JP5677501B2 - Ophthalmic equipment - Google Patents

Description

  The present invention relates to an ophthalmologic apparatus that performs imaging by guiding and fixing a gaze of a subject using an internal fixation target.

  In order to have a fixation target inside the ophthalmologic apparatus and present it to the subject, the fixation target needs to be arranged in the vicinity of the fundus conjugate position of the eye to be examined.

  FIG. 9 shows a configuration diagram of a conventional general fundus camera. In the optical path from the halogen lamp 1 to the objective lens 2, a visible light cut filter 3, a diffusion plate 4, a xenon tube 5, a lens 6, a pupil diaphragm 7, a lens diaphragm 8, and a mirror 9 are sequentially arranged. In the reflection direction of the mirror 9, relay lenses 10 and 11, a corneal diaphragm 12, and a perforated mirror 13 are sequentially arranged. Further, behind the perforated mirror 13, an imaging stop 14, a focus lens 15, an imaging lens 16, a flip-up mirror 17 as an optical path branching unit, and an imaging element 18 are sequentially arranged. Further, a dichroic mirror 19 is disposed in the reflection direction of the flip-up mirror 17, and a finder 21 is provided via a lens 20 in the reflection direction of the dichroic mirror 19.

  There are three possible locations A, B, and C as the fundus conjugate positions in the above-described fundus camera. The position A is in the vicinity of the primary image formation plane by the objective lens 2 of the fundus Er of the eye E to be examined. The position B is branched by a dichroic mirror 19 having visible transmission characteristics and near-infrared reflection characteristics on the optical path branched by the focus lens 15, the imaging lens 16, and the flip-up mirror 17 in the photographing observation optical system. And the conjugate position. The position C is in the vicinity of the conjugate plane where the relay image is formed on the position A of the primary imaging plane by the relay lens 11 in the illumination optical system.

  In the case of the position A, the internal fixation target cannot be arranged in the illumination photographing light beam. Therefore, a dichroic mirror (not shown) that reflects the wavelength light of the internal fixation target is arranged and arranged on the reflected light path. become. The dichroic mirror needs to be retracted from the optical path at the time of photographing. However, since the position A is in the vicinity of the objective lens 2, it is not realistic to provide a mechanism for raising the dichroic mirror. In addition, a mechanism for driving the internal fixation target in the optical axis direction according to the diopter of the eye E is also required.

  Therefore, in general, the fixation target is provided at the position B in the fundus camera. In the fundus camera of Patent Document 1, an internal fixation target is disposed in the vicinity of the fundus conjugate position in the photographing observation optical system. At this position B, the internal fixation target can be freely moved on a plane orthogonal to the optical axis, and after passing through the focus lens, the eye E to be examined always has any diopter. It becomes an optimal position, and it is not necessary to move the internal fixation target in the optical axis direction.

As an example in which the internal fixation target is provided in the illumination optical system as in the position C, a dichroic mirror 31 that reflects light of the wavelength of the internal fixation target is disposed between the relay lenses 10 and 11 as shown in FIG. In some cases, the internal fixation target 32 is arranged near the fundus conjugate position on the reflected optical axis.
The internal fixation target 32 or a mechanism for driving the dichroic mirror 31 and the internal fixation target 32 integrally in the optical axis direction according to the diopter of the eye E to be examined, and the dichroic mirror 31 withdraws out of the optical path during imaging. A mechanism is provided.

  Further, Patent Document 2 discloses that an internal fixation target is moved in conjunction with a focus lens in a photographing observation optical system.

JP-A-6-217941 Japanese Patent No. 297598

  The position B that is conjugate with the image sensor 18 on the optical path branched by the flip-up mirror 17 is not necessary to move in the optical axis direction and is suitable as a position to be arranged, but the flip-up mirror 17 is essential, Space for the arrangement is required. For this reason, it is necessary to increase the distance (back focus) from the imaging lens 16 to the image sensor 18 so that the flip-up mirror 17 that is an optical path branching unit can be arranged, which is a factor that makes it impossible to reduce the size of the fundus camera.

  On the other hand, when the internal fixation target is arranged at the position C near the conjugate plane where the relay lens 11 relays the position A near the primary imaging plane, as shown in FIG. 10, the flip-up mechanism of the dichroic mirror 31 is arranged. Is required. In addition, it is necessary to secure a space for jumping up the dichroic mirror 31 between the relay lenses 10 and 11, and there is a problem that the total height of the fundus camera is increased.

  In addition, since the dichroic mirror 31 is obliquely provided for observation when the dichroic mirror 31 is in the optical path and when the dichroic mirror 31 is out of the optical path, the optical axis is decentered. There is a possibility that harmful light may enter.

  In the fundus camera shown in Patent Document 2, since the focus index projection means using the split index for focusing cannot be arranged in the illumination optical system, the focus index projection means is not provided. When the examiner performs focusing while observing the fundus image, or when the photographing observation optical system is provided with the optical path branching unit and the focusing index projection unit is separately provided, the fundus camera has a very complicated configuration. I have to be. Furthermore, normally, the internal fixation target is not configured to be retracted out of the optical path during photographing.

  An object of the present invention is to solve the above-described problems, to reduce the size of an ophthalmologic apparatus, and to obtain an ophthalmologic apparatus that projects an internal fixation target.

An ophthalmologic apparatus according to the present invention for achieving the above object includes an illumination optical system for illuminating an eye to be examined,
An optical system having a fixation target portion provided with a deflection member that deflects a light beam from a first light source that illuminates from the side in a direction conjugate with the fundus of the eye to be examined of the illumination optical system. Members,
It is characterized by providing.

  According to the ophthalmologic apparatus of the present invention, by providing the fixation target projection unit in the illumination optical system, the dichroic mirror for the fixation target projection unit is not required in the photographing optical system, and the size can be reduced.

  Further, the ophthalmologic apparatus can be miniaturized by making the optical member have the fixation target portion and the focusing split.

It is a block diagram of a non-mydriatic fundus camera. It is the front view of a parameter | index member, a side view, and a rear view. It is explanatory drawing of the near infrared light in a parameter | index member. It is explanatory drawing of the visible light in a parameter | index member. It is explanatory drawing of the internal fixation target which a subject visually recognizes. It is explanatory drawing of the observation image which an examiner observes. It is a side view of the modification of an indicator member. It is a side view of the modification of an indicator member. It is a block diagram of a prior art example. It is a block diagram of a prior art example.

  The present invention will be described in detail based on the embodiment shown in FIGS. A fundus camera will be described below as an example of an ophthalmologic apparatus.

  FIG. 1 is a configuration diagram of a non-mydriatic retinal camera. An optical path of the illumination optical system is provided from the halogen lamp 41 as the observation light source to the objective lens 42 positioned in front of the eye E to be examined. Halogen lamp 41, visible light cut filter 43, diffuser plate 44, xenon tube 45 as a photographing light source, lens 46, pupil stop 47 having a ring-shaped opening disposed at the fundus conjugate position, and a lens having a ring-shaped opening An aperture 48 and a mirror 49 are arranged. In the reflection direction of the mirror 49, a relay lens 50, an index member 51 detachably disposed at the fundus conjugate position, a relay lens 52, a corneal diaphragm 53 having a ring-shaped opening, and a perforated mirror 54 are sequentially arranged. Has been. The index member 51 is integrally configured with a focus index projecting unit and an internal fixation target projecting unit. Further, a reflecting mirror 55 is provided behind the halogen lamp 41.

  Behind the perforated mirror 54, an imaging diaphragm 56, a focusing lens 57 that functions as a focusing means, an imaging lens 58, and an imaging element 59 are sequentially arranged to constitute a photographing optical system.

  The output of the image sensor 59 is connected to the control means 60 and is also connected to a monitor 61 for displaying moving image and still image signal signals. The control means 60 further includes an internal fixation target position input means 62 and a still image. A shooting switch 63 for shooting is connected. The output of the control means 60 is connected to the visible light cut filter 43 and the indicator member 51 via the drive means 64.

  The image sensor 59 has sensitivity from a visible light region to an invisible (near infrared) light region, and can output moving images and still images. However, since the sensitivity in the near-infrared wavelength region is lower than that in the visible wavelength region, in order not to place a burden on the subject, the image is taken by the control means 60 when observing the fundus Er with near-infrared light. It is necessary to perform processing such as pixel addition by increasing the gain or decreasing the resolution compared to the time.

  2A is a front view of the index member 51 viewed from the relay lens 50 side, FIG. 2B is a side view, and FIG. 2C is a rear view of the index member 51. The indicator member 51 is made of a transparent material such as acrylic. Three minute deflecting prisms 51 a to 51 c are provided so as to protrude on the surface of the index member 51, and the deflecting prism 51 a that is a split index deflecting member is disposed substantially at the center of the index member 51. The plurality of deflecting prisms 51b and 51c, which are the fixation target deflecting members, are arranged above the center. The indicator member 51 is provided with an opening 51d in the approximate center of the back surface, and a split prism 51e is provided inside the opening 51d.

  When observing the fundus Er of the eye E, the visible light emitted from the halogen lamp 41 is cut into the visible light wavelength by the visible light cut filter 43 to become near-infrared light, and the diffusion plate 44, lens 46, pupil stop 47, The light is reflected by the mirror 49 through the lens diaphragm 48. Thereafter, the light is reflected by the perforated mirror 54 through the relay lens 50, the index member 51, the relay lens 52, and the corneal diaphragm 53, and the fundus Er is illuminated through the objective lens 2. The reflected light from the fundus Er is imaged as a fundus image on the image sensor 59 via the objective lens 42, the hole of the perforated mirror 54, the imaging aperture 56, the focusing lens 57, and the imaging lens 58.

  In the index member 51, the deflecting prism 51a is provided in the vicinity of the index member 51 and reflects the light beam emitted from the focusing index light source 51a 'that emits split near-infrared light in the optical axis direction of the illumination optical system. To do. As shown in FIG. 3, the light beam reflected by the deflecting prism 51a is split in two directions by the split prism 51e and the focusing index opening 51d provided on the opposite surface of the deflecting prism 51a. Become.

  Light beams emitted from the internal fixation target visible light sources 51 b ′ and 51 c ′ are projected onto the deflection prisms 51 b and 51 c in the vicinity of the index member 51. The reflected light of the deflecting prisms 51 b and 51 c is emitted from the index member 51 at an angle at which the light beam is not kicked by the hole portion of the perforated mirror 54 and is reflected toward the eye E by the mirror surface of the perforated mirror 54.

  FIG. 4 is an explanatory diagram of the reflected light by the deflecting prism 51b. When the examiner selects the fixation target position via the internal fixation target position input means 62, the control means 60 sets the fixation target on the selected side. For example, the visible light source 51b ′ for the internal fixation target is turned on. The internal fixation target can selectively illuminate the fundus Er according to the left and right eyes, and the subject can see visible light L in the field of view as shown in FIG. The line of sight is fixed by gazing at. Since the present embodiment is a non-mydriatic fundus camera, the observation light and the light flux from the focusing index light source 51a ′ are near-infrared light, and only the light L of the internal fixation target can be visually recognized by the subject. .

  As shown in FIG. 6, on the monitor 61, a moving image for observation is electronically added with a split index S, a fundus oculi image Er ′, and an aperture mask M that have passed through a deflecting prism 51a, a split prism 51e, and an opening 51d. Is displayed. If the focus is not matched, the split index S shifts up and down. The index member 51 moves in the direction of the optical axis of the illumination optical system in conjunction with the focusing lens 57, and the examiner moves the focus knob (not shown) so that the split index S is not displaced. Thus, focusing can be performed.

  When the examiner presses the photographing switch 63 after completing the alignment adjustment and the above-described focus adjustment, the control unit 60 retracts the index member 51 to the outside of the optical path via the driving unit 64. The fundus Er is photographed by emitting light from the xenon tube 45.

  In the present embodiment, only two deflection prisms 51b and 51c for the left and right eyes are shown as deflection members for the internal fixation target. However, more internal fixation targets may be generated in consideration of a site to be imaged such as a presentation position centered on the optic nerve head or a presentation position for performing peripheral imaging.

  In the index member 51, the angles of the deflecting prisms 51b and 51c that can deflect the light beam as shown in FIG. 7 can be reduced.

  In this embodiment, the internal fixation light beam is projected from the front side of the index member 51. However, as shown in FIG. 8, a minute reflecting mirror 51f is formed on the back side of the index member 51, and the internal fixation target is formed. You may comprise so that the light beam may be projected.

41 Halogen lamp 42 Objective lens 43 Visible light cut filter 45 Xenon tube 51 Index member 51a-51c Deflection prism 51d Opening 51e Split prism 51f Reflection mirror 51a 'Focus index light source 51b', 51c 'Visible light source for internal fixation target 59 Image sensor 60 Control means 61 Monitor 62 Internal fixation target position input means 63 Imaging switch 64 Drive means

Claims (8)

An illumination optical system for illuminating the eye to be examined;
An optical system having a fixation target portion provided with a deflection member that deflects a light beam from a first light source that illuminates from the side in a direction conjugate with the fundus of the eye to be examined of the illumination optical system. Members,
An ophthalmologic apparatus comprising:   The ophthalmologic according to claim 1, wherein the optical member further includes a focusing optical member that splits a light beam from a second light source in a plurality of directions with respect to an optical axis of the illumination optical system. apparatus. An objective lens;
A perforated mirror placed on the optical axis of the objective lens;
An imaging optical system for imaging the eye to be inspected through a hole of the perforated mirror;
The ophthalmologic apparatus according to claim 1, wherein the illumination optical system illuminates the eye to be examined with a light beam reflected by the perforated mirror. The ophthalmologic apparatus according to claim 3 , wherein the optical member is placed between the perforated mirror and an illumination light source of the illumination optical system. 5. The photographing optical system according to claim 3 or 4 , further comprising a zoom lens, and a moving unit that moves the zoom lens and the optical member on the optical axis in conjunction with each other. Ophthalmic equipment. The ophthalmic apparatus according to claim 2 , wherein the focusing optical member includes a split prism that deflects a light beam from the second light source in an optical axis direction of the illumination optical system. The ophthalmic apparatus according to any one of claims 1 to 6 , wherein the illumination optical system includes an infrared light source for observation and a visible light source for photographing. The optical member ophthalmic apparatus according to any one of claims 1 to 7, characterized in that the retracted from the optical path during shooting.

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