not detected further flare based on this determination, the imaging optical system is set to capture an image of the eye to be inspected.

Further, the invention of claim 3 is the fundus camera according to claim 2, wherein the control circuit detects completion of alignment by the automatic alignment mechanism by a detection signal from the Z alignment detecting means. At the same time, when the flare detecting means detects flare, the driving means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a predetermined amount set by the flare detecting means. When the flare detection state is judged, and when it is judged that the flare detection means is further detecting flare based on this judgment, the drive means is operated and controlled so that the light shielding means is within the predetermined range set in advance. Automatically search the flare detection state by the flare detection means while moving in the optical axis direction of the system,
After sequentially storing the flare light amounts at a plurality of moving positions in the memory, the light shielding unit is moved by the driving unit in the optical axis direction of the illumination optical system to a position where the flare light amount stored in the memory is small, It is characterized in that the photographing optical system is set so as to photograph the eye to be inspected.

According to a fourth aspect of the present invention, in the fundus camera according to the second aspect, the control circuit detects that the alignment by the auto-alignment mechanism is completed by a detection signal from the Z alignment detecting means. At the same time, when the flare detecting means detects flare, the driving means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a predetermined amount set by the flare detecting means. When the flare detection state is judged, and when it is judged that the flare detection means is further detecting flare based on this judgment, the drive means is operated and controlled so that the light shielding means is within the predetermined range set in advance. Automatically search the flare detection state by the flare detection means while moving in the optical axis direction of the system,
After sequentially storing the flare light amounts of a plurality of movement positions in the memory, when the minimum flare light amount stored in the memory is equal to or larger than a predetermined value, the photographing of the eye to be examined by the photographing optical system is stopped, and the manual photographing mode is set. It is characterized in that it is set to be switched.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. [Configuration] In FIG. 1A, the fundus camera includes an illumination optical system 1 that illuminates an eye E to be inspected, a photographing optical system 10 that photographs the illuminated eye E to be inspected, and an automatic alignment optical system 30. The illumination optical system 1, the photographing optical system 10 and the automatic alignment optical system 30 are built in the apparatus main body (not shown). The main body of the apparatus is driven in the front-rear, left-right, and up-down directions via an auto-alignment mechanism (three-dimensional drive mechanism) (not shown). The three-dimensional drive mechanism can adopt a well-known configuration as disclosed in, for example, Japanese Patent Laid-Open No. 11-32993, and thus detailed description thereof will be omitted. <Illumination Optical System 1> The illumination optical system 1 has an observation illumination optical system and a photographing illumination optical system. (Observation illumination optical system) The observation illumination optical system includes an observation infrared light source 2, a condenser lens 3, a first relay lens 5,
Light blocking means 6, second relay lens 7, perforated mirror 8,
The objective lens 9 is provided in this order. This observation infrared light source 2
For this, an infrared light source in which a tungsten lamp and an infrared filter or a near infrared filter are combined can also be used.

The light shielding means 6 has ring slit plates having the ring slits Rs as shown in FIG. 1B as light shielding plates (light shields) 6a, 6b, 6c. In addition, in the light shielding plates 6a to 6c, a ring slit Rs is formed between the inner light shielding portion Ra and the outer ring-shaped light shielding portion Rb, and the light shielding portions Ra, Rb and the ring slit Rs are included in the illumination optical system 1. It is formed concentrically with the optical axis O and serves as a concentric light shielding means.

The light-shielding plates 6a and 6c are arranged at positions which are substantially conjugated to the standard human cornea and the posterior surface of the crystalline lens when the light-shielding plate 6b is conjugated to the iris. Also,
The light-shielding plates 6a and 6c are provided so as to be movable in the direction of the optical axis O of the observation illumination optical system 1, and differ in the thickness of the cornea or the crystalline lens that differs depending on the person, or the distance between the cornea and the posterior surface of the crystalline lens. Even if there is a difference, it can be adjusted to be conjugate with the cornea, iris, and posterior surface of the lens.

This adjustment can be performed manually, or
It can also be performed by a drive motor (electrically driven means). In this embodiment, the light shielding plates 6a, 6b and 6c are provided so as to be movable in the direction of the optical axis O of the observation illumination optical system 1 by drive motors M1 and M2 such as pulse motors.

The light-shielding plates 6a and 6c do not have to be ring slit plates and may be replaced with light-shielding plates having only the inner light-shielding portion Ra. (Illumination optical system for photography) The illumination optical system for photography has a light source for photography 4, a first relay lens 5, a light shielding means 6, a second relay lens 7, a perforated mirror 8, and an objective lens 9 in this order. As the photographing light source 4, a visible light source such as a xenon lamp is used for photographing with visible light. <Photographing optical system 10> The photographing optical system 10 includes a photographing optical system 11
a and an observation optical system 11b.

The photographing optical system 11a includes an objective lens 9, a central aperture 8a of a perforated mirror 8, an imaging lens 12, a quick return mirror 13, a roof prism 14, a field lens 14a, a first photographing lens 15, and color photographing. It has a TV camera (imaging device, color TV camera) 16 for use as flare detecting means.

The observation optical system 11b includes an objective lens 9, a central aperture 8a of a perforated mirror 8, and an imaging lens 1.
2, quick return mirror 13, field lens 1
7a, mirror 17, second photographing lens 18, observation TV
It has a camera (imaging device) 19. Observation TV camera 1
In order to perform infrared observation, an infrared TV camera having sensitivity to infrared or near infrared is used. <Alignment Optical System 30> The alignment optical system (alignment detecting means) 30 is the XY shown in FIG.
It has an alignment optical system (XY alignment detecting means) and a Z alignment optical system (Z alignment detecting means) shown in FIG. This XY alignment optical system
It is used to detect the up / down / left / right alignment state of the apparatus main body (not shown) with respect to the eye E, that is, the up / down / left / right alignment state of the observation and photographing optical system with respect to the eye E. Further, the Z alignment optical system is used to detect the working distance of the apparatus body with respect to the eye E, that is, the distance between the objective lens 9 of the observation and photographing optical system and the eye E (the distance in the optical axis direction of the eye to be inspected). .

The XY alignment optical system has an alignment light projection system 31 and an alignment light receiving system 32, as shown in FIG. This alignment light projection system 3
1 is a light source 33 for alignment, a pinhole plate 34,
It has a projection lens 35, a half mirror 36, and an objective lens 9. The alignment light receiving system has an objective lens 9, an image forming lens 12, a half mirror 37, a relay lens 38, and a two-dimensional light receiving element 39 such as an area CCD.

The Z alignment optical system 32 has a measuring light projection system 40 and a measuring light receiving system 41 as shown in FIG. The measurement light projection system 40 includes a light source 42 for Z alignment, a slit plate 43 that converts the measurement light from the light source 42 into a slit light flux, and a lens 44 that projects the measurement light onto the cornea C of the eye E to be inspected. Further, the measurement light receiving optical system 42
Is a lens 45 on which the measurement light beam reflected from the cornea C is incident.
And the light receiving element 4 on which the measurement light beam from the lens 45 is imaged
Have six. A line sensor is used for the light receiving element 46.

For such an alignment optical system 30, a well-known configuration as disclosed in, for example, Japanese Patent Laid-Open No. 11-32993 can be adopted. <Control Circuit> The video signals from the TV cameras 16 and 19 described above are input to the arithmetic control circuit (control circuit) 20 shown in FIG. This arithmetic control circuit (arithmetic control means) 20
Inputs the video signals from the TV cameras (flare detecting means) 16 and 19 to the display device 21 such as a color CRT or a liquid crystal color monitor to display an eye image to be inspected.

Further, the arithmetic control circuit 20 includes a switch 2
The ON / OFF signals from 2, 23, 24, and 25 are input, and the ON signal of the photographing switch 26 is input. Further, the arithmetic and control circuit 20 is configured such that when the photographing switch 26 is turned on, the solenoid S inserts the quick return mirror 13 between the imaging lens 12 and the field lens 14a of the photographing optical system 11a. .

Further, the arithmetic control circuit 20 includes a light receiving element 3
Detection signals from 9 and 40 are input. Further, the arithmetic control circuit 20 is connected to a memory M for storing an image and an amount of light and an information recording / reproducing means R, and a mode changeover switch MS. The mode changeover switch MS is a switch for changing over the control mode of the light shielding means 6 after the automatic alignment by the arithmetic control circuit 20. This control mode includes an auto mode and a manual mode. Then, in the auto mode, the arithmetic control circuit 20 automatically controls the operation of the drive motors M1 and M2 of the light-shielding means 6 after the alignment is completed, following the alignment.
Further, in the manual mode, the arithmetic control circuit 20 can manually operate the drive motors M1 and M2 of the light shielding means 6 by manually operating the switches 22 to 25 after the alignment is completed. . still,
The arithmetic control circuit 20 is normally set to perform the movement control of the light shielding means 6 after the automatic alignment in the automatic mode. [Operation] Next, the operation of the fundus camera having such a configuration will be described. [A] Auto-alignment (1) Infrared observation In such a configuration, the quick return mirror 13 is usually inserted between the imaging lens 12 and the field lens 14a of the observation optical system 11a as shown by the solid line. . When the power of the fundus camera (not shown) is turned on in this state, the observation infrared illumination light source 2 is turned on by the arithmetic control circuit 20.

The infrared light emitted from the infrared light source for observation 2 by this lighting is condensed lens 3, first relay lens 5, light-shielding means 6, second relay lens 7, perforated mirror 8 and objective lens 9. Is projected onto the anterior ocular segment of the subject's eye E via the to illuminate the fundus Ef of the subject's eye E.

At this time, the observation infrared light source 2 includes the condenser lens 3, the first relay lens 5, the light shielding means 6, and the photographing light from the photographing light source 4 is the first relay lens 5, the light shielding means 6, After the image is formed on the perforated mirror 8 via the second relay lens 7, the image is formed on the iris of the eye E via the objective lens 9.

On the other hand, the reflected light reflected by the eye E to be examined E is the objective lens 9, the central aperture 8a of the perforated mirror 8, the imaging lens 12, the quick return mirror 13, and the roof prism 1.
4, quick return mirror 13, field lens 1
The image of the eye E to be inspected is formed on the observation TV camera 19 by being projected onto the observation TV camera 19 via the second photographing lens 18. At this time, by moving the imaging lens 12, it is possible to move the fundus conjugate position to correspond to the diopter of the subject's eye.

Then, the video signal from the observation TV camera 19 is input to the arithmetic control circuit 20. The arithmetic control circuit 20 transfers the input video signal to the display device 21 and causes the display device 21 to display the anterior segment image of the eye E in black and white in real time. (2) Alignment detection state In this state, the arithmetic control circuit 20 turns on the light source 33 for XY alignment, and the alignment light flux from the light source 33 is pinhole 34, lens 35, half mirror 36.
And, it projects on the cornea C of the eye E through the objective lens 9. The reflected light from the cornea C is the objective lens 9 and the aperture 8.
A two-dimensional light receiving element 39 is imaged as a bright spot image via a, the imaging lens 12, the half mirror 37, and the lens 38. Since this bright spot image may be obtained by a conventionally known method of projecting and receiving alignment light, detailed description thereof will be omitted.

The detection signal from the two-dimensional light receiving element 39 is input to the arithmetic control circuit 20. The arithmetic control circuit 20 is configured to display the bright spot image on the anterior segment image displayed on the display device 21 based on the detection signal from the two-dimensional light receiving element 39.

Further, the arithmetic control circuit 20 determines the position of the bright spot image based on the detection signal from the two-dimensional light receiving element 39 so that the bright spot image is centered on the optical axis of the eye E (optical axis of the eye E). It is determined whether or not it is within the range (the range which is the automatic alignment possible range) and whether it is within the photographing possible range narrower than the automatic alignment possible range.

On the other hand, the arithmetic control circuit 20 turns on the light source 40 for Z alignment, makes the alignment light from the light source 40 into a slit light flux by the slit plate 43, and projects this slit light flux onto the cornea C via the lens 44. Let This slit light flux is reflected by the cornea C and imaged on the light receiving element 46 via the lens 45.

The detection signal from the light receiving element 46 is input to the arithmetic control circuit 20. This arithmetic control circuit 2
0 is an alignment state of the apparatus body (not shown) in the optical axis direction (optical axis direction of the eye to be inspected) with respect to the eye E based on the detection signal from the light receiving element, that is, a working distance of the objective lens 9 to the eye E to be inspected. It is determined whether or not is within the shooting range. (3) Alignment operation In this state, the examiner operates a joystick (not shown) to move the apparatus body (not shown) to the eye E to the left, right, up and down. At this time, the arithmetic control circuit 20
When it is determined that the bright spot image is within a predetermined range in which auto-alignment can be performed with respect to the optical axis of the eye E based on the detection signal from the light receiving element 39, the auto-alignment mechanism (three-dimensional drive device) is activated. Control to further X-
The movement control is performed in the Y direction (left and right / up and down directions), and the movement control is further performed so that the bright spot image approaches the optical axis of the eye E to be examined.

Then, the arithmetic control circuit 20 includes the light receiving element 3
When it is determined that the bright spot image is within the photographable range in the XY direction (left / right / up / down direction) based on the detection signal from 9, it is determined that the alignment in the XY direction is completed,
The auto alignment mechanism (three-dimensional driving device) is operated and controlled to drive the device main body in the optical axis direction of the eye E to be inspected. Further, when the arithmetic control circuit 20 determines that the working distance of the apparatus main body (not shown) with respect to the subject's eye E is within the photographic range based on the detection signal of the light receiving element 46, it is determined that the alignment in the Z direction is completed. , The driving of the apparatus main body (not shown) by the automatic alignment mechanism (three-dimensional driving apparatus) is stopped. [B] Control of Light-shielding Means in Auto Mode for Infrared Observation of Non-mydriatic Eyes and Visible Imaging Normally, the control circuit 20 is set to perform movement control of the light-shielding means 6 after auto-alignment in auto mode. ing. Therefore, when the alignment in the Z direction is completed, the arithmetic control circuit 20 operates the solenoid S to move the quick return mirror 13 out from between the imaging lens 12 and the field lens 14a of the observation optical system 11a, and at the same time, for observation. The light source 2 is turned off and the photographing light source 4 is turned on.

In this lighting state, the visible light (visible photographing light) emitted from the photographing light source 4 passes through the first relay lens 5, the light shielding means 6, the second relay lens 7, the perforated mirror 8 and the objective lens 9. The light is projected onto the fundus (fundus of the eye to be examined) Ef of the eye to be examined E to illuminate the fundus Ef.

On the other hand, the reflected light reflected by the fundus Ef is the objective lens 9, the central aperture 8a of the perforated mirror 8, the imaging lens 12, the quick return mirror 13, and the roof prism 1.
4, the field lens 14a, and the first shooting lens 15 are projected onto the shooting TV camera 16 to display the shooting TV.
An image (fundus image) of the fundus Ef of the eye E is formed on the camera 16.

The video signal from the photographing TV camera 16 is input to the arithmetic control circuit 20. Then, the arithmetic control circuit 20 transfers the input video signal to the display device 21, and causes the display device 21 to display the fundus image of the eye E to be color-displayed. <When flare does not exist at the time of completion of alignment> At this time, the arithmetic control circuit 20 determines whether or not the fundus image of the eye E to be inspected has flare based on the video signal from the photographing TV camera 16. This determination is made based on whether or not there is a light amount equal to or more than a predetermined value in the peripheral portion of the fundus image from this video signal.

When the arithmetic control circuit 20 determines that there is no flare or almost no flare (within the allowable range), the arithmetic control circuit 20 stores the fundus image in the memory M. <When flare is present when alignment is completed> On the other hand, when the arithmetic control circuit 20 determines that flare is present, the arithmetic control circuit 20 controls the drive motors M1 and M2 to operate the light shielding plates 6a and 6c.
Are moved in the optical axis direction by a specified amount (a predetermined amount, that is, a small amount). At this time, the movement directions of the light shielding plates 6a and 6c are set in a preset direction, for example, directions in which the light shielding plates 6a and 6c are separated from each other. <When the flare is removed by the movement of the shading plates 6a and 6c> Next, the arithmetic and control circuit 20 operates the shading plates 6a and 6c.
After performing the movement control of 6c, it is determined again in the same manner as described above whether or not flare exists in the peripheral portion of the fundus image of the eye E to be inspected.
Then, when the arithmetic control circuit 20 determines that there is no flare or almost no flare (within the allowable range), the arithmetic control circuit 20 stores the fundus image in the memory M. <When the flare is not removed by the movement of the light shielding plates 6a and 6c> Further, the arithmetic control circuit 20 removes the flare in the peripheral portion of the fundus image of the eye E by driving the light shielding plates 6a and 6c. If it is not possible, it is determined that the eye E to be inspected is an eye with an artificial lens (artificial lens), that is, an IOL (intraocular lens), and the IOL mode is set.

In this IOL mode, the arithmetic control circuit 20
Controls as follows. That is, the arithmetic control circuit 20
The drive motors M1 and M2 are drive-controlled to control the light shielding plates 6a and 6a.
The c is controlled to move in the optical axis direction in a range wider than the specified amount, and the memory M stores the light amount of the peripheral portion of the fundus image of the eye E at each predetermined moving position. Then, the arithmetic control circuit 20
After the movement of the shading plates 6a, 6c is completed, the shading plates 6a, 6c are moved to the moving positions of the shading plates 6a, 6c where the light amount of the peripheral portion of the fundus image stored in the memory M has no flare, The fundus image is stored in the memory.

Further, when all the light amounts of the peripheral portion of the fundus image stored in the memory M include flare, the arithmetic control circuit 20 determines whether or not the light amount of the smallest flare is within the photographing allowable range. If it is within the allowable range for photographing, the fundus image is stored in the memory.

However, the arithmetic control circuit 20 determines that the light amount of the smallest flare is not within the photographing allowable range when the light amount of the peripheral portion of the fundus image stored in the memory M includes flare. In this case, the photographing is terminated without storing the fundus image in the memory M. In this case, it is possible that the eye E to be inspected has a cataract and the light amount of the fundus image is larger than a predetermined value as a whole.

Therefore, when the amount of light is larger than the predetermined value, the arithmetic control circuit 20 switches so as to perform the manual processing without performing the automatic processing for photographing. [C] Control of the light-shielding means in the auto mode in the case of mydriasis The patient is intravenously injected with a mydriatic agent to dilate the pupil of the subject's eye while activating the solenoid S and observing the quick return mirror 13. The observation light source 2 is turned off and the photographing light source 4 is turned on while the optical system 11a is retracted between the imaging lens 12 and the field lens 14a.

In this lighting state, visible light (visible photographing light) emitted from the photographing light source 4 passes through the first relay lens 5, the light shielding means 6, the second relay lens 7, the perforated mirror 8 and the objective lens 9. The light is projected onto the fundus (fundus of the eye to be examined) Ef of the eye to be examined E to illuminate the fundus Ef.

On the other hand, the reflected light reflected by the fundus Ef is the objective lens 9, the central aperture 8a of the perforated mirror 8, the imaging lens 12, the quick return mirror 13, and the roof prism 1.
4, the field lens 14a, and the first shooting lens 15 are projected onto the shooting TV camera 16 to display the shooting TV.
An image (fundus image) of the fundus Ef of the eye E is formed on the camera 16.

The video signal from the photographing TV camera 16 is input to the arithmetic control circuit 20. Then, the arithmetic control circuit 20 transfers the input video signal to the display device 21, and causes the display device 21 to display the fundus image of the eye E to be color-displayed.

In this state, the arithmetic and control circuit 20 performs the alignment as in the case of the non-mydriasis described above, and the flare light amount detection processing and the photographing processing similar to those in the case of the non-mydriasis. You can also do it. [D] Flare removal by manual processing when flare removal cannot be performed by the auto mode In the processing of [B] and [C] described above, when flare cannot be removed and the manual processing mode is entered, the flare is detected. The operator operates the switches 22 and 23 while observing the fundus image displayed on the display device 21 to operate the arithmetic control circuit 20.
While operating the drive motor M2 in the forward or reverse direction,
By moving the light shielding plate 6c of the illumination optical system 1 back and forth in the optical axis O direction, the lens rear surface Lb is aligned so that the edge portion of the light shielding image 6c 'coincides with the lens rear surface Lb as shown in FIG.
Move to the side to remove harmful reflected light. La is the front surface of the lens.

The light-shielded image 6a 'is separated from the cornea c,
When it becomes difficult to remove harmful reflected light due to incomplete light shielding by the light-shielded image 6a ', the switches 24, 2
While operating the drive motor M2 in the forward or reverse direction by operating the arithmetic control circuit 20 by operating 5, the illumination optical system 1
By moving the light-shielding plate 6a in the optical axis O back and forth, the light-shielding image 6a 'is moved to the cornea c side so that the edge portion of the light-shielded image 6a' coincides with the cornea c, and the harmful reflected light is removed.

After the harmful reflected light (flare) is removed in this way, in case of [A], the arithmetic control circuit 20 operates the solenoid S to operate the solenoid S when the photographing switch 26 is turned on. The light source 13 for observation is turned off and the light source 4 for photographing is turned on while the light source 13 for observation is turned off while the light source 13 for observation 13 is retracted from between the imaging lens 12 and the field lens 14a of the observation optical system 11a. Further, in the case of [B], the arithmetic control circuit 20
The observation light source 2 is turned off and the photographing light source 4 is turned on.

In this lighting state, visible light emitted from the photographing light source 4 (visible photographing light) passes through the first relay lens 5, the light shielding means 6, the second relay lens 7, the perforated mirror 8 and the objective lens 9. The light is projected onto the fundus (fundus of the eye to be examined) Ef of the eye to be examined E to illuminate the fundus Ef.

On the other hand, the reflected light reflected by the fundus Ef is the objective lens 9, the central aperture 8a of the perforated mirror 8, the imaging lens 12, the quick return mirror 13, and the roof prism 1.
4, the field lens 14a, and the first shooting lens 15 are projected onto the shooting TV camera 16 to display the shooting TV.
An image (fundus image) of the fundus Ef of the eye E is formed on the camera 16.

The video signal from the photographing TV camera 16 is input to the arithmetic control circuit 20. Then, the arithmetic control circuit 20 transfers the input video signal to the display device 21, and causes the display device 21 to display the fundus image of the eye E to be color-displayed.

The fundus image thus photographed is stored in the memory M.
Shooting is completed by storing in the memory.

The fundus image photographed as described above and stored in the memory M is recorded in the information recording / reproducing means R. [E] Flare removal when it is known that the eye to be inspected has a cataract or has an artificial lens <light-shielded images 6b ', 6a', 6c 'coincide with iris i, cornea c, and posterior surface Lb of lens> eye to be inspected If E is known to be a cataract, or artificial lens (artificial lens) or IO
When it is known from the beginning that the eye has an L (intraocular lens) attached, the mode changeover switch MS is operated so that the light shielding means 6 after the alignment can be manually operated as follows. To do.

FIG. 4 shows the appearance of the anterior segment of the subject's eye illuminated by the ring slit.

In the figure, 6b ', 6a', and 6c 'are arranged in the illumination optical system 1 so as to be substantially conjugate with the iris i, the cornea c, and the rear surface Lb of the lens L (hereinafter abbreviated to the lens rear surface Lb), respectively. It is a light-shielded image by the arranged light-shielding plates 6b, 6a, 6c.
Then, when the fundus Ef is illuminated by the illumination optical system 1, the portions surrounded by the light-shielded image 6b 'and the light-shielded lines 32, 32 and the light-shielded image 6c' and the light-shielded lines 32, 32 become the light-shielding portions 34, 34.
Therefore, the illumination light flux 31 passes through the outside of the light shields 34, 34 and illuminates the fundus Ef of the eye E to be examined. On the other hand, the reflected light from the fundus Ef passes through the light-shielding portions 34, 34 as the photographing light flux 33 and then enters the photographing optical system 11a and the observation optical system 11b of the photographing optical system 10. In this way
The harmful reflected light on each surface of the iris i, the cornea c, and the lens rear surface 1b of the eye E to be examined is prevented from entering the photographing light flux 33.
The photographing light flux 33 is determined by the aperture 8a of the perforated mirror 8 of the photographing optical system 10 and the like. <Light-shielded image 6c 'does not match the lens rear surface Lb> However, as shown in FIG. 5, the light-shielded image 6c' is different from the lens rear surface Lb because the thickness of the lens L and the curvature radius of the rear surface are different depending on the eye to be inspected. As a result, the light shielding image 6c 'becomes incompletely shielded, and it becomes difficult to remove harmful reflected light.

Therefore, with the light-shielded images 6b 'and 6a' in substantially conjugate positions with the iris i and the cornea c, respectively, the switch 2
2 and 23 are operated to rotate the drive motor M2 in the forward or reverse direction by the arithmetic control circuit 20, and the light blocking plate 6c of the illumination optical system 1 is moved back and forth in the direction of the optical axis O, whereby a light blocking image 6c 'is obtained. The harmful reflected light is removed by moving the lens to the lens rear surface Lb side so that the edge portion of the lens matches the lens rear surface Lb as shown in FIG. La is the front surface of the lens.

When the light-shielded image 6a 'is separated from the cornea c and the light-shielding by the light-shielded image 6a' becomes incomplete and it becomes difficult to remove harmful reflected light, the switches 24 and 25 are used.
By operating the operation control circuit 20 to rotate the drive motor M2 in the forward or reverse direction, the light-shielding plate 6a of the illumination optical system 1 is moved back and forth in the optical axis O direction. Is moved to the cornea c side so that it coincides with the cornea c to remove harmful reflected light.

Further, since the thickness of the lens L and the radius of curvature of the rear surface are different, the light-shielded images 6a ', 6c' are separated from the cornea c and the lens rear surface Lb, respectively, and the light-shielded images 6a ', 6c are formed.
When the light blocking by c'is incomplete and it becomes difficult to remove the harmful reflected light, the light blocking plates 6a and 6c are moved in the optical axis direction as described above. (Others 1) In addition, in order to image a wider fundus of the eye, the eye E may be guided by a fixation target (not shown). FIG. 6 shows the appearance of the anterior segment of the eye E to be examined in this case, and the solid line 35 in FIG. 6 represents the visual axis.

In this case, since the radii of curvature of the cornea c and the crystalline lens posterior surface Lb are different from the center of rotation 40 of the eyeball (eye E to be examined), it is difficult to remove harmful reflected light as in the case where the shape of the crystalline lens L is different. Become. That is, the light-shielded images 6a 'and 6c'
Moves away from the cornea c and the lens posterior surface Lb. Here, as described above, the light-shielding plates 6a and 6b have the inner light-shielding portion Ra.
And the ring slit Rs between the outer ring-shaped light shielding portion Rb
Are formed. The direction in which the harmful reflected light is emitted corresponds to the rotation direction of the subject's eye.

As a result, as shown in FIG. 7 (a), the light shielding plate Ra is provided with a light shielding plate 6'a in which an arcuate projection a is projected in the direction in which harmful reflected light is generated, or as shown in FIG. 7 (b). As shown in FIG. 5, by providing a light shielding plate 6'c in which the light shielding portion Ra is decentered in the direction in which harmful reflected light is generated, the light shielding plates 6'a and 6'are provided.
The diameter of c can be made as small as possible, which is effective when the eye E to be inspected is a small pupil. In this way, the light shield R
By providing a projection a that is eccentric with respect to the optical axis O in a part of a or by making the entire light shielding portion Ra eccentric with respect to the optical axis O, the light shielding in FIGS. 7A and 7B is performed. Plates 6'a, 6'c
Serves as an eccentric shading plate (eccentric shading means).

Further, since the guiding direction of the eye E to be inspected is an arbitrary direction, the light shielding plate E is illuminated with an optics so that the eccentric direction of the arcuate projection a or the light shielding portion Ra coincides with the direction of rotation of the eye E to be inspected. A drive motor such as a pulse motor (not shown) is rotated around the optical axis of the system 1. The control at this time is performed by the arithmetic control circuit 20.

Therefore, the light shielding plate 6a shown in FIG.
6c and the light-shielding plates 6'a and 6'c having the configuration shown in FIG. The light shielding plates 6a and 6c shown in FIG. 1 (b) are used. When the eye E to be inspected is rotated, the light shielding plate 6a shown in FIG.
Light-shielding plate 6'having the structure shown in FIG.
7A and the light shielding plate 6c shown in FIG.
Light-shielding plate 6'having the structure shown in FIG.
It is better to switch to c.

In addition, supplementally, it is possible to remove the effective reflected light of the eye E when the diameter of the light shielding portion Ra is simply increased, but the outside of the illumination light beam is limited by the pupil of the eye to be inspected and the inside is limited by the light shielding object. Therefore, the fundus of the eye to be examined may not be sufficiently illuminated. (Other 2) Further, when the harmful reflected light from the cornea c, the iris i, and the lens rear surface Lb of the subject's eye enters the photographing light flux 33,
Flare occurs in the captured image. Since flare appears around the fundus image, the examiner observes the flare image on the display device (observation monitor) 21 and switches 2 to eliminate flare.
2, 23 and 24, 25 are turned on to drive motor M
It is preferable that the light shielding plates 6a and 6c be moved in the direction of the optical axis O by the drive motors M1 and M2 by rotating the light shielding plates 6a and 6c in the forward or reverse direction.

The examiner confirms that the flare image on the display device (observation monitor) 21 has disappeared by the movement operation of the light shielding plates 6a and 6c by the examiner, and turns on the photographing switch 26 for photographing. I do.

When the eye E to be inspected is rotated as described above, the shading plate 6a shown in FIG. 1 (b) has the construction shown in FIG. 7 (a) or 7 (b). The light shielding plate 6c shown in FIG. 1B is switched to the light shielding plate 6'c having the configuration shown in FIG. 7A or 7B. Moreover, in this state, the examiner turns on the switches 22, 23 and 24, 25 while observing the flare image on the display device (observation monitor) 21 to turn off the drive motors M1, M2, respectively. The light shielding plates 6'a and 6'c may be moved in the optical axis O direction by the drive motors M1 and M2 by rotating them in the forward or reverse direction. In this case as well, the light shielding plates 6'a and 6'c are rotated around the optical axis as indicated by the other reference numeral 1. (Other 3) In the above-described embodiment, the examiner observes the state of the display device (monitor) 21 while the light-shielding plate (diaphragm) 6
Although the configuration has been described in which a and 6c are moved, a known flare detection such as providing a detector so that the flare in the peripheral portion can be detected in the device or observing the flare state based on the video signal of the display device 21 is described. A mechanism is provided and the output result thereof is input to the arithmetic control circuit 20. Then, the arithmetic control circuit 20
However, based on the output result from the flare detection mechanism, the display device 2
The light shielding plate (aperture) is based on the output result from the flare detection mechanism so that the flare detection state is displayed on the screen of No. 1 or the output result from the flare detection mechanism does not detect flare. The movement of 6a and 6c may be automatically controlled along the optical axis.

When the eye E to be inspected is rotated as described above, the light shielding plate (concentric light shielding means) 6a shown in FIG. 1B is operated by the arithmetic control circuit 20 as shown in FIG.
Light-shielding plate having the configuration shown in (b) (eccentric light-shielding means)
6'a, and the light-shielding plate (concentric light-shielding means) 6c shown in FIG. 1 (b) has the structure shown in FIG. 7 (a) or 7 (b). Switch to.

Moreover, the arithmetic control circuit 20 assists the display of the flare detection state on the screen of the display device 21 based on the output result of the flare detection mechanism, or detects the flare by the output result of the flare detection mechanism. The light-shielding plates (apertures) 6'a and 6'c may be automatically controlled to move in the optical axis direction based on the output result from the flare detection mechanism so that the state does not occur. In this case as well, the light shielding plates 6'a and 6'c are rotated around the optical axis as indicated by the other reference numeral 1. (Others 4) Further, in the embodiment, the description has been made by exchanging the diaphragms having different shapes, but the shapes may be changed by a mechanical mechanism. (Other 5) Further, by using an element such as a liquid crystal capable of controlling the position and the transmittance, it is possible to present a diaphragm having a simple structure and having any position, size and shape.

[0065]

As described above, the invention of claim 1 illuminates the fundus of the eye to be examined via the flare removing light-shielding means which is conjugated to at least one of the cornea, the iris, and the posterior surface of the crystalline lens of the eye to be examined. Having an illumination optical system and a photographing optical system for photographing the eye to be inspected, and an automatic alignment mechanism for automatically aligning a device main body including the optical system with respect to the eye to be inspected, and control for controlling operation of the auto alignment mechanism. In a fundus camera equipped with a circuit,
Flare detecting means for detecting flare incident on the photographing optical system is provided, Z alignment detecting means for detecting an alignment state in the optical axis direction of the eye to be inspected by the auto alignment mechanism is provided, and the light shielding means is provided for the illumination optical system. Drive means for driving in the optical axis direction is provided, and the control circuit detects completion of alignment by the automatic alignment mechanism by a detection signal from the Z alignment detection means, and at the same time, the flare detection means. When the flare is detected, the driving means is operated and controlled so that the light-shielding means is finely moved in the optical axis direction of the illumination optical system by a preset amount. Work can be performed easily.

According to a second aspect of the present invention, in the fundus camera according to the first aspect, the control circuit detects completion of alignment by the automatic alignment mechanism by a detection signal from the Z alignment detecting means. At the same time, when the flare detecting means detects flare, the driving means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a predetermined amount set by the flare detecting means. When it is determined that the flare detection state has not been detected by the flare detection means, and the flare detection means determines that the flare detection means is not detecting further flare, the configuration is such that the imaging optical system captures an image of the eye to be examined. After confirming whether or not flare is present at the time of completion, fundus imaging can be performed reliably without flare.

Further, the invention of claim 3 is the fundus camera according to claim 2, wherein the control circuit detects completion of alignment by the auto-alignment mechanism by a detection signal from the Z-alignment detecting means. At the same time, when the flare detecting means detects flare, the driving means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a predetermined amount set by the flare detecting means. When the flare detection state is judged, and when it is judged that the flare detection means is further detecting flare based on this judgment, the drive means is operated and controlled so that the light shielding means is within the predetermined range set in advance. Automatically search the flare detection state by the flare detection means while moving in the optical axis direction of the system,
After sequentially storing the flare light amounts at a plurality of moving positions in the memory, the light shielding unit is moved by the driving unit in the optical axis direction of the illumination optical system to a position where the flare light amount stored in the memory is small, Since the configuration is set so as to photograph the eye to be inspected by the photographing optical system, even if flare is detected, the flare can be automatically removed and fundus photography can be performed.

According to a fourth aspect of the invention, in the fundus camera according to the second aspect, the control circuit detects that the alignment by the automatic alignment mechanism has been completed by a detection signal from the Z alignment detecting means. At the same time, when the flare detecting means detects flare, the driving means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a predetermined amount set by the flare detecting means. When the flare detection state is judged, and when it is judged that the flare detection means is further detecting flare based on this judgment, the drive means is operated and controlled so that the light shielding means is within the predetermined range set in advance. Automatically search the flare detection state by the flare detection means while moving in the optical axis direction of the system,
After sequentially storing the flare light amounts of a plurality of movement positions in the memory, when the minimum flare light amount stored in the memory is equal to or larger than a predetermined value, the photographing of the eye to be examined by the photographing optical system is stopped, and the manual photographing mode is set. Since the configuration is set so as to switch the flare, even if flare cannot be removed, flare removal work can be performed by manual operation (manual operation), and fundus imaging without flare can be reliably performed.

[Brief description of drawings]

1A is an explanatory diagram of an optical system of a fundus camera according to the present invention, and FIG. 1B is an explanatory diagram of a light shielding plate in FIG.

FIG. 2 is an explanatory diagram showing a Z alignment optical system of the fundus camera according to the present invention.

FIG. 3 is a control circuit of the fundus camera shown in FIG.

FIG. 4 is an enlarged explanatory diagram of an anterior segment of the subject's eye shown in FIG. 1.

5 is an explanatory view of the operation when the distance between the cornea and the posterior lens surface of the anterior segment shown in FIG. 4 is large.

6 is an enlarged explanatory view of an anterior segment when the eye to be inspected shown in FIG. 1 is rotated by a fixation target.

7A and 7B are explanatory diagrams showing another example of the light shielding plate shown in FIG.

[Explanation of symbols]

1 ... Illumination optical system 6 ... Shading means 6a, 6b, 6c ... (Shading means, concentric shading means) 6'a, 6'c ... Shading plate (eccentric shading means) 10 ... Shooting optical system 16 ... TV camera for photographing (flare detection means) 19: TV camera for shooting 20 ... Arithmetic control circuit (control circuit) c ... Cornea E ... Eye to be examined i ... iris La ... Front of crystalline lens Lb: Rear of lens M1, M2 ... Drive motor (drive means)

Claims (4)

[Claims] 1. An illumination optical system for illuminating the fundus of the eye to be examined through a light-shielding means for flare removal which is conjugated with at least one of the cornea, the iris, and the posterior surface of the crystalline lens of the eye to be examined, and an image to photograph the eye to be examined. In an eye fundus camera having an optical system and an auto-alignment mechanism for automatically aligning an apparatus main body including the optical system with respect to the eye to be inspected, and a fundus camera including a control circuit for controlling operation of the auto-alignment mechanism, the light is incident on the photographing optical system. Flare detection means for detecting flare is provided, Z alignment detection means for detecting the alignment state in the optical axis direction of the eye by the auto-alignment mechanism is provided, and the light shielding means is driven in the optical axis direction of the illumination optical system. And a driving means for driving the automatic alignment mechanism. When the flare detecting means detects a flare at the same time that the completion of the measurement is detected by the detection signal from the Z alignment detecting means, the driving means is operated and controlled so that the light shielding means is moved by a predetermined amount. A fundus camera, which is set so as to make a slight movement in the optical axis direction of the illumination optical system. 2. The fundus camera according to claim 1, wherein the control circuit detects completion of alignment by the automatic alignment mechanism by a detection signal from the Z alignment detection means, and at the same time, the flare detection means When flare is detected, the drive means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a preset predetermined amount to determine the flare detection state by the flare detection means, The fundus camera is set so as to take an image of the eye to be inspected by the taking optical system when the flare detecting means determines that the flare is not further detected. 3. The fundus camera according to claim 2, wherein the control circuit detects completion of alignment by the automatic alignment mechanism by a detection signal from the Z alignment detection means, and at the same time, the flare detection means. When flare is detected, the drive means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a preset predetermined amount to determine the flare detection state by the flare detection means, When it is determined from this determination that the flare detection means is further detecting flare, the drive means is operated and controlled so that the light shielding means is moved in the optical axis direction of the illumination optical system within a preset predetermined range. The flare detection state is automatically searched by the flare detection means while sequentially recording the flare light amounts at a plurality of movement positions in the memory. After that, the light-shielding means is moved in the optical axis direction of the illumination optical system by the driving means to a position where the amount of flare light stored in the memory is small, so that the image of the eye to be inspected is taken by the imaging optical system. A fundus camera characterized by being set. 4. The fundus camera according to claim 2, wherein the control circuit detects that the alignment by the automatic alignment mechanism has been completed by a detection signal from the Z alignment detection means, and at the same time, the flare detection means. When flare is detected, the drive means is operated and controlled, and the light shielding means is finely moved in the optical axis direction of the illumination optical system by a preset predetermined amount to determine the flare detection state by the flare detection means, When it is determined from this determination that the flare detection means is further detecting flare, the drive means is operated and controlled so that the light shielding means is moved in the optical axis direction of the illumination optical system within a preset predetermined range. The flare detection state is automatically searched by the flare detection means while sequentially recording the flare light amounts at a plurality of movement positions in the memory. After that, when the minimum amount of flare light stored in the memory is equal to or larger than a predetermined value, the photographing of the eye to be inspected by the photographing optical system is stopped, and it is set to switch to the manual photographing mode. Fundus camera to do.