JP2004236843A - Photographing apparatus for ophthalmology - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a photographing apparatus for ophthalmology, selecting and changing the optimum illumination method corresponding to the state of cell of each layer to be observed and photographed even in the process of photographing. <P>SOLUTION: This photographing apparatus for ophthalmology includes: an illuminating optical system 6 provided with a first mirror element 36 having a great number of very small mirrors, light reflection of which are controllable, and adapted to reflect illuminating light on the first mirror element 36 to be obliquely applied from the front to an anterior ocular segment of an examined eye E; a photographing optical system 7 provided with a second mirror element 37 having a great number of very small mirrors, light reflection of which are controllable and adapted to reflect the reflected light from the anterior ocular segment on the second mirror element 37; and a control device for controlling both mirror elements 36, 37. The control device sets the relative positional relationship between an illumination reflecting part 36a controlled to reflect light on the first mirror element 36 and a photographing reflecting part 37a controlled to reflect light on the second mirror element 37. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ophthalmic imaging apparatus. More specifically, the present invention relates to an ophthalmologic photographing apparatus for observing and photographing cells such as a cornea by a specular method without making contact with an eye to be examined. The specular imaging apparatus is an apparatus that irradiates illumination light obliquely with respect to the optical axis of the eye to be examined, receives mainly specular reflected light from the cornea obliquely, and observes and photographs this image.
[0002]
[Prior art]
FIG. 14 schematically shows a cross section of the cornea C. The symbol T is a tear film. The symbol U indicates the epithelium, the symbol J indicates the substantial part, and the symbol I indicates the endothelium. In recent years, LASIK (laser in situ keratomileisis) has been actively performed for dioptric correction and the like. In the LASIK operation, the cornea C of the eye to be examined is bisected in the thickness direction at the parenchyma J, and the exposed parenchyma is irradiated with a laser beam to thin the cornea C. Then, the cornea C, which has been bisected, is returned to the original state, and the restoration and integration are awaited. In this case, it is necessary to observe the cornea after the operation to monitor the restoration status of the bisected cornea, but it is not possible to specify in advance the position of the portion D of the substantial portion of the cornea which is being restored after being bisected. It must be monitored and probed in the corneal plane and thickness.
[0003]
For this purpose, a device is required that clearly separates the image showing the state of each layer from the images of other layers while moving the observation point in the thickness direction of the cornea. This is because, in particular, the parenchyma has cells that are not arranged in a layered manner like endothelial cells and epithelial cells and have an irregular shape in the corneal thickness direction.
[0004]
In order to separate the image of the observation target from the image of the other layer and photograph clearly, it is necessary to use an extremely narrow slit illumination light. However, it is difficult to form a narrow slit, and a field of view can be obtained only with a narrow slit width. Therefore, a corneal cell photographing apparatus has been proposed that can scan by scanning slit light to the anterior segment of the eye to be examined (for example, see Patent Literature 1, Patent Literature 2, and Patent Literature 3). These photographing apparatuses have a rotary slit plate. This slit plate has a plurality of slits formed on a circumference having the same radius from the center of rotation. The slit illumination light that has passed through one slit (illumination slit) is reflected by the anterior segment of the subject's eye, and the other slit (imaging slit) positioned 180 ° from the illumination slit across the center of rotation of the slit plate. ) To the imaging camera. Since the slit plate rotates, the illumination slit and the imaging slit move in synchronization with each other, and the cornea of the subject's eye is scanned by the slit light. Therefore, it is possible to observe and photograph a wide range of corneal cells even with slit light that illuminates a very narrow range.
[0005]
[Patent Document 1]
JP 2001-245846 A
[Patent Document 2]
JP 2002-17678 A
[Patent Document 3]
JP 2002-17679 A
[0006]
[Problems to be solved by the invention]
However, it is difficult to mechanically form a narrow slit in the slit plate. Further, the slit position that can be used for each optical system is limited due to the shape of the slit, the scanning direction, and the like. Further, due to the arrangement of the illumination optical system and the photographing optical system, it is difficult to realize the accuracy of scanning the entire photographing visual field while maintaining the relationship between the illumination slit and the photographing slit in a conjugate position.
[0007]
The present invention has been made in order to solve such problems, and easily and accurately separates reflected light from other layers not only of the endothelium and epithelium of the eye to be examined, but also of each of the parenchymal layers, and has a sufficient effect. It is an object of the present invention to provide an ophthalmologic photographing apparatus capable of obtaining a clear cell image by the amount of illumination light.
[0008]
[Means for Solving the Problems]
The ophthalmologic photographing apparatus of the present invention,
An illumination optical system having a first mirror element having a large number of micromirrors capable of controlling light reflection, and irradiating illumination light to the anterior eye portion of the subject's eye from obliquely forward by reflecting the first mirror element. A second mirror element having a large number of micromirrors capable of controlling light reflection, an imaging optical system for reflecting the reflected light from the anterior ocular segment to the second mirror element for imaging, and A control unit for controlling the mirror element, wherein the control unit is controlled to reflect light at the first mirror element and controlled to reflect light at the second mirror element. It is configured to set a relative positional relationship with the photographing reflector.
[0009]
With this configuration, it is possible to irradiate the eye to be inspected with illumination light having a predetermined shape (hereinafter, referred to as a slit shape including a dot shape or a band shape) by being reflected by the illumination reflection portion set in the first mirror element. This is because light reflection can be controlled for each micromirror (micromirror). In addition, when the slit-like reflected light from the eye to be examined reaches the second mirror element, it is easy to set a reflecting portion in the second mirror element based on the position where the slit-shaped reflected light reaches the second mirror element. Therefore, the difficulty of forming and arranging the slit as in the conventional slit plate is avoided. As a result, it is possible to effectively separate the reflected light from the other layers in the layer to be imaged by the eye. As each of the mirror elements, a so-called DMD (digital micromirror device) is suitable.
[0010]
The control device controls the illumination reflector of the first mirror element to move, and further moves the imaging reflector of the second mirror element in synchronization with the movement of the illumination reflector of the first mirror element. An ophthalmologic photographing apparatus that is configured to control as much as possible is preferable. This is because the illumination reflection unit and the photographing reflection unit can be easily and synchronously moved. As a result, scanning of the subject's eye is facilitated, and a cell image of a wide field of view can be obtained despite the narrow slit width.
[0011]
Further, the imaging optical system receives the reflected light obliquely forward in the anterior eye portion, and the surface of the second mirror element is disposed approximately optically conjugate with the imaging target surface of the eye to be inspected. Ophthalmic imaging devices are preferred. This is because a clear image that is in focus with a wider range can be obtained on an inclined imaging surface.
[0012]
Further, the operating position detection index light is reflected by the first mirror element to irradiate the anterior eye of the subject's eye from obliquely forward, and receives the focused reflected light in the anterior eye from obliquely forward to determine the operating position. It is preferable that the ophthalmologic imaging apparatus further includes an operating position detecting optical system for detecting, and the first mirror element is provided with an index light reflecting portion that reflects the operating position detecting index light. This is because the configuration of the operating position detecting optical system is simplified. Further, the operating position to be set can be easily changed.
[0013]
Another ophthalmic photographing apparatus of the present invention,
An illumination optical system that has a first liquid crystal element having a large number of pixels capable of controlling light transmission, transmits illumination light to the first liquid crystal element, and irradiates the anterior part of the subject's eye from obliquely forward, A photographic optical system having a second liquid crystal element having a large number of pixels capable of controlling light transmission, and transmitting reflected light from the anterior segment through the second liquid crystal element for photographing; And a control unit for controlling the illumination of the first liquid crystal element to transmit light, and the imaging unit controlled to transmit light in the second liquid crystal element. It is configured to set a relative positional relationship with the transmission unit.
[0014]
With this configuration, the eye can be irradiated with slit-shaped illumination light by transmitting the illumination light through the illumination transmission portion set in the first liquid crystal element. This is because light transmission can be controlled for each pixel. Further, when the slit-like reflected light from the eye to be examined reaches the second liquid crystal element, it is easy to set a light transmitting portion in the second liquid crystal element based on the position where the light has reached. Therefore, the difficulty of forming and arranging the slit as in the conventional slit plate is avoided. As a result, it is possible to effectively separate the reflected light from the other layers in the layer to be imaged by the eye.
[0015]
The control device controls the illumination transmission part of the first liquid crystal element to move, and further moves the imaging transmission part of the second liquid crystal element in synchronization with the movement of the illumination transmission part of the first liquid crystal element. An ophthalmologic photographing apparatus that is configured to control as much as possible is preferable. This is because scanning of the eye to be inspected becomes easy, and a cell image of a wide field of view can be obtained despite the narrow slit width.
[0016]
Further, the operating position detection index light is transmitted through the first liquid crystal element to irradiate the anterior eye of the subject's eye from obliquely forward, and the in-focus reflected light in the anterior eye is received from obliquely forward to determine the operating position. It is preferable that the ophthalmologic imaging apparatus further includes an operating position detecting optical system for detecting, and the first liquid crystal element is provided with an index light transmitting portion that transmits the operating position detecting index light. This is because the configuration of the operating position detecting optical system is simplified, and the set operating position can be easily changed.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
An ophthalmologic photographing apparatus according to the present invention will be described based on an embodiment shown in the accompanying drawings.
[0018]
FIG. 1 is a plan view schematically showing an embodiment of an ophthalmologic photographing apparatus according to the present invention, and mainly shows an optical path thereof. FIG. 2 is a view taken along line II-II in FIG. 1 and mainly shows the optical path. FIG. 3 is a view taken along line III-III of FIG. 1 and mainly shows the optical path. FIG. 4 is a cross-sectional view of a central portion of the apparatus of FIG. 1, and is a view mainly showing an optical path thereof.
[0019]
The ophthalmologic photographing apparatus 1 shown in FIGS. 1 to 4 includes a machine frame 2, a Z direction mounted on the machine frame 2, and a Z direction that moves forward and backward toward the subject's eye E, and an X that is perpendicular to the Z direction and perpendicular to each other. An XYZ moving base 3 that can move in the directions and the Y directions is provided. Furthermore, an XYZ follow-up pedestal 4 mounted on the XYZ movable gantry 3 and capable of moving in the XYZ directions with respect to the eye E is provided. The following optical systems are assigned to the XYZ movable mount 3 and the XYZ followable mount 4, respectively.
[0020]
That is, an illumination optical system 6 for illuminating the anterior eye of the eye E with a slit light obliquely from the front thereof for observation and photographing of ophthalmic imaging, and the slit light reflected on the surface of the anterior eye of the eye E. An optical system 7 for imaging the subject, a first alignment optical system 8 and a second alignment optical system 9 for performing alignment (alignment) of the imaging optical axis with the eye E in the X and Y directions, and an imaging optical system A Z-direction positioning optical system (operating position detecting optical system) 10 for aligning the focal point 7 with the corneal endothelium, which is the imaging site, is disposed.
[0021]
The illumination optical system 6 has an observation lamp 11 and a xenon tube 12 as a light source for illuminating the cornea. The observation lamp 11 is used for continuously observing ophthalmic photography while moving the focal point in the corneal thickness direction, and emits visible light. The xenon tube 12 is used to photograph a cell at a specified site, and emits visible light. Illumination light from any of the light sources 11 and 12 is reflected in a slit shape by the first mirror element 36 on which a slit reflection portion 36a as an illumination reflection portion for forming slit light is formed. The light passes through the illumination objective lens 14 and is converged on the cornea of the eye E to be examined. The first mirror element 36 has a number of micromirrors capable of controlling light reflection. In this embodiment, a known DMD element (digital micromirror device) is used as the first mirror element and a second mirror element 37 described later. A hot mirror 15 is interposed in the optical path of the illumination optical system 6 to make the optical path of an operation position detecting optical system 10 to be described later halfway in the optical path of the illumination optical system 6. The hot mirror 15 transmits illumination light, which is visible light, and reflects index light, which is infrared light, for detecting an operating position, which will be described later.
[0022]
The photographing optical system 7 has a CCD camera 17 for observing and photographing ophthalmic photographing. The slit light reflected by the cornea of the subject's eye E passes through the imaging objective lens 18, the mirror 19, the imaging lens 20, the second mirror element 37 including the DMD element and the relay lens 13, and is reflected by the mirror 30. It is led to the CCD camera 17. The slit reflected light forms an image once at the position of the second mirror element 37, is reflected in a slit shape by the slit reflecting part 37 a as a photographing reflecting part at the image forming position on the second mirror element 37, and is reflected by the relay lens 13 into the CCD camera 17. Is formed on the light-receiving surface of In the present embodiment, the optical path of the photographing optical system 7 is the same as the optical path of the operating position detecting optical system 10 described later halfway. For this purpose, a hot mirror 21 for splitting the optical path is interposed. The hot mirror 21 transmits the illumination light, which is visible light, and reflects the index light for detecting the operating position, which is infrared light.
[0023]
Here, the first and second mirror elements 36 and 37 will be described. A large number of micromirrors are arranged in a matrix on a surface of a DMD serving as a mirror element in a predetermined section. Each micromirror can be digitally controlled to tilt its surface independently. In the present embodiment, each micromirror is inclined ± 12 ° in the same direction with respect to the normal to the surface of the DMD. Of course, a device that is inclined at another angle may be used.
[0024]
FIG. 5 shows the relationship between the direction of the light incident on the mirror elements 36 and 37 and the direction of the reflected light. In the present embodiment, the light is incident at an incident angle of 24 ° with respect to the normal N of the element surface, and is reflected in the direction of the normal N by the inclination of ± 12 ° of the micromirror (called on-off) (called on). ) And the case of reflection in the direction of 48 ° with respect to the normal line N (called off). Further, the micromirrors to be turned on / off in this manner and the range thereof can be arbitrarily set by the control device 42. That is, it is possible to arbitrarily change the outer shape (slit shape) of the range to be turned on / off. For example, it is possible to turn on / off a micromirror in a narrow rectangular area (so-called band-shaped area), a micromirror in a microcircle, a micromirror in an annular area, and the like. Further, the control device 42 can move the on / off range while maintaining the outer shape of these ranges. That is, the movement of the slit (slit reflecting portion).
[0025]
The functions of the mirror elements 36 and 37 in the device 1 will be described with reference to FIGS. In the illumination optical system 6 and the photographing optical system 7, the light reflected by the mirror elements 36 and 37 along the optical axes 6 a and 7 a of each optical system when the mirror element is turned on in any of the optical systems 6 and 7. move on. When the mirror element is off, the reflected light deviates from the optical axes 6a and 7a and is absorbed by the light absorber 31 arranged in the direction of the reflected light.
[0026]
In the present apparatus 1, an optical slit is formed in each of the mirror elements 36 and 37. That is, the micromirrors in the range of the slit shape are turned on (the above-described slit reflection portions 36a and 37a), and the micromirrors in the other range are turned off. Therefore, light incident on the mirror element is reflected as slit light. As described above, each mirror element corresponds to a slit in the related art, and a combination of both mirror elements corresponds to a slit plate in the related art. However, the mirror element has much better functions than conventional slits and slit plates. This is because the movement of the first and second mirror elements 36 and 37 can be synchronized easily and with high accuracy, and the shape of the slit can be arbitrarily changed.
[0027]
In the present apparatus 1, the illumination light that has been formed into a slit shape by the first mirror element 36 is reflected by the subject's eye and reaches the second mirror element 37 to form an image. In the second mirror element 37, a slit reflecting portion 37a having substantially the same shape as the slit light is formed substantially corresponding to the image forming position of the incident slit light. Of course, different shapes may be used as described later. The micromirrors in that range are turned on. Therefore, the invasion of the scattered light is suppressed by the second mirror element 37, and the slit illumination light is reflected in a slit shape. The slit light is received by the CCD camera 17, and an image of the test portion is captured.
[0028]
As shown in FIG. 6, it is easy to scan the eye to be inspected by the slit illumination light. FIG. 6 shows the movement of the slit reflecting portions 36a and 37a in the mirror elements 36 and 37. The two-dot chain line in the figure indicates the driving range of the micro mirror. FIG. 6B shows a first slit reflecting portion (illumination light reflecting portion) 36a, and FIG. 6A shows a corresponding second slit reflecting portion (photographing light reflecting portion) 37a. The arrow in the figure indicates the scanning direction, the small circle indicates the center of the illumination optical axis 6a and the imaging optical axis 7a, and the top and bottom correspond to the directions on the eye to be examined. The slit reflecting portion 36a of the first mirror element 36 is moved while maintaining the slit shape (FIG. 6B). By doing so, the slit illumination light moves on the surface of the eye to be inspected, and the reflected light moving by the eye to be inspected is captured by the second mirror element 37. In the second mirror element 37, the slit reflecting portion 37a having substantially the same shape as the slit light is moved in synchronism with the movement of the slit light, substantially coincident with the image forming position of the slit light incident on the surface of the second mirror element 37 (FIG. FIG. 6 (a)). This operation is performed by controlling the drive mechanism of the mirror element by the control device 42.
[0029]
With this configuration, it is possible to photograph the cornea and the like of the eye E by separating the reflected light from each layer using the slit light, and to scan the cornea. This is also shown in FIG. As shown in FIG. 7A, reflected light R1, R2 from different layers S1, S2 of the cornea of the eye E is effectively separated by one thin slit illumination light L1. Further, as shown in FIGS. 7B and 6A, by scanning the narrow slit illumination light with L1, L2, and L3, reflected light R1, R2, and R3 in a wide range of one layer S can be obtained. Light is continuously received, and images are continuously taken of K1, K2, and K3 (see also FIG. 6B). Therefore, even with slit light that illuminates an extremely narrow range, it is possible to observe and photograph a wide range of corneal cells and the like by scanning. Since the above scanning can be repeated in a very short time, corneal cells and the like can be observed as moving images. The scanning direction may be only one direction, and reciprocating scanning with a predetermined stroke is also possible. It is possible to use slit illumination light having a width narrow enough to completely separate the reflected light from the surface of the thin surface layer (about 10 microns or less) of the corneal surface and the reflected light from the corneal epithelium. For example, the slit reflecting portion on the first mirror element 36 is formed to have a width of about 0.05 to 0.2 mm, and the slit light reflected by the slit reflecting portion is converted to about 10 μm on the cornea by the lens system. Can be reduced so as to be slit illumination light having a width of This reflected light is also enlarged by the lens system of the photographing optical system 7.
[0030]
The adjustment for forming the slit reflecting portion 37a having substantially the same shape as the slit light substantially coincident with the imaging position of the slit light reflected by the subject's eye and formed on the second mirror element 37 will be described later.
[0031]
The direction of an image from the illumination optical system 6 to the photographing optical system 7 in the present apparatus 1 will be described with reference to FIG. FIGS. 1A and 1B show arrows indicating the up and down directions of the slit image and the left and right directions when the illumination light from the illumination light sources 11 and 12 is slit into the first mirror element 36. It is also described as a town needle shape. FIG. 1B shows the direction of the image on the mirror elements 36 and 37 as viewed from the back side of the mirror elements. In the first mirror element 36 and the second mirror element 37, the vertical and horizontal directions of the incident image are opposite to each other. FIG. 1C shows the movement (scanning) of the slit reflecting portions 36a and 37a in the mirror elements 36 and 37 as viewed from the back side of the mirror elements. The two-dot chain line in the figure indicates the driving range of the micro mirror. FIG. 1D shows the moving direction of the slit illumination light in the anterior segment of the subject's eye when the slit reflecting portion 36a of the first mirror element 36 moves in the direction shown in FIG. 1C. FIG. 1D shows a state in which the slit illumination light is reflected by the corneal surface and the corneal endothelium. The reflected light is strong at the corneal surface.
[0032]
The illumination light is obliquely incident on the surface of the eye E and is reflected obliquely. The light reflected obliquely is received by the CCD camera 17 of the photographing optical system on a surface perpendicular to the photographing optical axis 7a. Therefore, when scanning with the slit illumination light, the peripheral portions (both ends) in the scanning direction in the visual field range (reference numeral H in FIG. 7B) are out of focus. In order to solve such a problem, the second mirror element 37 is installed with its normal line inclined with respect to the photographing optical axis 7a. That is, the surface of the second mirror element 37 is tilted in a direction to offset the tilt of the reflected light with respect to the surface of the eye E, that is, the surface of the second mirror element 37 is tilted with respect to the imaging surface of the photographing lens 20. It is inclined (see FIG. 3). In the present embodiment, as described above, the normal line of the first mirror element is inclined by 24 ° with respect to the imaging optical axis 7a.
[0033]
Next, the first alignment optical system 8 has an alignment objective lens 22, light sources 23X and 23Y for two alignment index lights composed of light emitting diodes, and light receiving elements 24 such as area sensors. The light sources 23X and 23Y are first projection units, and the alignment objective lens 22, a diffusion lens 25a and an imaging lens 25b described below, and the light receiving element 24 are first detection units. The intersection of the optical axis 6a of the illumination optical system 6 and the optical axis 7a of the photographing optical system 7 is located on the optical axis of the objective lens 22 for alignment. This intersection is the focal point described later.
[0034]
FIG. 8 shows an arrangement in the vicinity of the objective lenses 14, 18, and 22 as viewed from the eye E. Around the alignment objective lens 22, an X-axis light source 23X and a Y-axis light source 23Y are arranged in a 90 ° direction with respect to each other. From each of the light sources 23X and 23Y, infrared index light is alternately emitted toward the eye E. The index light from each of the light sources 23X and 23Y is reflected by the subject's eye, passes through the alignment objective lens 22, the diffusion lens 25a and the imaging lens 25b, and forms an image on the light receiving element 24. The image signal from the light receiving element 24 is sent to a control device 42 described later.
[0035]
An alignment operation using the first alignment optical system 8 will be described with reference to FIG. The alignment performed by moving the XYZ gantry 3 using the first alignment optical system 8 is referred to as first alignment. 9A shows an anterior segment image displayed on the monitor screen 26 in a state where the first alignment is established, that is, the optical axis of the alignment objective lens 22 is set to the eye E to be examined. This shows a state in which the vertices are matched. At this time, if both the light sources 23X and 23Y are turned on, and the center of the anterior eye is set to the vertex of the eye to be examined, the image 23Xa of the X-axis light source and the Y-axis Are displayed, and the ranges of the images 23Xa and 23Ya in this state are set as alignment completion ranges (hereinafter, referred to as gates) 27X and 27Y. When the alignment is not established, the image 23Xa of the X-axis light source is off the gate 27X as shown in FIG. 9B, and the image of the Y-axis light source is shown in FIG. 9C. 23Ya is off the gate 27Y. At this time, the XYZ movable gantry 3 is moved in the X direction so as to enter the gate 27X in the X direction, and the XYZ movable gantry 3 is moved in the Y direction so as to enter the gate 27Y in the Y direction. During the alignment operation, the X-axis light source 23X and the Y-axis light source 23Y emit light alternately in synchronization with the setting of the gates 27X and 27Y alternately at a short pitch to facilitate identification. The first alignment is completed when both images 23Xa and 23Ya enter their gates 27X and 27Y.
[0036]
Next, the operating position detecting optical system 10 will be described with reference to FIGS. The operating position detecting optical system 10 irradiates an eye to be inspected with an index light for detecting an operating position, which is infrared light, which is infrared light, and a reflected light of the index light obliquely from the eye to be inspected. And a detection light detection optical system 10b for detecting The detection light irradiation optical system 10a includes an infrared lamp 28 as an index light source for detecting an operation position. The detection index light is formed by the first mirror element 36 as described later. The detection light detection optical system 10b includes an operation position detection sensor 29. The detection light irradiation optical system 10a has almost the same optical axis as the illumination optical system 6, and a detection lamp 28 is disposed on the optical axis branched by the hot mirror 15. The detection light detection optical system 10b has almost the same optical axis as the imaging optical system 7, and an operation position detection sensor 29 is disposed on the optical axis branched by the hot mirror 21. As the operation position detection sensor 29, a line sensor or an area sensor is used.
[0037]
The indicator light from the detection lamp 28 is reflected by the first mirror element 36, reaches the eye E through the optical axis 6a of the illumination optical system 6, and is reflected by the anterior segment. The reflected light passes through the optical axis 7a of the photographing optical system 7, is reflected by the hot mirror 21, reaches the operation position detecting sensor 29, and is received. The first mirror element 36 is provided with an operating position detecting reflecting portion (index light reflecting portion) 32 which does not move, separately from the slit reflecting portion 36a for observation and photography (see FIG. 10 (h1)). One area of the micromirror may be used as the index light reflecting section 32. As will be described later, when observing the subject's eye following fine movement of the subject's eye, for example, the operation position detecting operation and the observation photographing operation are performed in parallel. Therefore, there is a possibility that reflected light from the first mirror element 36 other than from the index light reflecting portion 32 is also received by the operating position detection sensor 29. In order to prevent this, a mask 39 for blocking reflected light from portions other than the index light reflecting portion 32 is provided in front of the operating position detection sensor 29. As a result, even when the micromirrors in other ranges in the first mirror element 36 are turned on, only the index light reflected from the index light reflector 32 to the subject's eye reaches the operating position detection sensor 29.
[0038]
FIG. 10 illustrates the pattern of the slit reflecting portions 36a and 37a in the mirror elements 36 and 37. The lower part of each figure is a first slit reflection part (illumination reflection part) 36a, and the upper part is a corresponding second slit reflection part (photographing reflection part) 37a. The two-dot chain line in the figure indicates the driving range of the micro mirror. The intersections of the vertical and horizontal center lines correspond to the optical axes 6a and 7a.
[0039]
When the indicator light is received in a predetermined area set in the light receiving range of the operating position detection sensor 29, the control device 42 determines that the operating position has been reached, and an image is taken. This is the operation position, which is the reference position for focusing.
[0040]
The above will be described in more detail with reference to FIG. In FIG. 11, the optical path of the index light when the index light reflecting portion 32 is formed at a predetermined position (the position shown in FIG. 10 (h1)) of the first mirror element 36 and the corneal surface of the eye to be examined with the index light. Are shown as L2 and R. The intersection of the optical axis of the detection light irradiation optical system 10a and the optical axis of the detection light detection optical system 10b is the operating position K2 (FIG. 11). When the optical system reaches the operating position, the intersection (focal point) between the optical axis 6a of the illumination optical system 6 and the optical axis 7a of the imaging optical system 7 is located at a position (imaging) in the thickness direction of the cornea of the eye E to be examined. ), The cells at this site will be imaged. In FIG. 11, it is indicated by reference numeral C. The illumination light from the symbol L2 to the symbol C is the illumination light, and the illumination light from the symbol C to the symbol 7a is the reflected light of the imaging portion, and is the light reaching the CCD camera. Since the reflected light that can be clearly detected by the operating position detection sensor 29 is the reflected light on the corneal surface, the position when the reflected light on the corneal surface is detected is defined as the operating position. The control device 42 moves the XYZ movable gantry 3 by the feedback control according to the displacement of the eye E so as to maintain the operating position, that is, so that the reflected slit light reaches the predetermined area of the operating position detecting sensor 29. Move in the axial direction. This is the first Z-direction positioning operation.
[0041]
As shown in FIG. 11, the intersection (imaging site) C between the optical axis 6a of the illumination optical system 6 and the optical axis 7a of the imaging optical system 7 is defined by the optical axis of the detection light irradiation optical system 10a and the optical axis of the detection light detection optical system 10b. It is set at a position different from the intersection (operation position) K2 with the optical axis. This is because, as described above, the operating position is clearly detected by the reflected light on the corneal surface, but the imaging region is usually not the surface but a layer inside the cornea. However, it is easy to make C and K2 coincide.
[0042]
The first alignment operation and the first Z-direction positioning operation proceed as follows. First, the subject fixes the face by bringing the face into contact with the chin rest 43 and the forehead pad 44 of the device 1. Next, the subject E is fixed by causing the subject to fixate on a fixation lamp (not shown). Next, the images 23Xa and 23Ya of the first alignment index light are confirmed on the monitor screen 26 by bringing the XYZ movable base 3 close to the eye to be inspected. Thereafter, the XYZ movable gantry 3 is moved closer to the subject's eye while maintaining the alignment, and the first Z-direction positioning is performed. After the first alignment and the first Z-direction positioning are performed, the operation is switched to the second alignment operation and the second Z-direction positioning operation. As will be described later, the second alignment operation and the second Z-direction positioning operation are to move the XYZ tracking gantry 4 according to the displacement of the eye E by feedback control.
[0043]
The present apparatus 1 is configured so that each layer of the cornea can be observed by moving the focal point in the thickness direction of the cornea. Specifically, the reflection point and the focal point of the detection index light to be detected by the operation position detection sensor 29 on the subject's eye are relatively displaced in the axial direction of the objective lens. Since the reflected light that can be clearly detected by the operating position detection sensor 29 is reflected light on the corneal surface, an image is taken at this time (when the operating position is reached), and the operating position is separated from the focal point. Or approach. This means that the focal point is displaced in the thickness direction of the cornea as described above.
[0044]
In order to relatively move the operating position, the index light reflecting portion 32 of the first mirror element 36 is moved in a lateral direction perpendicular to the optical axis of the detection light irradiation optical system 10a. This will be described with reference to FIGS. For example, it is moved from FIG. 10 (h1) to FIG. 10 (h2) or FIG. 10 (h3). The moving distance is stored by the control device 42 as position information. When the index light reflecting section 32 is reset to the position shown in FIG. 10 (h2), the index light is emitted to the subject's eye from L1 in FIG. 11, and the operating position that can be detected by the operating position detection sensor 29 is shown in FIG. It becomes the code K1 in the middle. Conversely, when the index light reflecting section 32 is reset to the position shown in FIG. 10 (h3), the index light is radiated to the subject's eye from L3 in FIG. The position is indicated by the symbol K3 in the figure. By moving the index light reflecting portion 32 in the lateral direction with respect to the optical axis 10a in this manner, the detectable operating position moves forward and backward. In response to this, the XYZ moving gantry 3 is moved in the Z direction to move the operating position in the Z axis direction. That is, since the reflected light for detecting the operating position deviates from the setting range of the operating position detecting sensor 29 by moving the index light reflecting portion 32 in the lateral direction, the operating position detecting sensor 29 detects the reflected light by feedback control. Thus, the XYZ movable base 3 is moved in the Z direction. As a result, the focal point (focusing point) of the photographing optical system 7 moves in the Z-axis direction. In this way, the focal point is aligned with each layer in the thickness direction of the cornea. By this operation, each layer in the thickness direction of the cornea can be observed.
[0045]
Both the first alignment optical system 8 and the operating position detecting optical system 10 described above have their optical devices divided and mounted on the XYZ moving gantry 3 and the XYZ tracking gantry 4. Therefore, the optical devices on the XYZ moving gantry 3 and the optical devices on the XYZ following gantry 4 form an afocal optical path so that the movement of the XYZ following gantry 4 does not affect the imaging operation. Is configured. Specifically, as shown in FIG. 1, in the illumination optical system 6, the illumination light is converted into a parallel light beam by the illumination lens 5, and in the imaging optical system 7, the cornea reflected light is converted into a parallel light beam by the imaging objective lens 18. In the optical system 8, the reflection light of the alignment index light from the subject's eye is converted into a parallel light beam by the diffusion lens 25a. Since the optical device of the second alignment optical system 9 described later is mounted on the XYZ tracking gantry 4, it is not necessary to form an afocal optical path.
[0046]
Next, the second alignment optical system 9 will be described. The second alignment optical system 9 includes the above-described alignment objective lens 22, and has a second alignment index light source 33 composed of a light emitting diode that emits infrared light and a light receiving element 34 such as an area sensor. As described above, the second alignment optical system 9 and the first alignment optical system 8 share the same alignment objective lens 22. The second alignment index light source 33 and the alignment objective lens 22 are a second projection unit, and the alignment objective lens 22, the imaging lens 35, and the light receiving element 34 are a second detection unit.
[0047]
As shown in FIG. 12, the index light Bf from the second alignment index light source 33 is supplied by the alignment objective lens 22 to the optical axis of the alignment objective lens 22 at a predetermined distance in front of the surface of the eye E at the operating position. It is converged at an angle that forms an image upward. The reflected light Br on the surface of the eye to be examined passes through the alignment objective lens 22 and the imaging lens 35 and is received by the light receiving element 34. The predetermined dimension is about の of the radius of curvature r of the corneal surface, whereby the reflected light Br on the surface of the eye becomes parallel light. The radius of curvature r of the corneal surface of a general human eye is about 8 mm. The actual setting of the alignment objective lens 22 is such that the index light is positioned about 0.5 r ahead of the focal point of the photographing optical system 7, that is, the intersection of the optical axis 6a of the illumination optical system 6 and the optical axis 7a of the photographing optical system 7. It is made to form an image.
[0048]
FIG. 12A shows a state in which the optical axis of the alignment objective lens 22 is orthogonal to the vertex of the eye to be inspected, that is, a state in which the XY alignment is established, and the reflected light Br is applied to the optical axis of the alignment objective lens 22. Is back along. FIG. 8B shows a state in which the optical axis of the alignment objective lens 22 deviates from the vertex of the eye to be inspected, that is, a state in which the XY alignment has not been established. It is inclined to. As an example, when the vertex of the eye to be examined deviates from the optical axis of the alignment objective lens 22 by 0.01 mm, the optical axis of the reflected light Br is inclined by about 0.15 ° with respect to the optical axis of the alignment objective lens 22. When it deviates by 0.6 mm, it is inclined by about 9 °. When the displacement of the alignment objective lens 22 from the optical axis is small, this displacement is substantially proportional to the inclination angle of the reflected light. Even when the eye to be examined is slightly displaced in this way, it is enlarged and detected by the light receiving element 34.
[0049]
An image signal is sent to the control device 42 from the light receiving element 34 that has received the reflected light Br on the surface of the subject's eye. The control device 42 moves the XYZ tracking gantry 4 in the XY directions based on the luminescent spot, which is the reflected light Br of the alignment index light Bf on the cornea of the eye E to be inspected, so that the optical axis of the alignment objective lens 22 becomes the corneal vertex. Match.
[0050]
A specific alignment operation will be described with reference to FIG. The center O of the monitor screen 26 shown in FIG. 13 corresponds to the optical axis of the alignment objective lens. Therefore, as is clear from FIG. 12A, the bright spot F is located at the center O when the second alignment is established. In a state where the second alignment is not established, the luminescent spot F is out of the screen center O as shown by a two-dot chain line. The XYZ tracking gantry 4 is moved in the XY directions such that the bright spot F moves to the center O by feedback control of the control device 42.
[0051]
In the control device 42, the speed at which the bright spot F is moved toward the center O (the speed of the XYZ tracking gantry 4) is proportional to the distance between the center O and the bright spot F. That is, when the XYZ tracking gantry 4 is moved, the approach speed decreases as the optical axis of the alignment objective lens 22 approaches the corneal vertex. By doing so, overrun or hunting of the movement of the XYZ tracking stand with respect to the target position is prevented, and the control accuracy is improved.
[0052]
During the second alignment operation, the second Z-direction positioning operation is performed in parallel. The second Z-direction positioning is also performed by using the above-described operation position detection optical system 10, but the XYZ movement gantry 3 is moved instead of the XYZ movement gantry 3. That is, the control device 42 moves the XYZ tracking gantry 4 in the Z-axis direction by feedback control according to the displacement of the eye E so that the reflected slit light reaches the predetermined area of the operation position detection sensor 29. The point that the XYZ tracking gantry 4 is moved instead of the XYZ moving gantry 3 is different from the first alignment, and the other operations are the same, and therefore the description is omitted. Since the afocal optical path is formed as described above, the relative movement of the XYZ tracking gantry 4 with respect to the XYZ moving gantry 3 does not affect the operation of the optical system.
[0053]
In the present apparatus 1, first, the first alignment operation and the first Z-direction positioning operation are performed, and when the first alignment operation and the first Z-direction positioning operation are completed, the control device 42 switches to the second alignment operation and the second Z-direction positioning operation. When the operation is switched to the second operation, the eye to be inspected can easily follow the fixation even if the eye moves slightly. On the other hand, the range of the detectable displacement of the subject's eye in the first alignment is large, and the range of the detectable displacement of the subject's eye in the second alignment is small. For example, the former ranges from 10 to 15 mm in diameter and the latter ranges from about 2 mm. Therefore, if the eye to be examined is greatly displaced during the second alignment operation, it cannot be detected. In this case, that is, when the bright spot F caused by the reflected light during the second alignment operation has disappeared from the gate, the control device 42 switches to the first alignment operation. Then, when the first alignment is established, the alignment operation is switched from the first to the second again.
[0054]
When the second alignment is established and the operation position is detected, the inspector operates the observation button to turn on the continuous observation lamp 11, and performs a focusing operation. The focusing operation is performed by moving the index light reflecting portion 32 of the first mirror element 36 by operating the focus button. That is, by moving the operating position relative to the focal point of the imaging optical system 7 in the Z direction, the focal point of the imaging optical system 7 is moved in the thickness direction of the cornea. During this time, the second alignment is maintained. As a result, the ophthalmic photographed image is displayed on the monitor screen, and the examiner can observe the cell image of each layer in the thickness direction of the cornea of the eye to be examined. The examiner operates the imaging button at a desired position, that is, at the selected corneal site, so that the xenon tube 12 emits light and can take an ophthalmologic image of the site. The selected image is recorded as a still image.
[0055]
Hereinafter, an initial setting for making the slit reflecting portion 36a of the first mirror element 36 coincide with the slit reflecting portion 37a of the second mirror element 37 will be described below. First, a light receiving element (not shown) such as an area sensor for detection is arranged at the position of the eye E to be examined. Next, the continuous observation lamp 11 as an illumination light source is turned on. Then, in the illumination optical system 6, the slit light is irradiated on the light receiving element by the point-like slit reflecting portion 36a (see FIG. 10B) fixedly set to the first mirror element 36, and the slit light is received by the light receiving element. On the other hand, a light source for initial setting is arranged at the position of the CCD camera 17 of the photographing optical system 7, and is turned on. Then, in the photographing optical system 7, slit light is irradiated to the light receiving element by the point-like slit reflecting portion 37a (see FIG. 10B) set in the second mirror element 37, and the slit light is received by the light receiving element. Thus, the light receiving element is irradiated with two slit lights. After that, the shape and position of the slit light on the light receiving element surface are changed by changing and moving the shape of the slit reflecting portion 37a of the second mirror element 37 by the control device 42. By doing so, the positions of the slit light by the first mirror element 36 and the second mirror element 37 are matched. This position is stored in the control device 42. As a result, the positions of the slit reflecting portions 36a and 37a of both mirror elements optically match, and the initial setting is completed. Of course, at this time, there is no problem even if the position of the slit reflector 36a in the first mirror element 36 and the position of the slit reflector 37a in the second mirror element 37 are different. Specifically, while the position of the slit reflecting portion 36a of the first mirror element 36 is at the center of the first mirror element 36, the position of the slit reflecting portion 37a of the second mirror element 37 is (See FIG. 10A). Even in this case, both slit reflecting portions can be scanned synchronously by the control device 42.
[0056]
Focusing will be described with reference to FIG. As described above, when the slit reflecting portions 36a and 37a of both mirror elements 36 and 37 are optically matched, that is, when both slit reflecting portions 36a and 37a are located on the center of the optical axis, for example, The illumination light L2 (the optical axis at which the slit reflecting portion of the first mirror element 36 is located) matches the optical axis R2 at which the slit reflecting portion 37a of the second mirror element 37 is located. In addition, the slit illumination light L1 (the optical axis where the slit reflection portion 36a of the first mirror element 36 is located) matches the optical axis R1 where the slit reflection portion of the second mirror element 37 is located, and the slit illumination light L3 ( The optical axis R3 at which the slit reflector 37a of the second mirror element 37 is located coincides with the optical axis at which the slit reflector 36a of the first mirror element 36 is located). The above may be referred to FIG. Therefore, the intersection K1 between L1 and R1, the intersection K2 between L2 and R2, and the intersection K3 between L3 and R3 are the imaging parts, respectively. Then, in this state, that is, when the slit illumination light is scanned synchronously while the slit reflecting portions 36a and 37a of the two mirror elements 36 and 37 are made to coincide with each other, the imaging region reaches K3 from K1 through K2, and the field of view in the figure. An image in the range H is captured.
[0057]
However, the positions of the slit reflecting portions 36a and 37a of both mirror elements may be shifted from each other without being matched in advance (see FIGS. 10 (g2) and 10 (g3)). For example, suppose that the slit reflecting portions 36a and 37a of both mirror elements are set so that L3 and R1 in FIG. 7B correspond (see FIG. 10G3). In this case, an intersection K4 between L3 and R1 is photographed. When scanning with the slit illumination light, an image of the visual field range H in the drawing is captured for the layer S4 having the depth where the above K4 is located. It is also assumed that the slit reflecting portions 36a and 37a of both mirror elements are set so that L1 and R3 in FIG. 7B correspond (see FIG. 10G2). In this case, an intersection (not shown) of L1 and R3 is photographed. As described above, by shifting the positions of the slit reflecting portions of the two mirror elements without making them coincide with each other (by changing the scanning phase of the slit illumination light), the depth of the imaging region in the subject's eye is changed. Can be. With this configuration and the control by the control device 42, the depth of the imaging region is changed only by the phase change of the slit reflecting portion on the mirror element without moving the optical system itself, so that the responsiveness is good. Therefore, it is possible to cope with the slight movement of the subject's eye at the time of the continuous observation described above.
[0058]
Further, even after the two slit reflecting portions are made to coincide with each other as described above, it is possible to change the predetermined distance and the predetermined direction by the control device 42.
[0059]
As described above, the shape of the slit reflecting portions of the mirror elements 36 and 37 can be freely changed by the control device 42. This can be changed during the scan. Hereinafter, an example of a modification of the slit shape will be described.
[0060]
Since the cornea surface of the eye to be examined has a spherical shape, the direction of reflection of the illumination light at the peripheral portion deviates from the imaging objective lens 18 and becomes dark. Therefore, as shown in FIG. 10C, the slit shape is widened toward both ends, and the illumination light amount is increased toward both ends. Alternatively, the slit shape is made a narrow rectangle, and the lighting duty is changed by changing the blinking speed of the micromirror between the center of the slit and the vicinity of both ends, that is, by changing the ratio of the lighting time and the light-off time. May be.
[0061]
Although not shown, the brightness of the tear film, mucin layer, corneal epithelium, stromal layer, and corneal endothelium of the eye to be examined are different. That is, the reflectivity for illumination light is different. Therefore, the illumination light amount can be changed by changing the slit width according to the difference in the observation target site. Alternatively, the duty of illumination may be changed by changing the blinking speed of the micro mirror as described above.
[0062]
Each layer of the cornea of the eye to be examined has a depth of field suitable for the observation. It is better for the endothelium and the parenchymal layer to be deep. On the other hand, it is better to reduce the depth of the epithelium and the mucin layer to improve the separation of reflected light. At the time of observation of each layer, it is easy to operate by first adjusting to the endothelial layer as a reference. At this time, it is easy to find the observation site by widening the slit width, and after specifying the observation site, it is easy to observe if the slit width is narrowed to improve the resolution.
[0063]
If the width of the slit illumination is narrowed to improve the light separation, the reflected light whose direction has changed due to slight displacement of the subject's eye may not be captured by the slit reflecting portion 37a of the second mirror element 37 in some cases. In this case, as shown in FIG. 10D, by setting the slit width of the first mirror element 36 wider than the slit width of the second mirror element 37, even if the eye to be examined moves slightly forward, backward, left and right, the amount of observation light is increased. Can be suppressed.
[0064]
For example, when observing corneal epithelial basal cells, strong scattered light from the tear film may cause disturbance. Further, nerve fibers of the eye to be examined are difficult to observe by specular reflected light. In such a case, as shown in FIGS. 10E and 10F, the slit reflecting portions of both mirror elements 36 and 37 are arranged so that the illumination optical path and the imaging optical path do not intersect at the observation site of the subject's eye. It is preferable to observe by scattered light from the surroundings by setting the phase so as to be shifted. FIG. 10E shows that although the centers of both slit reflecting portions 36a and 37a coincide, the imaging side 37a is a small circular slit, and the illumination side 36a does not coincide with the small circular slit 37a. A ring-shaped slit corresponding to the outside. FIG. 10 (f) shows that although the centers of both slit reflecting portions 36a and 37a coincide with each other, the imaging side 37a is a narrow band-shaped slit, and the illumination side 36a does not coincide with this band-shaped slit 37a. There are two strip-shaped slits corresponding to the parallel positions on both the left and right sides.
[0065]
Further, a small circular slit reflecting portion is formed as shown as the photographing side slit reflecting portion 37a in FIGS. 10B and 10E, and the small circular (or dot) slit is scanned vertically and horizontally. It is also possible. In some cases, a single micro mirror may be scanned vertically and horizontally. Scanning can be performed like a screen display of a television. With this configuration, light can be separated in any direction around the small circular or point slit. That is, in the case of the elongated slit illumination light, the light can be separated in the width direction, but cannot be separated in the longitudinal direction of the slit as much as the width direction. There is no such problem in the case of a small circular or point slit.
[0066]
In the embodiment described above, the DMD element is used as the slit member of the illumination optical system and the photographing optical system, but the present invention is not limited to such a configuration. For example, a liquid crystal element may be used instead of the DMD element. In a known liquid crystal element having a large number of liquid crystal cells (pixels), similarly to the DMD element, each pixel transmits and transmits light (referred to as ON) and shields (referred to as OFF) by digital control by a suitable control device. Can be. Therefore, by using the first liquid crystal element and the second liquid crystal element instead of the above-described first and second mirror elements and turning on a predetermined range of pixels in the liquid crystal element, slit-like light can be transmitted. A slit transmission portion (illumination light transmission portion and photographing light transmission portion) having a predetermined shape can be formed. Further, the function is the same as that of the DMD element in that the shape of the pixel to be turned on can be changed or moved.
[0067]
Further, it is easy to set an index light transmitting portion in the first liquid crystal element, similarly to the first mirror element 36 described above. The operating position is detected by irradiating the operating position detection index light transmitted through the index light transmitting section to the anterior eye of the subject's eye, and detecting the reflected light at the anterior eye with the operating position detecting sensor 29 described above. Can be. Further, similarly to the index light reflecting portion 32 of the first mirror element 36, the focal point can be changed by changing the position of the index light transmitting portion.
[0068]
The fundamental difference between a liquid crystal element and a DMD element is that, in a DMD element, a micromirror in an on state and a micromirror in an off state reflect light in a different direction, whereas in a liquid crystal element, a micromirror turns on. In this state, the pixel transmits light, and the pixel in the off state blocks light. Therefore, as described above, the optical axis of the DMD element is bent by reflection, but the light axis of the liquid crystal element is not bent since the light is transmitted. In this regard, when a liquid crystal element is used, it can be said that the optical path is equivalent to that of a conventional slit plate that transmits light.
[0069]
【The invention's effect】
In the ophthalmologic imaging apparatus of the present invention, an optical slit having an arbitrary shape is formed by the mirror element, and the position of the slit is easily changed, so that the eye to be inspected is irradiated with slit illumination light having a predetermined shape. The reflected light can be separated with high accuracy in the eye to be examined. Therefore, the difficulty of forming and arranging the slit as in the conventional slit plate is avoided. In addition, it is possible to select and change an optimal illumination method according to the state of cells in each layer to be observed and photographed, even during photographing.
[Brief description of the drawings]
FIGS. 1A and 1B show arrows indicating the up and down directions of the slit image and the left and right directions when the illumination light from the illumination light sources 11 and 12 is slit into the first mirror element 36. It is also described as a town needle shape. FIG. 1B shows the direction of the image on the mirror elements 36 and 37 as viewed from the back side of the mirror elements. In the first mirror element 36 and the second mirror element 37, the vertical and horizontal directions of the incident image are opposite to each other. FIG. 1C shows the movement (scanning) of the slit reflecting portions 36a and 37a in the mirror elements 36 and 37 as viewed from the back side of the mirror elements. The two-dot chain line in the figure indicates the driving range of the micro mirror. FIG. 1D shows the moving direction of the slit illumination light in the anterior segment of the subject's eye when the slit reflecting portion 36a of the first mirror element 36 moves in the direction shown in FIG. 1C.
FIG. 1A is a plan view schematically showing mainly an optical path of an ophthalmologic photographing apparatus according to an embodiment of the present invention, and FIG. 1B is a plan view of the ophthalmologic photographing apparatus shown in FIG. FIG. 1C shows the orientation of the image in the mirror element of the apparatus as viewed from the back side of the mirror element, and FIG. 1C shows the movement of the slit reflector in the mirror element as viewed from the back side of the mirror element. FIG. 1D shows a state before the eye to be examined when the slit reflecting portion of the first mirror element of the ophthalmologic photographing apparatus of FIG. 1A moves in the direction shown in FIG. 1C. It shows the moving direction of the slit illumination light in the eye.
FIG. 2 is a view taken in the direction of arrows II-II in FIG. 1, and mainly shows an optical path thereof.
FIG. 3 is a view taken along a line III-III in FIG. 1, and mainly shows an optical path thereof.
FIG. 4 is a cross-sectional view of a central portion of the device of FIG. 1, mainly showing an optical path thereof.
FIG. 5 is a side view showing the relationship between the direction of light incident on a mirror element and the direction of reflected light in the apparatus of FIG. 1;
FIGS. 6A and 6B are plan views showing the movement of a slit reflecting portion set on a mirror element when scanning slit illumination light with respect to an eye to be inspected.
7 (a) and 7 (b) are cross-sectional views showing scanning of the eye to be inspected by slit illumination light performed by the apparatus of FIG. 1;
FIG. 8 is a view taken along line VIII-VIII in FIG. 4;
FIGS. 9A to 9C are front views of a monitor screen showing an example of a first alignment operation performed by the apparatus of FIG. 1;
FIGS. 10 (a) to 10 (h3) are plan views each showing an example of a slit reflecting portion set in a mirror element in the apparatus of FIG. 1;
11 is a cross-sectional view showing a relationship between a detection index light and a photographing illumination light at the time of detecting an operation position by the apparatus of FIG. 1;
12A and 12B are side views each showing an example of a second alignment operation performed by the apparatus of FIG. 1;
FIG. 13 is a front view of a monitor screen showing an example of a second alignment operation performed by the apparatus of FIG. 1;
FIG. 14 is a cross-sectional view schematically showing a cross section of a cornea.
[Explanation of symbols]
1 Ophthalmic imaging device
2 aircraft frame
3 XYZ movable mount
4 XYZ tracking rack
5 Lighting lens
6. Illumination optical system
6a Optical axis (of illumination optics)
7 Shooting optical system
7a Optical axis (of photographing optical system)
8 First alignment optical system
9 Second alignment optical system
10 Operating position detection optical system
10a Detection light irradiation optical system
10b Detection light detection optical system
11 Continuous observation lamp
12 Xenon tube
13 relay lens
14 Illumination objective lens
15 Hot mirror
17 CCD camera
18 Objective lens for photography
19 mirror
20 Shooting lens
21 Hot Mirror
22 Objective lens for alignment
23X Light source for X axis
23Y Y-axis light source
23Xa X-axis light source image
23Ya Y-axis light source image
24 light receiving element
25a Diffusion lens
25b imaging lens
26 Monitor screen
27X X direction gate
27Y Y direction gate
28 Detection lamp
29 Operating position detection sensor
30 mirror
31 Light absorber
32 Indicator light reflector
33 Second alignment index light source
34 light receiving element
35 Imaging lens
36 First mirror element
37 Second mirror element
36a Slit reflector of first mirror element
37a Slit reflector of second mirror element
38 motor
39 mask
42 Controller
43 chin rest
44 Forehead
Bf Second alignment index light
Br (the second alignment index light) reflected light
E Eye to be examined
F bright spot
H Field of view
r radius of curvature (of the eye surface)

Claims (7)

An illumination optical system having a first mirror element having a number of micromirrors capable of controlling light reflection, and irradiating illumination light to the anterior eye portion of the subject's eye from obliquely forward by reflecting the first mirror element. ,
An imaging optical system having a second mirror element having a large number of micromirrors capable of controlling light reflection, and imaging by reflecting light reflected by the anterior eye to the second mirror element,
A control device for controlling the two mirror elements,
The controller is configured to set a relative positional relationship between an illumination reflector controlled to reflect light at the first mirror element and an imaging reflector controlled to reflect light at the second mirror element. Ophthalmological imaging device. The control device controls the illumination reflector of the first mirror element to move, and further moves the imaging reflector of the second mirror element in synchronization with the movement of the illumination reflector of the first mirror element. 2. The ophthalmologic photographing apparatus according to claim 1, wherein the photographing apparatus is configured to perform control as needed. The imaging optical system receives the reflected light obliquely forward in the anterior eye part, and the surface of the second mirror element is disposed substantially optically conjugate with the imaging surface of the eye to be inspected. An ophthalmologic imaging apparatus according to claim 1. The operating position detection index light is reflected by the first mirror element to irradiate the anterior eye of the subject's eye from obliquely forward, and receives the focused reflected light from the anterior eye from obliquely forward to detect the operating position. It further includes an operating position detection optical system,
2. The ophthalmologic photographing apparatus according to claim 1, wherein an index light reflecting portion for reflecting the operating position detection index light is set on the first mirror element. An illumination optical system that has a first liquid crystal element having a large number of pixels capable of controlling light transmission, transmits illumination light to the first liquid crystal element, and irradiates the anterior part of the subject's eye from obliquely forward,
An imaging optical system having a second liquid crystal element having a large number of pixels capable of controlling light transmission, and transmitting reflected light from the anterior ocular segment to the second liquid crystal element for imaging.
A control device for controlling the two liquid crystal elements,
The controller is configured to set a relative positional relationship between an illumination transmission unit controlled to transmit light in the first liquid crystal element and an imaging transmission unit controlled to transmit light in the second liquid crystal element. Ophthalmological imaging device. The control device controls the illumination transmission part of the first liquid crystal element to move, and further moves the imaging transmission part of the second liquid crystal element in synchronization with the movement of the illumination transmission part of the first liquid crystal element. 6. The ophthalmologic photographing apparatus according to claim 5, wherein the apparatus is configured to perform control as needed. The operating position detection index light is transmitted through the first liquid crystal element to irradiate the anterior eye of the subject's eye from obliquely forward, and receives the focused reflected light from the anterior eye from obliquely forward to detect the operating position. It further includes an operating position detection optical system,
The ophthalmologic photographing apparatus according to claim 5, wherein an index light transmitting portion that transmits the operating position detection index light is set in the first liquid crystal element.

Images