JP6116212B2 - Ophthalmic equipment - Google Patents

Description

  The present invention relates to an improvement in an ophthalmologic apparatus used for an ophthalmic examination such as a fundus examination.

  2. Description of the Related Art Conventionally, there are large-sized ophthalmologic apparatuses that are installed in ophthalmic clinics or spectacle stores and used by doctors having specialized knowledge as ophthalmologic apparatuses used for fundus examinations, eyesight examinations, and the like. In recent years, a light and compact ophthalmic apparatus has been developed that is easy to carry and operate, and that can be easily examined by group screening in places other than hospitals or the like (for example, Patent Document 1, 2).

  Patent Document 1 discloses an ophthalmologic apparatus that combines a hand-held type and a stationary type. The hand-held ophthalmologic apparatus is a small ophthalmologic apparatus that is used by a person who performs an examination such as a doctor (hereinafter referred to as “examiner”). The examiner grasps a handle or the like provided in the ophthalmologic apparatus, brings the eye of the person to be examined (hereinafter referred to as “subject”) close to the eyepiece, and observes and photographs the eye to be examined. . Further, the stationary ophthalmic apparatus is an ophthalmic apparatus that is used by being installed on a desk or work table. The hand-held type allows easy and flexible inspection regardless of the place of use. On the other hand, in the stationary type, the subject's eye is more reliably inspected because the head and the jaw of the subject are placed on the alignment and the head is fixed to the device. be able to.

  Further, Patent Document 2 discloses a hand-held ophthalmic apparatus in which a handle can be rotated with an optical axis as a rotation axis with respect to the apparatus main body. With such a configuration, the angle of the handle can be freely set with respect to the camera body, and it is not necessary for the examiner and the subject to face each other in front of each other for inspection. Therefore, it is intended to increase the degree of freedom of inspection such that a subject sleeping on the bed can be inspected from any direction of the bed.

JP-A-9-234184 Japanese Patent Laid-Open No. 9-224910

  However, in conventional ophthalmologic apparatuses such as Patent Documents 1 and 2, operation buttons and an operation panel are arranged at positions that are easy for the examiner to operate in a state where the eyepiece and the like are close to the examinee's eye. Yes. That is, since it is assumed that a person other than the subject performs an ophthalmic examination of the subject, it is not assumed that the subject performs an ophthalmic examination by himself / herself. Therefore, when the subject becomes an examiner with a hand-held ophthalmic apparatus and performs his own ophthalmic examination, the ophthalmic apparatus is rotated 180 °, and an operation button or the like is placed with the eyepiece or the like in proximity to his / her own eye. Need to operate. In this case, since the operation buttons and the like are also inverted by 180 °, the operation buttons are searched for and operated in an unstable state such as unnaturally bending the wrist, which may affect the inspection accuracy. . In the case of a stationary ophthalmic apparatus, when the examiner performs his own ophthalmic examination, it is troublesome because it is necessary to move to the position of the subject, and the operation panel or the like is difficult to operate. May end up.

  The present invention has been made in view of the above circumstances, and can be easily used for group examinations, etc., and the examiner not only conducts an ophthalmic examination of the subject but also examinees himself. It is an object of the present invention to provide an ophthalmologic apparatus with excellent operability, which allows the examiner to perform his or her own ophthalmic examination with high accuracy.

To achieve the above object, an ophthalmologic apparatus according to the present application includes an apparatus main body having at least an optical system that receives light from an eye to be examined illuminated by an illumination light source, and a support that supports the apparatus main body. The operation unit for giving a processing instruction to the apparatus main body is provided so as not to rotate with respect to the support, and the optical system is connected to the support with respect to the optical axis of the optical system. The position of the optical system with respect to the support and the operation unit is changed by relatively rotating an axis orthogonal to the rotation axis.

  According to the present invention, the position of the optical system can be changed with respect to the support by rotating the optical system used for the ophthalmic examination. Therefore, not only can the optical system be disposed at a position facing the subject's eye but also the optical system can be disposed at a position facing the subject's own eye. Therefore, it can be used easily for group examinations, etc., and not only the examiner conducts an ophthalmic examination of the subject, but also the examinee becomes the examiner himself or the examiner takes his own ophthalmic examination. In addition, it is possible to provide an ophthalmic apparatus with excellent operability that can be performed with high accuracy. As a result, ophthalmic examination can be performed with high accuracy, and the optical performance of the ophthalmologic apparatus can be improved. In addition, it is not necessary for the subject to go to a hospital or the like equipped with an ophthalmologic apparatus, and the examination can be easily performed even in a group medical examination or the like performed outside a medical facility such as a public hall or a company.

It is a perspective view of the optical scanning ophthalmoscope concerning Example 1 of this application. 3 is an explanatory diagram for explaining a configuration of an optical system of an optical scanning ophthalmoscope according to Embodiment 1 and a system configuration of a control circuit unit; FIG. In the optical scanning ophthalmoscope according to Example 1, it is a schematic diagram showing a state where the examiner is photographing the fundus of the subject (other person photographing mode). FIG. 6 is a schematic diagram illustrating a state (self-photographing mode) in which the examiner is photographing his / her fundus with the hand-held optical scanning ophthalmoscope according to the first embodiment. In the hand-held optical scanning ophthalmoscope according to Example 1, it is a schematic diagram showing a relative positional relationship between the apparatus main body and a support in the other person photographing mode, and (a) is a plane viewed from the apparatus main body side. It is a figure, (b) is the front view seen from the eyepiece part, (c) is a side view. FIG. 3 is a schematic diagram illustrating a state in which a support is detached from the apparatus main body of the hand-held optical scanning ophthalmoscope according to the first embodiment. In the hand-held optical scanning ophthalmoscope according to Embodiment 1, it is a schematic view showing a relative positional relationship between the apparatus main body and a support in the self-photographing mode, and (a) is a plan view seen from the apparatus main body side. (B) is a front view seen from the eyepiece, and (c) is a side view. It is a top view which shows the relative positional relationship of the apparatus main body at the time of rotating the apparatus main body of the handheld optical scanning ophthalmoscope which concerns on Example 2 with respect to a support body, (a). The initial position before rotation (other person shooting mode) is shown, (b) shows a state rotated by 90 ° from the initial position (second other person shooting mode), and (c) shows 180 ° rotation from the initial position. (Self-photographing mode). In the hand-held optical scanning ophthalmoscope according to Example 3, it is a schematic diagram showing the relative positional relationship between the apparatus main body and the support in the other person's imaging mode, and (a) is a plane viewed from the apparatus main body side. It is a figure, (b) is the front view seen from the eyepiece part, (c) is a side view. In the hand-held optical scanning ophthalmoscope according to Example 3, it is a schematic view showing a relative positional relationship between the apparatus main body and the support in the self-photographing mode, and (a) is a plan view seen from the apparatus main body side. (B) is a front view seen from the eyepiece, and (c) is a side view. In the stationary optical scanning ophthalmoscope according to Example 4, it is a schematic diagram showing a relative positional relationship between the apparatus main body and the support in the other person photographing mode, and (a) is a plane viewed from the apparatus main body side. It is a figure, (b) is the front view seen from the eyepiece part, (c) is a side view. In the stationary optical scanning ophthalmoscope according to Example 4, it is a schematic view showing a relative positional relationship between the apparatus main body and the support in the self-photographing mode, and (a) is a plan view seen from the apparatus main body side. (B) is a front view seen from the eyepiece, and (c) is a side view. In the stationary optical scanning ophthalmoscope according to Example 5, it is a schematic diagram showing a relative positional relationship between the apparatus main body and the support in the other person photographing mode, and (a) is a plane viewed from the apparatus main body side. It is a figure, (b) is the front view seen from the eyepiece part, (c) is a side view. In the stationary optical scanning ophthalmoscope according to the fifth embodiment, a schematic diagram showing a relative positional relationship between the apparatus main body and the support in the self-photographing mode, where (a) is a plan view viewed from the apparatus main body side. (B) is a front view seen from the eyepiece, and (c) is a side view.

Example 1
(Outline configuration of handheld optical scanning ophthalmoscope)
Hereinafter, an ophthalmologic apparatus according to Embodiment 1 of the present application will be described with reference to FIGS. FIG. 1 illustrates a hand-held (also referred to as a portable type) optical scanning ophthalmoscope 100 as an ophthalmic apparatus according to a first embodiment, and includes an apparatus main body 1 and a support body 2 that supports the apparatus main body 1. Is configured.

  Hereinafter, in the present specification, the apparatus main body 1 is directed upward and the support 2 is corresponding to the vertical direction in a state where the optical scanning ophthalmoscope 100 is held in a normal usage pattern (normal posture) as shown in FIG. The direction is defined as down. Therefore, even when the optical scanning ophthalmoscope 100 is tilted or placed upside down, the apparatus main body 1 side is assumed to be the upper side and the support body 2 side is assumed to be the lower side. In an ophthalmic apparatus configured such that when the apparatus is held in a normal posture, the apparatus main body is located below and the support is located above, the support body side may be defined as the upper side and the apparatus body side as the lower side. As for the front-rear and left-right directions, basically, as shown in FIG. 1, when performing the ophthalmic examination of the subject, the direction in which the eyepiece is located is the front, the direction of the examiner is the rear, and the eyepiece The left side is defined as left and the right side is defined as right as viewed from the above, but for the sake of explanation, description may be made with the front, back, left and right interchanged.

  As shown in FIGS. 1 and 6, the apparatus main body 1 is provided with an eyepiece tube portion 3 as an eyepiece portion that faces the subject eye. Further, a monitor unit 4 for displaying a fundus image and the like, and a mounting surface 5 as a mounting unit for mounting the support 2 are provided on the opposite side of the main body 1 of the eyepiece tube unit 3. .

  Further, as shown in FIG. 2, the apparatus main body 1 includes a laser scanning optical system 200 as an observation photographing optical system for observing and photographing the fundus, a control for controlling the laser scanning optical system 200 and other operations. A circuit unit 30 and the like are provided. Details of these will be described later. Although not shown, the apparatus main body 1 is further provided with a power supply for supplying power to each unit, a drive mechanism necessary for fundus observation photographing, a power button for power on / off, and the like. The power source may be a battery exchange type built-in type or a rechargeable type.

  The support 2 includes a gripping unit 6 that an examiner A who operates the optical scanning ophthalmoscope 100 grips with fingers and palms, an operation button 7 as an operation unit that gives a processing instruction to the apparatus main body 1, and the apparatus main body 1. And a support portion 8 as a mounted portion to be mounted on the mounting surface 5. The support unit 8 and the mounting surface 5 also function as a position setting unit 10 that rotates the apparatus main body 1 relative to the support 2 and changes the position of the laser scanning optical system 200 with respect to the support 2. To do.

  As shown in FIG. 1, the grip portion 6 is configured to be positioned in front of the apparatus main body 1 when the optical scanning ophthalmoscope 100 is disposed in a normal use state. And it has a simple structure in which a quadrangular prism is projected downward from the apparatus main body 1. In addition, the holding part 6 is not limited to the structure of Example 1, and as another different embodiment, for example, it may be formed in a cylindrical shape so that it can be easily held by a palm, and a finger can be easily arranged. As described above, finger-shaped irregularities or the like may be provided on the surface of the grip portion 6. As long as it is a shape that the examiner A can easily grip, the grip portion 6 having any other shape may be used.

  In the first embodiment and the subsequent embodiments, an operation button 7 is provided as an operation unit, and a push button format is adopted. By pressing the operation button 7, an instruction to perform various operations during fundus photographing using the optical system, such as alignment, fundus photographing, and focusing, is given, and an instruction to stop the operation is given. In the first embodiment, as shown in FIGS. 1 to 7, only one operation button 7 is illustrated, and all operations are performed by this one operation button 7. However, the present application is not limited to this, and a plurality of operation buttons such as a photographing button, an alignment button, and a focusing button may be provided for each process. Further, the operation unit is not limited to the push button, and any other form such as a trigger form may be used as long as it is easy for the examiner A to operate.

  Further, any conventionally known means may be used as a means for transmitting commands such as observation, photographing, alignment, and focusing from the operation button 7 of the support 2 to the control circuit unit 30 of the apparatus body 1. For example, it may be transmitted by a wireless electrical signal or the like, or may be transmitted by a code (not shown) or the like. Further, a mechanical transmission means using a cam or a link may be used. The same applies to the following embodiments.

  The support portion 8 is formed in a plate shape extending from the upper end of the grip portion 6 along the bottom surface of the apparatus main body 1 in the direction perpendicular to the grip portion 6, and is formed integrally with the grip portion 6. With the configuration of the grip portion 6 and the support portion 8 as described above, the side surface of the support body 2 is L-shaped as shown in FIG. In addition, the support part 8 is not limited to plate shape, It is good also as a shape which has a curved surface etc. corresponding to these shapes so that it may mount on the back of a hand or an upper arm easily.

  The support portion 8 is provided with a magnet member (not shown). The support portion 8 is attached to the attachment surface 5 of the apparatus main body 1 by the attractive force of the magnet member. Thereby, the apparatus main body 1 and the support body 2 are connected. The mounting surface 5 of the apparatus main body 1 is formed by providing a magnetic member that is attracted to the magnet member on the lower surface of the apparatus main body 1. The magnetic member is provided on the entire lower surface of the apparatus main body 1 or at least a portion where the support 2 is mounted. Alternatively, the housing of the apparatus main body 1 may be formed of a magnetic member such as a magnetic metal so that the support portion 8 can be mounted on any of the upper, lower, left, and right surfaces.

  When the examiner A performs an ophthalmic examination of the examinee B, as shown in FIGS. 5A and 5B, the eyepiece tube portion 3 is positioned in the gripping portion 6 side, The support body 2 is attached to the apparatus main body 1. Further, when the examiner A performs his own ophthalmic examination, as shown in FIGS. 7A and 7B, the grip portion 6 is positioned on the monitor portion 4 side opposite to the eyepiece tube portion 3. The support 2 and the apparatus main body 1 are mounted in such a direction. In this way, by changing the mounting direction of the support portion 8 with respect to the mounting surface 5, the function as the position setting portion 10 that changes the position of the eyepiece tube portion 3 with respect to the examiner A from 0 ° to 180 ° is exhibited. be able to. In the first embodiment, the mounting position of the support portion 8 in the left-right direction is located to the right of the center of the apparatus main body 1 in any case, but if the operation is easy for the examiner A, the apparatus main body 1 The support portion 8 may be mounted at any position on the left and right sides.

  Further, the support unit 8 has not only a function as a connection unit and a position setting unit between the apparatus main body 1 and the support 2 but also a function as a support unit of the optical scanning ophthalmoscope 100. That is, when the examiner A holds the optical scanning ophthalmoscope 100 and grasps the grasping portion 6, the support portion 8 is disposed on the back of the examiner A's hand or the upper surface of the arm, thereby reducing the weight of the apparatus main body 1. Can be supported with arms. In this way, by supporting the apparatus main body 1 with the arm, the stability when held by hand is improved, camera shake and the like are suppressed, and the fundus observation and photographing with the optical scanning ophthalmoscope 100 can be performed with higher accuracy. Can be done.

  In addition, the mounting surface 5 and the support portion 8 as the mounting portion and the mounted portion of the present application are not limited to the above, and the magnet member may be provided on the mounting surface 5 and the magnetic member may be provided on the support portion 8. . Moreover, you may provide a positive and negative magnet member in the support part 8 and the mounting surface 5, respectively, and can obtain a stronger attraction force. Further, the mounting part and the mounted part are not limited to the mounting surface 5 and the support part 8, and the apparatus body 1 is provided with irregularities and rail members corresponding to the shape of the support part 8 to provide the mounting part. The support portion 8 may be fitted and mounted on the mounting portion formed of the unevenness or rail. Even in this case, the function as the position setting unit 10 can be exhibited by mounting the mounting unit while changing the mounting direction of the support unit 8.

  Further, the apparatus main body 1 may be provided with a forehead support 9 on the upper part of the eyepiece tube 3 as shown by a dotted line in FIGS. 5 and 6. When using the optical scanning ophthalmoscope 100, the subject B (or the examiner A himself) applies a forehead to the forehead support 9 so that the eyepiece tube portion 3 faces the eye E to be examined. Can be arranged. Furthermore, the head of the subject B can be fixed with respect to the apparatus main body 1, and camera shake or the like can be suppressed and high-accuracy imaging can be performed. In addition, by providing the forehead support 9 with dents along the curve of the forehead at two places on the left and right when viewed from the eyepiece tube unit 3, if the forehead is applied to the dent on the right side, the left eye can be inspected. The right eye can be inspected by placing the forehead on the left side. Thus, the forehead support 9 also has a function of aligning the eye E to be examined.

(Outline of laser scanning optical system and control circuit of optical scanning ophthalmoscope)
Next, the laser scanning optical system 200 and the control circuit unit 30 used in Example 1 and the following examples will be described with reference to FIG. The optical system and the control circuit unit of the present application are not limited to these, and appropriate ones can be used according to the inspection purpose and design. As shown in FIG. 2, the laser scanning optical system 200 includes an illumination light source unit 20 that emits illumination light from an illumination light source, and a light receiving unit 21 that receives light from the eye E to be examined.

  The illumination light source unit 20 includes an infrared light source 20a as an illumination light source that irradiates infrared light, a blue light source 20b as an illumination light source that generates blue light (hereinafter referred to as “B light”), and green light (hereinafter referred to as “light”). , Referred to as "G light"), and a red light source 20r as an illumination light source that generates red light (hereinafter referred to as "R light"). . Lasers are used for these light sources.

  Infrared light Pa emitted from the infrared light source 20a is condensed by the condensing lens 20a ′ and guided to the reflection mirror 20a ″. B light emitted from the blue light source 20b is obtained by the condensing lens 20b ′. The light is condensed and guided to the dichroic mirror 20b ″. The G light emitted from the green light source 20g is condensed by the condenser lens 20g ′ and guided to the dichroic mirror 20g ″. The R light emitted from the red light source 20r is condensed by the condenser lens 20r ′. Then, it is guided to the dichroic mirror 20r ″.

  The dichroic mirror 20b ″ functions to transmit infrared light Pa and reflect B light. The dichroic mirror 20g ″ functions to transmit infrared light Pa and B light and reflect G light. The dichroic mirror 20r ″ functions to transmit R light and reflect G light, B light, and infrared light Pa.

  Infrared light Pa, B light, G light, and R light have their illumination light paths synthesized by reflection mirrors 20a ″, dichroic mirrors 20b ″, 20g ″, and 20r ″, and are guided to a beam splitter 22. And is guided to, for example, a MEMS mirror 23 as a biaxial scanner (scanner).

  The infrared light Pa, B light, G light, and R light are guided by the MEMS mirror 23 to the relay lens 24 while being scanned in a two-dimensional direction, and spotted on a surface Er ′ conjugate with the fundus Er of the eye E to be examined. It is imaged in the air as light.

  The spot light imaged on the surface Er ′ conjugate with the fundus Er is condensed by the objective lens 25 as a focusing lens, guided into the eye through the pupil Ep and the crystalline lens Ec of the eye E, and the surface Er. An image is formed as the spot light Sp on the conjugate surface Er ″ of the fundus Er conjugate with “′.

  In the first embodiment and the following embodiments, the objective lens 25 is provided in the eyepiece tube portion 3 so as to be movable back and forth in the axial direction by manual operation. When the annular ring member (not shown) of the eyepiece tube portion 3 is rotated according to the refractive power of the eye E, the objective lens 25 moves back and forth in the optical axis direction. As a result, the conjugate plane Er ″ matches the fundus Er, and a clear spot light is formed on the fundus Er.

  The fundus Er is scanned by the two-dimensional scanning by the MEMS mirror 23. Further, the spot reflected light from the fundus Er is guided to the objective lens 25 through the crystalline lens Ec and the pupil Ep, and is once imaged in the air on a plane Er 'conjugate with the fundus Er. Thereafter, the spot reflected light is collected by the relay lens 24 and guided to the beam splitter 22 via the MEMS mirror 23. The spot reflected light reflected by the beam splitter 22 is guided to the light receiving unit 21.

  The light receiving unit 21 reflects the R light and transmits the G light, the B light, and the infrared light Pa. The dichroic mirror 21r ″ reflects the G light, and transmits the B light and the infrared light Pa. In addition, a dichroic mirror 21b ″ that reflects the B light and transmits the infrared light Pa is provided.

  An imaging lens 21r ′ is provided in front of the reflecting direction of the dichroic mirror 21r ″, and the R light is spot-imaged on the PD sensor 21r as an image receiving element by the imaging lens 21r ′. The dichroic mirror 21g. An imaging lens 21g ′ is provided in front of the reflection direction of “”, and the G light is imaged in a spot shape on the PD sensor 21g as an image receiving element by the imaging lens 21g ′. An imaging lens 21b ′ is provided in front of the reflection direction of the dichroic mirror 21b ″, and the G light is imaged in a spot shape on a PD sensor 21b as an image receiving element by the imaging lens 21b ′. An imaging lens 21a ′ is provided behind the reflection direction of “,” and the G light is imaged in a spot shape on the PD sensor 21a as an image receiving element by the imaging lens 21a ′.

  Light reception signals from the PD sensors 21a, 21b, 21g, and 21r are input to the fundus image construction unit 33 described later. The PD sensor 21a has sensitivity in the infrared region, the PD sensor 21b has sensitivity in the blue wavelength region, the PD sensor 21g has sensitivity in the green wavelength region, and the PD sensor 21r has sensitivity in the red wavelength region. Have

  The laser scanning optical system 200 as described above is provided in a movable case (not shown) or the like and housed inside the apparatus main body 1. Then, the movable case is driven in the front-rear, up-down, left-right direction with respect to the apparatus main body 1 by a drive mechanism (not shown), thereby performing alignment, focusing, etc. of the laser scanning optical system 200 with respect to the eye E. .

  In addition, the above-described control circuit unit 30 is provided inside the apparatus main body 1. The control circuit unit 30 controls the operations of the laser scanning optical system 200 and the drive mechanism in accordance with an instruction from the examiner A by the operation of pressing the operation button 7, constructs an image of the fundus oculi Er, and displays it on the monitor unit 4. For example, the entire optical scanning ophthalmoscope 100 is controlled. The control circuit unit 30 includes a CPU (Central Processing Unit) that executes various operations and drive control of each unit, a ROM (Read Only Memory) that stores fixed data such as a computer program in advance, and a work that stores various data in a rewritable manner. Hardware such as RAM (Random Access Memory) that functions as an area or the like is provided.

  As shown in FIG. 2, the control circuit unit 30 includes an optical control circuit unit 31, a lighting control circuit unit 32, a fundus image construction unit 33, and the like. The optical control circuit unit 31 controls the operation of the laser scanning optical system 200. The alignment adjustment process of the apparatus main body 1 for the eye E, the focus adjustment process for the fundus Er of the eye E, and the observation of the fundus Er Processing, fundus Er imaging processing, and the like are executed. The lighting control circuit unit 32 controls the illumination light source unit 20 to irradiate infrared light, B light, R light, and G light according to each process. The fundus image constructing unit 33 constructs a fundus image based on the signal input from the light receiving unit 21 and displays and stores the fundus image on the monitor unit 4.

  Hereinafter, an operation in the observation mode and the imaging mode of the optical scanning ophthalmoscope 100 for the eye E using the laser scanning optical system 200 and the control circuit unit 30 as described above will be described. Although explanation is omitted, when observation or photographing is performed, alignment adjustment or focus adjustment of the laser scanning optical system 200 is performed. For example, the alignment adjustment is performed by moving the entire laser scanning optical system 200 up and down and left and right together with the movable case based on the light reception result of the light receiving unit 21. The focus adjustment is performed by moving the entire laser scanning optical system 200 back and forth based on the light reception result or by adjusting the positions of the objective lens 25 and the relay lens 24.

(In observation mode)
When the optical scanning ophthalmoscope 100 enters the observation mode by the operation of the operation button 7 by the examiner A, the infrared light source 20a of the illumination light source unit 20 is turned on under the control of the lighting control circuit unit 32. Thereby, spot light which is infrared light is formed on the fundus Er of the eye E.

  The MEMS mirror 23 scans the fundus Er in a predetermined range under the control of the optical control circuit unit 31. Spot reflected light from the fundus Er generated by this scanning is received by the infrared sensor PD sensor 21a. The light reception signal from the PD sensor 21 a is input to the fundus image construction unit 33.

  The fundus image constructing unit 33 constructs a fundus image for fundus observation based on the received light signal, and outputs the image signal toward the monitor unit 4. Thereby, the fundus image EGr is displayed on the liquid crystal display screen of the monitor unit 4. The examiner A operates the operation button 7 while observing the fundus image EGr for fundus observation, so that the optical scanning ophthalmoscope 100 shifts to the photographing mode.

(In shooting mode)
In the photographing mode, the blue light source 20b, the green light source 20g, and the red light source 20r of the illumination light source unit 20 are simultaneously turned on under the control of the lighting control circuit unit 32. The lighting time is, for example, 100 milliseconds. During the lighting time of the blue light source 20b, the green light source 20g, and the red light source 20r, the MEMS mirror 23 is driven so as to draw the same scanning locus as that when constructing the fundus image for observation.

  As a result, similarly to the observation, the fundus Er is scanned with white spot light that is visible light. The reflected light is received by the PD sensors 21 b, 21 g, and 21 r, and photographing is performed, and each light reception signal that is a result of the photographing is input to the fundus image construction unit 33.

  The fundus image constructing unit 33 constructs a color fundus image based on the light reception signals from the PD sensors 21b, 21g, and 21r. This fundus image is stored as a color image in a built-in memory unit or the like. In addition, a reproduction button (not shown) may be provided on the apparatus main body 1, and a color fundus image may be displayed on the monitor unit 4 by operating the reproduction button, or simultaneously with photographing through a telephone line or the like. The fundus image may be automatically transmitted to the medical institution.

  When the examiner A performs fundus photographing of the eye E of the subject B using the optical scanning ophthalmoscope 100 of Example 1 configured as described above, and the examiner A has his own subject. The operation when photographing the fundus of the optometry E will be described below with reference to the drawings. In this specification, when the examiner A performs fundus imaging of the subject B is referred to as “other person imaging mode”, and includes the case where the examiner A (the subject B himself / herself becomes the examiner A). ) Performing own fundus photographing is called “self-photographing mode”.

(Others shooting mode)
When the examiner A performs fundus imaging of the subject B (other person), as shown in FIG. 5B, the eyepiece tube portion 3 side is positioned on the gripping portion 6 side of the support 2, The apparatus main body 1 and the support body 2 are attached. In this state, when the examiner A grasps the grasping portion 6 from the rear side with his / her palm, the operation button 7 is in the same direction as the eyepiece tube portion 3, that is, the direction facing the subject B as shown in FIG. (Forward). Further, the support portion 8 is disposed so as to extend from the grip portion 6 in a direction (backward) facing the examiner A.

  Further, when the examiner A grips the grip portion 6 in this way, the operation button 7 is arranged at the position of the index finger or the like. Therefore, it is possible to easily press the operation button 7 with the index finger while firmly holding the grip portion 6 with a finger or palm. Then, when the examiner A holds the optical scanning ophthalmoscope 100 from the front with respect to the subject eye E of the subject B and puts it on the forehead of the subject B on the forehead support 9, the subject's eye of the subject B is examined. The eyepiece tube portion 3 is arranged close to E (see FIG. 3). In addition, since the examiner A holds the optical scanning ophthalmoscope 100 in this way, the support portion 8 comes into contact with the back of the examiner A's hand or the upper surface of the upper arm. It can be carried out.

  Next, when the examiner A presses the operation button 7 with an index finger or the like, fundus imaging by the laser scanning optical system 200 is started. The examiner A can operate the operation button 7 in a state where the grasping portion 6 is stably grasped by the finger other than the index finger and the entire palm. In the laser scanning optical system 200, the fundus photographing of the subject B can be performed by the optical operation as described above. As described above, by using the hand-held optical scanning ophthalmoscope 100 according to the first embodiment, the examiner A can easily and easily shoot the fundus of the subject B.

(Self-shooting mode)
Next, the self-photographing mode will be described. First, an operation when switching from the other person photographing mode as shown in FIG. 6 to the self photographing mode will be described. In the positional relationship between the apparatus main body 1 and the support 2 in the other person photographing mode, when the eyepiece tube portion 3 is brought close to the eye E of the examiner A himself, the operation button 7 of the grasping portion 6 is moved to the examiner A. It arrange | positions toward the direction (front) which faces, and the support part 8 is arrange | positioned toward the direction (back) opposite to the examiner A. Therefore, if the grip part 6 is gripped, the support part 8 cannot be supported by the upper arm. In addition, the examiner A operates the operation button 7 with the thumb away from the grip portion 6, and the stability of the optical scanning ophthalmoscope 100 at the time of photographing is lowered, and smooth photographing may not be performed. Or the wrist is bent, the grasping portion 6 is grasped from the back side of the operation button 7, and the operation button 7 is operated with an index finger or the like.

  Therefore, in order to perform self-photographing easily and stably, in the first embodiment, the optical scanning ophthalmoscope 100 is provided with the position setting unit 10 as described above. In order to switch to the self-photographing mode, first, as shown in FIG. 6, the examiner A detaches the support portion 8 of the support 2 from the mounting surface 5 of the apparatus main body 1, and the apparatus main body 1 and the support 2. And isolate. Next, the apparatus main body 1 is rotated by 180 ° with the rotation axis X being an axis that intersects the optical axis L of the laser scanning optical system 200 and is parallel to the protruding direction (vertical direction) of the grip 6. In the first embodiment, for example, as shown in FIGS. 5 to 7, the axis passing through the position where the center of the support portion 8 and the optical axis L intersect is the rotation axis X. However, it is only necessary that the apparatus main body 1 or the support body 2 can be rotated 180 ° in the horizontal direction in the separated state, and the position where the center of the support portion 8 and the optical axis L intersect does not necessarily have to be the rotation axis. . In this state, the support portion 8 is mounted on the mounting surface 5 while being rotated 180 ° from the initial position, and the apparatus main body 1 and the support body 2 are connected.

  When the examiner A grasps the grasping portion 6 with fingers or palm by the above operation, the support portion 8 is disposed above the arm of the examiner A, and the index finger of the examiner A is disposed on the operation button 7 (FIG. 4). Moreover, as shown in each figure of FIG. 4, FIG. 7, the eyepiece cylinder part 3 is arrange | positioned toward the direction (back) which faces the examiner A. FIG. Further, since the support portion 8 is disposed above the upper arm of the examiner A, the examiner A can support the weight of the apparatus main body 1 with the back of the hand or the upper arm even in the self-photographing mode. Also in this case, since the support body 2 is positioned on the right side of the apparatus main body 1, the apparatus main body 1 is positioned on the right hand side of the examiner A. Therefore, not only the support portion 8 but also the lower surface of the apparatus body 1 hits the right arm of the examiner A, and the weight of the apparatus body 1 can be easily supported by the right arm. When the examiner A operates with the left hand, the mounting position of the support portion 8 on the apparatus main body 1 may be changed.

  Then, when the examiner A presses the operation button 7 with an index finger or the like while holding the optical scanning ophthalmoscope 100 with respect to his / her eye E, the laser scanning optical system 200 can capture a fundus image. Done. Further, when switching from the self-photographing mode to the other-person photographing mode again, the apparatus main body 1 and the support body 2 are separated, the apparatus main body 1 is rotated by 180 ° with respect to the support body 2, and then the apparatus main body 1 and By simply connecting the support 2 to each other, the mode can be easily switched.

  As described above, in the optical scanning ophthalmoscope 100 according to the first embodiment, the relative position between the apparatus main body 1 and the support body 2 (only by attaching / detaching the support portion 8 of the support body 2 to the mounting surface 5 of the apparatus main body 1). In other words, the relative position of the optical system with respect to the examiner A) can be changed to switch between the other person photographing mode and the self photographing mode. Therefore, the examiner A stably operates the operation button 7 by grasping the grip 6 in both the other person photographing mode for photographing the fundus of the subject B and the self photographing mode for photographing his own fundus. Operability is improved. Further, by supporting the own weight of the apparatus main body 1 with the upper arm via the support portion 8, the stability of the apparatus main body 1 is improved, and camera shake and the like can be suppressed. Therefore, in the optical scanning ophthalmoscope 100 according to the first embodiment, more accurate fundus photographing can be performed in both the other person photographing mode and the self photographing mode, and the optical performance is improved.

(Example 2)
Hereinafter, the hand-held optical scanning ophthalmoscope of Example 2 will be described with reference to FIG. The optical scanning ophthalmoscope 110 according to the second embodiment has the same basic configuration as the optical scanning ophthalmoscope according to the first embodiment except that the position setting unit 10 is changed to a position setting unit using a shaft support described later. ing. Therefore, the same code | symbol is attached | subjected to the member similar to Example 1, and detailed description is abbreviate | omitted. FIGS. 8A and 8B show changes when the optical scanning ophthalmoscope 110 according to the second embodiment is rotated. FIG. 8A shows an initial state (other person photographing mode), and FIG. 8B shows an initial state. FIG. 8C shows a state rotated by 90 ° counterclockwise (second other photographing mode), and FIG. 8C shows a state rotated by 180 ° from the initial state (self-photographing mode).

  As shown in FIGS. 8A and 8B, the optical scanning ophthalmoscope 110 according to the second embodiment includes an apparatus main body 1 including a laser scanning optical system and a control circuit unit similar to those in the first embodiment, an operation button 7, and a grip. And a support body 2 provided with a portion 6, a support portion 8 and the like. In the first embodiment, the apparatus main body 1 and the support body 2 are formed so as to be separable, and the mounting direction of the support section 8 on the mounting surface 5 is changed, whereby the eyepiece tube section 3 of the apparatus main body 1 with respect to the support body 2 is changed. A position setting unit 10 for changing the position is configured.

  On the other hand, in the second embodiment, the apparatus main body 1 and the support body 2 are rotatably supported by a support shaft (rotary shaft member) arranged coaxially with the rotation axis X orthogonal to the optical axis L. (Hereinafter referred to as “shaft support 11”). The shaft support portion 11 constitutes the position setting portion 10. That is, the position of the eyepiece tube portion 3 (optical system) relative to the examiner A is changed by relatively rotating the apparatus main body 1 and the support body 2 with the shaft support portion 11 as a fulcrum (rotation axis). Yes. 8, the shaft support portion 11 is represented by a solid line. However, since the shaft support portion 11 is actually provided between the lower surface of the apparatus body 1 and the upper surface of the support body 2, , Is not visible.

  In the first embodiment, the apparatus main body 1 can be rotated 180 ° in the horizontal direction with respect to the support 2. On the other hand, in the second embodiment, the apparatus main body 1 is configured to rotate at an angle of 90 ° or 180 ° in the horizontal direction with respect to the support 2 so that photographing at various angles is possible. ing. As described above, since photographing at a 90 ° position (left and right sides) is possible, it is not necessary for the examiner A to photograph from the front of the subject B, and the fundus photographing of the subject B by the examiner A is performed. The degree of freedom can be further increased.

  Further, after the position is set by rotating 90 ° or 180 ° in this manner, a locking means or the like may be provided so that the apparatus main body 1 does not rotate with respect to the support 2 unnecessarily. For example, a protrusion that protrudes up and down is provided on the lower surface of the apparatus main body 1, and when the support 2 is rotated, the protrusion is retracted so that the rotation movement is not hindered. Then, when the rotational movement is completed, the protrusion protrudes and engages with the support 2 so as to exhibit the function of stopping rotation. Alternatively, mutual rotation may be suppressed by using frictional force between the apparatus main body 1 and the support body 2 or fixing means such as a magnet member when the position is not set.

  In the normal other person photographing mode in which the examiner A and the subject B face each other and photograph with the optical scanning ophthalmoscope 110 of Example 2 configured as described above, FIG. ), The eyepiece tube 3 is disposed in front of the subject B. In this state, the examiner A holds the grasping unit 6 and holds the optical scanning ophthalmoscope 110 with respect to the eye E of the subject B from the front of the subject B. The fundus photographing of the person B can be performed with good operability.

  Next, the second other person shooting mode will be described. In the state of FIG. 8 (a), the apparatus body 1 is rotated 90 ° counterclockwise with respect to the support 2 with the shaft support 11 as the rotation axis X, as shown in FIG. 8 (b). The position is set so that the eyeglass tube section 3 faces rightward. With this arrangement, when the examiner A grasps the grasping portion 6, the eyepiece tube portion 3 is arranged facing the examiner A in the lateral direction (left side of the examiner A). . Therefore, the examiner A can perform fundus photography without changing his / her posture on the subject B who is not on the front but on the left side. Further, it is not necessary for the patient sitting on the bed or the like to get on the bed and to set up the optical scanning ophthalmoscope 110 from above the patient, and light is applied to the patient's eye E from the side of the bed. The scanning ophthalmoscope 110 can be easily set up. Further, even if the apparatus main body 1 is disposed sideways with respect to the examiner A as described above, the orientation of the support 2 with respect to the examiner A does not change. Therefore, the operation button 7 is disposed at a position (the position of the index finger) that is easy to be operated by the examiner A when the grasping portion 6 is grasped, and fundus photographing can be performed with good operability.

  Then, the apparatus main body 1 is further rotated, and the position of the apparatus main body 1 is arranged at a position 180 ° from the initial position, as shown in FIG. By this operation, the eyepiece tube portion 3 is arranged on the side opposite to the grip portion 6, that is, facing the direction facing the examiner A (rearward). Therefore, the examiner A (or the examinee B himself / herself) can easily perform his / her own fundus photography (self-photographing mode).

  In addition, in Example 2 shown in FIG. 8, although it has comprised so that it may rotate at the angle of 90 degrees and 180 degrees, this application is not limited to this. For example, the position of the apparatus main body 1 may be set to 120 ° (90 ° clockwise) with respect to the support 2 so that fundus photographing or the like can be performed. Furthermore, the apparatus main body 1 may be freely rotated in the 360 ° direction so that the position can be set at a desired angle, and the degree of freedom during fundus photography and other ophthalmic examinations can be further improved.

  Further, in the second embodiment, the apparatus main body 1 and the support body 2 are relatively revised by the shaft support portion 11 using the support shaft. However, the present application is not limited to this, and the gear and other rotations are performed. You may comprise so that it may rotate using a mechanism etc. The same applies to the shaft support portions of the following embodiments.

(Example 3)
Hereinafter, the optical scanning ophthalmoscope of Example 3 will be described with reference to FIGS. In the third embodiment, the same members as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 9, the optical scanning ophthalmoscope 120 according to the third embodiment includes an apparatus main body 1 including a laser scanning optical system and a control circuit unit similar to those in the first embodiment, an operation button 7, a gripping unit 6, And a support body 2 provided with a support portion 8 and the like.

  As shown in FIGS. 9 and 10, the apparatus main body 1 according to the third embodiment includes a substrate portion 1a, a pair of arm portions 1b formed to protrude upward on both sides of the substrate portion 1a, and the pair. The arm portion 1b includes a movable body 12 that is rotatably supported via a pair of shaft support portions 13. The movable body 12 is provided with a laser scanning optical system and an eyepiece tube portion 3. Further, as shown in FIG. 9A, FIG. 10A, etc., the pair of shaft support portions 13 has an axis X (vertical in the horizontal direction (left-right direction) with respect to the optical axis L of the laser scanning optical system. It is arranged coaxially with the rotation axis X). Therefore, the movable body 12 is rotatable in the front-rear direction with respect to the apparatus main body 1 with the shaft support portion 13 as a rotation axis. In the third embodiment, the position setting unit 10 that changes the position of the eyepiece tube unit 3 (laser scanning optical system) with respect to the examiner A is configured by the shaft support unit 13 and the like.

  In the first and second embodiments, the entire apparatus body 1 is rotated relative to the support 2. On the other hand, in the third embodiment, the position of the eyepiece tube portion 3 with respect to the examiner A is changed by rotating the movable body 12 with respect to the apparatus main body 1, so that the apparatus with respect to the support body 2 is changed. It is not necessary to form the entire main body 1 to be rotatable. The support portion 8 of the support body 2 and the apparatus main body 1 are integrally connected so as not to be separated by connection means such as an adhesive or a screw, thereby improving the stability of each other. Also in the third embodiment, a monitor unit 4 or the like for displaying a fundus image or the like may be provided on the upper surface or the like of the substrate unit 1a. Since the substrate unit 1a does not rotate, the monitor unit 4 and the like can be arranged at a position facing the examiner A in both the other person photographing mode and the self photographing mode.

  When performing the other person photographing mode with the optical scanning ophthalmoscope 120 of Example 3 configured as described above, the position of the movable body 12 is adjusted as shown in each drawing of FIG. The cylinder portion 3 is arranged so as to face the same direction as the operation button 7 faces. In this state, when the examiner A grasps the grasping portion 6 from the back side (rear side) of the operation button 7, the support portion 8 is arranged on the upper arm of the examiner A with the finger placed on the operation button 7. . Further, the eyepiece tube 3 is arranged in the direction opposite to the examiner A, that is, in the direction facing the subject B (front). Then, when the examiner A holds the optical scanning ophthalmoscope 120 close to the eye E of the subject B and presses the operation button 7, the fundus photographing of the subject B can be easily performed. .

  Further, when switching from the other person photographing mode to the self photographing mode, as shown in each drawing of FIG. 10, the movable body 12 faces the examiner A with respect to the apparatus body 1 with the shaft support portion 13 as the rotation axis X. Rotate in the direction (backward). In Example 3, the movable body 12 is rotated about 135 ° from the initial position of FIG. Accordingly, as shown in FIG. 10C, the eyepiece tube portion 3 is disposed so as to be inclined obliquely upward with respect to the direction (backward) facing the examiner A.

  Therefore, the examiner A does not need to raise the optical scanning ophthalmoscope 120 to the position of the line of sight and perform fundus photography, and the upper arm can easily hit the support portion 8 and can easily support the weight of the apparatus main body 1. . Therefore, fundus photographing in the self-photographing mode can be easily performed with good operability. Furthermore, the eyepiece tube part 3 does not protrude greatly toward the monitor part 4 side, and the visual recognition of the monitor part 4 is not hindered. Of course, you may comprise so that the movable body 12 may be rotated to the position of 180 degrees, and the movable body 12 can be rotated at an appropriate angle according to the positional relationship of each part, a purpose of use, etc. Further, although the number of parts and assembly man-hours of the apparatus main body 1 are increased, it is not necessary to rotate the entire apparatus main body 1 at the time of position setting, and the position setting can be easily performed with little effort.

  In the first to third embodiments, the hand-held optical scanning ophthalmoscope is used. However, as a modification, the optical scanning ophthalmoscope according to the first to third embodiments is placed on an appropriate stationary table, and the stationary optical scanning ophthalmoscope is installed. It is good also as a structure which can be used also as a type of optical scanning ophthalmoscope. With such a configuration, it is usually possible to perform more reliable fundus imaging as a stationary type, and it can be removed from the stationary table and used as a hand-held optical scanning ophthalmoscope. High fundus photography is possible. In particular, in Example 1, since the support body 2 and the apparatus main body 1 can be separated, in a state in which the support body 2 for hand-holding is detached, it is configured to be mounted on a stationary table equipped with operation buttons. In any case, it can be used with good operability. As described above, it is possible to provide an ophthalmologic apparatus having both hand-held ease of use and high degree of freedom, and stationary type reliability. The operation button 7 is not necessarily provided on the support 2 and may be provided on the apparatus main body 1 as long as the examiner A can easily operate the operation button 7.

Example 4
(Appearance structure and action of stationary optical scanning ophthalmoscope)
Hereinafter, the stationary optical scanning ophthalmoscope of Example 4 will be described with reference to FIGS. 11 and 12. In the fourth embodiment, members similar to those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in each of FIGS. 11 and 12, the optical scanning ophthalmoscope 130 according to the fourth embodiment includes an apparatus main body 1 having a laser scanning optical system, a control circuit unit, and the like, an operation button 7, and a gripping unit 6. And a support body 2 provided.

  In the third embodiment, the movable body 12 formed separately from the apparatus main body 1 is pivotally supported on the apparatus main body 1. However, in the fourth embodiment, the apparatus main body 1 itself is pivotally supported on the support body 2 so as to be rotatable. doing. In the first to third embodiments, a hand-held optical scanning ophthalmoscope is provided by providing the grip 6 on the support 2. However, in the fourth embodiment, the support 2 is set on a surface such as a desk. A stationary optical scanning ophthalmoscope 140 is provided by providing the stationary table 14.

  The apparatus main body 1 of Example 4 includes a laser scanning optical system and a control circuit unit, and includes an eyepiece tube unit 3. The apparatus main body 1 has a pair of arm portions 1b projecting from both sides, and the pair of arm portions 1b is pivotally supported on the support 2 via a pair of support shafts (shaft support portions 13). The pair of shaft support portions 13 are coaxial with an axis X (rotation axis X) orthogonal to the horizontal direction (left-right direction) with respect to the optical axis L of the laser scanning optical system, as shown in FIGS. Is placed on top. Therefore, the apparatus main body 1 is rotatable with respect to the support body 2 with the shaft support portion 13 as a rotation axis. In the fourth embodiment, the position setting unit 10 that changes the position of the eyepiece tube unit 3 (laser scanning optical system) with respect to the examiner A is configured by the shaft support unit 13 and the like.

  In the fourth embodiment, the operation button 7 is provided on the upper surface of the support 2. In addition, the monitor unit and the like may be provided in the apparatus main body 1, but in order to rotate the entire apparatus main body 1, if it is provided behind the support body 2 (position facing the examiner A), the examiner A can easily Can be visually recognized.

  In the optical scanning ophthalmoscope 130 of Example 4 configured as described above, in the other person photographing mode, as shown in FIG. 11C and the like, the eyepiece tube portion 3 is in front. It is arranged toward the direction of person B. Moreover, when the monitor part etc. are provided, these are arrange | positioned toward the examiner A direction. In this state, the subject B brings the subject's eye E close to the eyepiece tube portion 3 and the examiner A presses the operation button 7, whereby the fundus photographing of the subject B can be performed. In addition, the examiner A can perform an operation while confirming a photographed image of the subject B on the monitor unit or the like.

  Next, when switching to the self-photographing mode, the apparatus main body 1 is rotated in the direction of the examiner A with respect to the support 2 with the shaft support 13 as the rotation axis X. By this operation, as shown in each drawing of FIG. 12, the eyepiece tube portion 3 is arranged in the direction (backward) facing the examiner A.

  Therefore, even if it is a stationary type, the examiner A does not have to bother to move to the position of the subject in the self-photographing mode, and can easily shoot his own fundus. Further, when switching to the other person photographing mode again, it is only necessary to rotate the apparatus main body 1 so that the eyepiece tube portion 3 is directed toward the subject B (front). Can be easily switched. In addition, since the support 2 is not rotated, when a monitor unit or the like is provided behind the support 2, they are arranged facing the direction of the examiner A (rear) even when the imaging mode is switched. . Therefore, the examiner A can easily view the fundus oculi image or the like on the monitor unit regardless of whether the image is taken by another person or by self-photographing. In addition, since the table 14 can be provided and the optical scanning ophthalmoscope 130 can be installed and used, stability can be improved and more accurate fundus photography can be performed without fear of camera shake or the like.

(Example 5)
Hereinafter, the stationary optical scanning ophthalmoscope of Example 5 will be described with reference to FIGS. The optical scanning ophthalmoscope 140 of the fifth embodiment has the same basic configuration as the optical scanning ophthalmoscope 130 of the fourth embodiment except that the operation button 7 is provided on the stationary table 14. Therefore, members similar to those in the fourth embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIGS. 12 and 13, the optical scanning ophthalmoscope 140 of Example 5 includes a laser scanning optical system, a control circuit unit, and the like, and the shaft support 13 is set as the rotation axis X with respect to the support 2. The apparatus includes a rotatable apparatus main body 1 and a support body 2 including an operation button 7 and a table 14. Also in the fifth embodiment, the position setting unit 10 that changes the position of the eyepiece tube unit 3 (laser scanning optical system) with respect to the examiner A is configured by the shaft support unit 13 and the like.

  In the fifth embodiment, the operation panel 15 is provided on the upper surface of the stationary table 14 behind the support body 2 (in the direction facing the examiner A), and the operation button 7 is provided on the operation panel 15. . By providing the operation button 7 on the side facing the examiner A in this way, the examiner A can easily press the operation button 7 during photographing. Also in Example 5, a monitor unit (not shown) or the like may be provided behind the support 2 (position facing the examiner A).

  In the optical scanning ophthalmoscope 130 of Example 5 configured as described above, in the other person photographing mode, as shown in FIG. It is arranged toward the direction of person B. Further, the operation panel 15 provided with the operation buttons 7, the monitor unit, and the like are arranged in a direction (backward) facing the examiner A. In this state, the subject B brings the subject's eye E close to the eyepiece tube portion 3 and the examiner A presses the operation button 7, whereby the fundus photographing of the subject B can be performed. In addition, the examiner A can perform an operation while confirming a photographed image of the subject B on the monitor unit or the like.

  Next, when switching from the other person photographing mode to the self photographing mode, the apparatus main body 1 is rotated in the direction of the examiner A with respect to the support 2 with the shaft support portion 13 as the rotation axis X. By this operation, as shown in each drawing of FIG. 14, the eyepiece tube portion 3 is arranged in the direction (backward) facing the examiner A. On the other hand, the operation panel 15 provided with the operation buttons 7, the monitor unit, and the like are arranged in the direction of the examiner A (rear) without changing the position.

  Therefore, the operation button 7 and the monitor unit can be arranged toward the examiner A in both the other person photographing mode and the self photographing mode. Therefore, the examiner A can easily perform his / her own fundus photographing by operating the operation buttons 7 with good operability. In addition, the examiner A can check the image after photographing by using the monitor unit or the like. Of course, also in Example 5, when the examiner A is in the self-photographing mode, there is no need to bother to the position of the subject B. Further, since the optical scanning ophthalmoscope 140 can be used in a stationary manner, the stability is improved, and more accurate fundus photography can be performed without fear of camera shake or the like.

  As mentioned above, although each Example was described, the ophthalmologic apparatus of this application is not limited to these. In each of the above embodiments, an optical scanning ophthalmoscope is implemented as an ophthalmologic apparatus, but the ophthalmologic apparatus of the present application is not limited to the optical scanning ophthalmoscope. As described in each embodiment, an ophthalmologic apparatus having another configuration may be used as long as the examiner can switch between the ophthalmic examination of the subject and the ophthalmic examination of the examiner himself.

A Tester B Tester E Test eye 1 Device body 2 Support 5 Mounting surface (mounting part)
6 Grasping part 7 Operation buttons (operation part)
8 Supporting part (attached part)
DESCRIPTION OF SYMBOLS 10 Position setting part 11 Axis support part 12 Movable body 13 Axis support part 14 Stationary table 100,110,120,130,140 Optical scanning ophthalmoscope (ophthalmologic apparatus)
200 Laser scanning optical system (optical system)

Claims (10)

An ophthalmologic apparatus comprising: an apparatus main body having at least an optical system that receives light from an eye to be examined illuminated by an illumination light source; and a support that supports the apparatus main body,
An operation unit that gives processing instructions to the apparatus main body is provided so as not to rotate with respect to the support.
By rotating the optical system relative to the support relative to an axis orthogonal to the optical axis of the optical system as a rotation axis, the position of the optical system relative to the support and the operation unit is changed. An ophthalmic apparatus characterized by that. An ophthalmologic apparatus comprising: an apparatus main body having at least an optical system that receives light from an eye to be examined illuminated by an illumination light source; and a support that supports the apparatus main body,
The apparatus main body and the support body are configured to be connected to each other by mounting a mounting portion provided on the apparatus main body and a mounted portion of the support body,
The apparatus main body and the support are separated by detaching the mounted portion of the support from the mounting portion of the apparatus main body, and the apparatus main body or the support is used as an optical axis of the optical system. The optical system is rotated relative to the support relative to the support by rotating relative to an orthogonal axis as a rotation axis and mounting the mounted portion on the mounting portion. , ophthalmologic apparatus characterized by changing the position of the optical system with respect to the support. An ophthalmologic apparatus comprising: an apparatus main body having at least an optical system that receives light from an eye to be examined illuminated by an illumination light source; and a support that supports the apparatus main body,
It said support body includes a grip portion examiner grips, when the front Symbol examiner grips the grip portion, disposed from the grip portion protrudes in the direction of the patient, on the upper surface of the arm of the examinee that the supporting part, further Yes,
The position of the optical system relative to the support is changed by rotating the optical system relative to the support with the axis orthogonal to the optical axis of the optical system as a rotation axis. ophthalmic device that. The optical system has an eyepiece disposed to face the eye of the subject,
By rotating the optical system in which the eyepiece is disposed in a direction facing the eye of the subject to be examined relatively around the rotation axis, the eyepiece of the optical system is detected. The ophthalmologic apparatus as described in any one of Claims 1-3 comprised so that it may oppose and arrange | position a person's eye to be examined. The apparatus main body and the support body are configured to be connected to each other by mounting a mounting portion provided on the apparatus main body and a mounted portion of the support body,
The apparatus main body and the support body are separated from each other by detaching the mounted portion of the support body from the mounting portion of the apparatus main body, and the apparatus main body or the support body is relative to the rotation axis. rotated manner by mounting the mating attachment section to the mounting section, the ophthalmologic apparatus according to claim 1 or 3 to change the position of the optical system with respect to the support. The apparatus main body and the support are pivotally supported with each other by a pivotal support portion composed of a pivotal shaft arranged coaxially with the rotating shaft,
As a rotational axis said support shaft, said by relatively rotating the device body relative to the support, according to claim 1 for changing the relative position of the optical system with respect to the support 3, 4 either the ophthalmic apparatus according to an item or. The optical system is pivotally supported on the apparatus main body by a pivotal support portion composed of a pivotal shaft arranged coaxially with the rotating shaft,
As the rotation axis the support shaft, by relatively rotating the optical system with respect to the apparatus main body, according to claim 1 for changing the position of the optical system with respect to the support, any one of 3, 4 An ophthalmic device according to claim 1. The ophthalmologic apparatus according to claim 1 , wherein the support has a grip portion that is held by an examiner. The support is, when the examiner grips the grip portion, according to claim 8 which protrude from the grip portion in the direction of the examiner, the supporting portion disposed on the upper surface of the arm of the subject, further comprising An ophthalmic device according to claim 1. The ophthalmic apparatus according to any one of claims 1 to 9 , wherein the support body includes a stationary base for placing the apparatus main body on an installation surface.