JP3888771B2 - Fundus camera - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a fundus camera used for fundus imaging diagnosis.
[0002]
[Prior art]
For example, a fundus camera disclosed in Japanese Patent Laid-Open No. 7-31590 is known. In this device, illumination light is irradiated to the fundus of the eye to be examined, and the fundus is observed and photographed through an objective lens of an observation / photographing optical system.
[0003]
[Problems to be solved by the invention]
By the way, in the conventional fundus camera, in addition to the fundus central part (so-called posterior pole part), the fundus peripheral part may be photographed. That is, when photographing the fundus periphery, the fixation target is projected toward the subject's eye from the direction along the optical axis of the photographing system, and the photographing is performed after matching the line of sight of the subject's eye with the optical axis of the photographing system. Do. On the other hand, when photographing the fundus periphery, the fixation target is projected from a direction different from the optical axis of the imaging system, and imaging is performed with the line of sight of the eye to be examined directed in a direction different from the optical axis of the imaging system.
[0004]
However, such a conventional fundus camera has a problem in that it is difficult to perform alignment adjustment because the imaging position of the alignment index image on the television camera changes as the fixation target projection position changes.
[0005]
That is, when photographing the center of the fundus, as shown in FIG. 5A, the corneal vertex Cf coincides with the photographing optical axis O1 due to the action of the fixation target. For this reason, the alignment index forming light beam projected onto the eye E by the alignment index 58a existing on the imaging optical axis O1 is reflected along the imaging optical axis O1 in a state where the alignment is completed, and is on the imaging optical axis O1. An alignment index image 58a ′ is formed at the position of the fundus conjugate plane R.
[0006]
On the other hand, when the fundus periphery is projected, as shown in FIG. 5B, the corneal vertex Cf is shifted from the photographing optical axis O1 by the action of the fixation target. For this reason, the alignment index light beam projected onto the eye E by the alignment index 58a existing on the photographing optical axis O1 is reflected in a direction different from the photographing optical axis O1 in a state where the alignment is completed, and as a result, the alignment index image 58a. 'Forms an image at a position shifted from the photographing optical axis O1.
[0007]
As described above, in the conventional fundus camera, the imaging position of the alignment index 58a changes due to the change of the imaging part, and therefore the examiner can move the alignment index image 58a ′ to which position when photographing which part. It had to be remembered whether it should be done, and it was difficult to handle for those who are not familiar with the operation.
[0008]
The present invention has been made in view of the above circumstances, and the object of the present invention is to easily perform alignment adjustment when photographing the fundus periphery when photographing the fundus periphery. To provide a fundus camera.
[0009]
[Means for Solving the Problems]
The present invention has been made to solve the above problems, and the invention according to claim 1 includes an illumination system for illuminating the fundus of the eye to be examined, and an imaging system for photographing the fundus of the eye to be examined. ,
A fixation target projection system for projecting a fixation target for gaze guidance of the eye to be examined toward the eye to be examined; an alignment index projection system for projecting an alignment index for alignment with the eye to be examined;
An observation system including a monitor that displays the fundus image of the eye to be examined together with an alignment index image and an alignment reference position mark;
Fixation target position changing means for changing the position of the fixation target when photographing the central part of the fundus of the subject eye and the peripheral part of the fundus of the subject eye;
A fundus camera comprising switching means for switching the display position of the reference position mark on the monitor in correspondence with the fixation target position changing means.
[0010]
The invention according to claim 2 is characterized in that a part of the fixation target forming light beam from the fixation target projection system is guided to the observation system, and the fixation target formation light beam is used as the alignment reference position mark. It is a fundus camera.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
[0016]
[Example 1]
This fundus camera includes the illumination optical system 30, the imaging optical system 31, the alignment index projection system 56, and the fixation target projection optical system 100 shown in FIG.
[0017]
The illumination optical system 30 includes an observation light source 1, a condenser lens 2, a dichroic mirror 3, a ring slit plate 4, a relay lens 5, an objective lens 41, and a perforated mirror 42.
[0018]
The illumination light beam from the observation light source 1 is guided to the ring-shaped opening 4a of the ring slit plate 4 through the condenser lens 2 and the dichroic mirror 3 having the reflection characteristic of visible light transmission infrared light, and passes through the ring-shaped opening 4a. The illuminated light is once imaged in the vicinity of the perforated mirror 42 via the relay lens 5.
[0019]
The illumination optical system 30 includes a photographing light source 19 and a condenser lens 20 behind the dichroic mirror 3.
[0020]
In the case of photography, the photographing light source 19 emits light. The photographing light from the photographing light source 19 passes through the condenser lens 20 and the dichroic mirror 3 and is once imaged in the vicinity of the perforated mirror 42 like the illumination light from the observation light source 1.
[0021]
The photographing optical system 31 includes an objective lens 41, a perforated mirror 42, a half mirror 43 used for reflecting an alignment light beam, which will be described later, a focusing lens 44, an imaging lens 45, and a flip-up mirror 47. The observation optical system 48 includes a flip-up mirror 47, a dichroic mirror 50, and a television relay lens 51, and constitutes an observation system together with the imaging tube 52 and the television monitor 53.
[0022]
The reflected light from the fundus oculi Ef is guided to the objective lens 41, and once imaged on the fundus conjugate plane R conjugate with the fundus oculi Ef by the objective lens 41, passes through the hole portion 42a of the perforated mirror 42, and then the half mirror The light passes through 43 and is guided to the flip-up mirror 47 through the focusing lens 44 and the imaging lens 45. Then, the reflected light beam forming this fundus image is re-imaged by the flip-up mirror 47 at the arrangement position R ′ of the field lens 49. The re-imaged reflected light beam is received by the imaging tube 52 via the dichroic mirror 50 and the television relay lens 51, and the fundus image 54 is displayed on the screen of the television monitor 53.
[0023]
The photographing optical system 31 is provided with a film 55 in a conjugate position with the field lens 49 with respect to the flip-up mirror 47. At the time of photographing, the flip-up mirror 47 is detached from the optical path of the photographing optical system 31 at the same time as the light emission of the photographing light source 19, and the fundus The image 54 is formed and recorded on the film 55.
[0024]
The alignment index projection system 56 includes an LED 57 as an alignment light source, a light guide 58, a reflecting mirror 60, a relay lens 61, and a half mirror 43. The LED 57 has a characteristic of emitting near infrared light having a center wavelength of 760 nm. The exit end (alignment index) 58a of the light guide 58 is disposed on the optical axis O of the relay lens 61 (the optical axis O1 of the photographing optical system 31). A two-hole aperture 59 is disposed between the relay lens 61 and the reflecting mirror 60. The two-hole aperture 59 has a pair of holes 59a and 59b as shown in FIG. The holes 59a and 59b are formed at symmetrical positions with respect to the optical axis O, and the two-hole aperture 59 is close to the relay lens 61.
[0025]
The alignment light beam emitted from the emission end 58a of the light guide 58 is reflected by the reflecting mirror 60 and guided to the holes 59a and 59b of the two-hole aperture 59. The alignment light flux that has passed through the holes 59a and 59b is guided to the relay lens 61. The alignment light flux that has passed through the relay lens 61 is reflected by the half mirror 43 toward the perforated mirror 42. The relay lens 61 temporarily forms an intermediate image at the exit end 58a of the light guide 58 at a central position X (a position on the optical axis O1 of the photographing optical system 31) X of the hole 42a of the perforated mirror 42. As shown in FIG. 3, the half mirror 43 has a transmission characteristic T that transmits approximately half of the light beam having a wavelength of 760 nm and transmits approximately 100% of the light beam in the other wavelength region. For this reason, the light amount of the reflected light beam from the fundus oculi Ef is prevented from being reduced by the presence of the half mirror 43.
[0026]
A pair of alignment light beams forming an alignment index 58a formed at the center position X of the hole 42a of the perforated mirror 42 is guided to the cornea C of the eye E through the objective lens 41. Here, when the working distance W from the eye E to the apparatus main body and the vertical and horizontal positions are appropriate, an intermediate position Cc between the apex Cf of the cornea C and the corneal curvature center Cr by a pair of alignment light beams from the exit end 58a. An alignment image is formed and projected. Further, when the working distance W from the eye E to the apparatus main body is deviated from the appropriate position, the alignment image based on the pair of alignment light beams is projected separately at the intermediate position Cc of the cornea C.
[0027]
The alignment reflected light beam reflected by the cornea C is imaged on the fundus conjugate plane R by the objective lens 41 when the working distance W is appropriate. The alignment reflected light beam imaged on the fundus conjugate plane R passes through the hole 42a and is received by the image pickup tube 52 in the same manner as the reflected light beam forming the fundus image 54. As shown in FIG. An alignment image (image of the emission end 58a) 58 ′ is displayed on the screen of the television monitor 53 together with the image 54.
[0028]
Further, when the working distance W is deviated from the appropriate position, an alignment image (image of the emission end 58a) 58 ′ is separated and formed on the television monitor 53 as shown in FIG. The examiner can adjust the alignment by visually recognizing the match / separation of the alignment image 58 ′ based on this alignment light beam (see Japanese Patent Publication No. 60-52820, Japanese Patent Laid-Open No. -277183, JP-B-60-57854, JP-B63-22823, JP-B-60-57855, JP-B-5-54777, etc.).
[0029]
A fixation target projection optical system 100 is provided behind the dichroic mirror 50. The fixation target projection optical system 100 includes a fixation light source 101 for guiding the eye of the eye E, a stop 102 as a fixation target, and a fixation target projection lens 103. The fixation target is projected onto the fundus oculi Ef of the eye E through each optical system element of the photographing optical system 30. A plurality of (for example, five) fixation light sources 101 are provided, one of which is used for photographing the fundus central part and the remaining four are used for photographing the fundus peripheral part. FIG. 1 shows two fixation light sources 101 for photographing the fundus periphery, and the remaining two fixation light sources 101 for photographing the fundus periphery are arranged in a direction perpendicular to the paper surface. Is abbreviated. When photographing the fundus center, the fixation light source 101 for photographing the fundus center is turned on and a fixation target is presented to the eye E to be examined. When photographing the fundus periphery such as the right, left, top, and bottom, the fixation light source 101 corresponding to the fundus periphery to be photographed is turned on and the fixation target is presented to the eye E to be examined. .
[0030]
In addition, an I scale I for determining the degree of pupil opening is synthesized and displayed at the center of the screen on the TV monitor 53 (FIG. 6A). This I scale I is also used as an alignment image reference position mark when photographing the center of the fundus.
[0031]
Hereinafter, the operation of the fundus camera according to the present embodiment will be described separately for the case of photographing the fundus central part and the fundus peripheral part.
[0032]
[When photographing the center of the fundus]
When photographing the fundus center, the fixation light source 101 for photographing the fundus center is selected and turned on by a fixation target selection switch (not shown). As a result, the line-of-sight direction of the subject coincides with the direction of the optical axis O1 of the imaging optical system 31. Therefore, when the alignment is completed, a fundus image 54 is displayed on the television monitor 53 such that the center of the fundus, that is, the eye papilla to be examined is near the center of the screen.
[0033]
An alignment image 58 ′ is displayed on the television monitor 53. When the alignment is not completed, the alignment image 58 ′ is displayed separately as shown in FIG. 4 (b). The examiner moves the retinal camera body in the front-rear direction using a joystick (not shown) or the like, so that the alignment image 58 ′ matches (that is, the state shown in FIG. 4A). In addition, the fundus camera body is moved up, down, left and right so that the I scale I displayed on the television monitor 53 matches the alignment image 58 ′.
[0034]
Thereafter, the examiner presses a photographing switch (not shown) to photograph the fundus image 54.
[0035]
[When photographing the periphery of the fundus]
First, a case will be described as an example in which a fundus image 54 in which the eye E of the subject eye E is above the fundus oculi Ef, that is, the eye papilla is in the lower half of the screen, is taken as an example. In this case, a fixation light source 101 that causes the subject's line of sight to be directed upward is selected and turned on by a fixation target selection switch (not shown). As a result, the line of sight of the subject is directed upward, and in the state where the alignment is completed, a fundus image 54 is displayed on the television monitor 53 such that the subject's eye nipple is in the lower half of the screen.
[0036]
When the fixation light source 101 for turning the line of sight upward is turned on, an alignment reference position mark 104a is displayed in the downward direction of the screen of the television monitor 53 in conjunction with this. The alignment reference position mark 104a indicates the alignment reference position when photographing the upper side of the fundus oculi Ef. That is, as already described with reference to FIG. 5, when the line of sight of the subject eye E for photographing above the fundus oculi Ef is directed upward, the alignment image 58 ′ is displayed in the photographing optical system 31 in a state where the alignment is completed. The image is formed at a position deviated from the optical axis O1, and the image is formed at the position of the alignment reference position mark 104a on the screen of the television monitor 53. Therefore, the examiner can complete the alignment by adjusting the position of the fundus camera body so that the alignment reference position mark 104a and the alignment image 58 ′ coincide with each other.
[0037]
Similarly, the alignment reference position mark 104b is used when shooting the lower side of the fundus oculi Ef, the alignment reference position mark 104c is used when shooting the right side of the fundus oculi Ef, and the alignment reference position when shooting the left side of the fundus oculi Ef. Each position mark 104d is displayed. The examiner can complete the alignment by matching the alignment reference position marks 104a, 104b, 104c, and 104d with the alignment image 58 ′.
[0038]
Thus, in the present embodiment, the display of each alignment reference position mark 104a, 104b, 104c, 104d is changed according to the position of the alignment image 58 ′ that changes depending on which part of the fundus oculi Ef is imaged. Therefore, there is an advantage that alignment adjustment between the optical axis O1 of the photographing optical system 31 and the pupil center becomes easy.
[0039]
In the above embodiment, the display positions of the alignment reference position marks 104a, 104b, 104c, and 104d are changed in conjunction with the operation of the fixation target selection switch. A selection switch for selecting which part (center, upper side, lower side, right side, left side) of Ef is to be photographed is prepared, and each of the alignment reference position marks 104a, 104b, 104c, 104d is selected according to the operation of this selection switch. You may comprise so that a display position may be changed. Further, the examiner may select the lighting position of each alignment reference position mark 104a, 104b, 104c, 104d by a selection switch without being linked.
[0040]
[Modification]
Instead of displaying the alignment reference position on the television monitor 53, a fixation target may be used as each alignment reference position mark 104a, 104b, 104c, 104d. In this case, the planar portion 49a of the field lens 49 is a half mirror, and a part of the fixation target is reflected and received by the imaging tube 52. As shown in FIG. 5B, the line-of-sight direction of the eye E and the reflection direction of the alignment light beam (the direction of the optical axis O2) are almost the same angle θ with respect to the optical axis O1 of the imaging optical system 31. Since the formation position of the alignment image 58 ′ on the TV monitor 53 is substantially the same as the formation position of the fixation target on the TV monitor 53, the fixation target is indicated by each alignment reference position mark 104a, 104b, 104c, 104d. Can be used as The flat surface portion 49a of the field lens 49 may be a half mirror having a concave shape.
[0041]
[ Reference example 1 ]
FIG. 8 illustrates the present invention. Reference example 1 Is shown. this Reference example 1 Then, instead of changing the lighting position of each alignment reference position mark 104a, 104b, 104c, 104d according to the change in the fixation target projection position, the alignment index formation position according to the change in the fixation target projection position. Thus, the position where the alignment index is formed on the television monitor 53 is not changed regardless of the projection position of the fixation target.
[0042]
Specifically, when projecting a fixation target for photographing the center of the fundus, the exit end 58a of the light guide 58 is disposed on the optical axis O1 of the photographing optical system 31, as shown in FIG. When projecting a fixation target for photographing the fundus periphery, as shown in FIG. 8, the exit end 58a of the light guide 58 is perpendicular to the optical axis O1 of the photographing optical system 31 (the direction of the arrow S shown in FIG. 8). , And is arranged at a position shifted from the optical axis O1. Thereby, the position on the television monitor 53 of the alignment image 58 ′ when the alignment is completed is set to be the same when the fundus central part is photographed and when the fundus peripheral part is photographed.
[0043]
Further, it is preferable not only to move the exit end 58a in the direction orthogonal to the optical axis O1 of the photographing optical system 31, but also to move in the optical axis O1 direction by a distance δ2 (see FIG. 7). As a result, the virtual image of the alignment index is formed at the position of the cornea surface and the focal plane Fc as in the case of photographing the center of the fundus, so that the focused alignment image 58a can be observed. In other words, when the light guide 58 is not moved in the direction of the optical axis O1 of the photographing optical system 31, the alignment image 58a is slightly blurred. However, when the projection angle of the fixation target is small, this blur is of a level that does not hinder the alignment adjustment, and thus the movement of the exit end 58a in the direction of the optical axis O1 may be omitted. The moving distances δ1 and δ2 of the light guide 58 are determined in consideration of the projection angle of the fixation target light flux, the curvature of the eye cornea C to be examined, and the working distance.
[0044]
[Modification 1]
In FIG. 8, when photographing the fundus periphery, the exit end 58a is moved in the direction of the optical axis O1 of the photographing optical system 31 as indicated by the arrow Z1, but as shown in FIG. When photographing the central part, a parallel plane plate 80 as an optical member for correcting the optical path length is inserted from the optical path of the alignment index projection system 56, and when photographing the fundus periphery, the parallel plane plate 80 is used as the optical path of the alignment index projection system 56. It is good also as a structure which leaves | separates.
[0045]
With this configuration, even when the light guide 58 is not movable in the direction of the optical axis O1, the presentation position of the alignment index 58a in the optical axis direction is taken when photographing the fundus central part and when photographing the fundus peripheral part. Can be changed.
[0046]
[Modification 2]
10 to 14 Reference example 1 When the center of the fundus is imaged, a plane parallel plate 80 shown in FIGS. 12 (a) and 12 (b) is inserted into the optical path of the alignment index projection system 56 to When shooting, the prism 81 (see FIGS. 11 (a) and 11 (b)) for changing the position of the alignment index 58a corresponding to the position of the fixation target and correcting the optical path length is aligned. It is configured to be inserted into the optical path of the index projection system 56. FIG. 10 shows an alignment index projection system 56 for photographing the fundus periphery, in which a prism 81 is inserted into the optical path and a plane parallel plate 80 is detached from the optical path. As shown in FIG. 12, a two-hole aperture 82 is integrally formed on the plane-parallel plate 80 by means of printing or the like. Is formed. That is, the straight line L1 connecting the centers of the pair of holes 82a and 82a intersects the optical axis O. As shown in FIG. 11, the two-hole aperture 83 is also formed integrally with the prism 81. A straight line L2 connecting the centers of the pair of holes 83a and 83a of the two-hole aperture 83 is separated from the optical axis O. The prism 81 can be rotated around the optical axis O corresponding to the change of the fixation target presentation position, and the alignment index presentation position is changed by the declination of the prism 81. In addition, the optical path length of the prism 81 and the optical path length of the parallel plane plate 80 are different in order to change the presentation position of the alignment index 58a in the optical axis direction when photographing the fundus central part and when photographing the fundus peripheral part. It is different. The reason for changing the formation positions of the hole portions 82a and 83a of the two-hole apertures 82 and 83 when photographing the fundus central portion and when photographing the fundus peripheral portion is that the luminous flux is caused by the hole portion 42a of the perforated mirror 42. This is to prevent vignetting.
[0047]
[Modification 3]
In this modified example, as shown in FIG. 15, instead of moving the exit end 58a of the light guide 58, a plurality of alignment index projection systems 105 for photographing the fundus periphery are formed around the hole 42a of the perforated mirror 42. It was set as the structure which provides (4 pieces). The peripheral area alignment index projection system 105 includes an LED 106 and an optical fiber 107. Then, the LED 57 is turned on when photographing the fundus central part, while the LED 106 is turned on when photographing the peripheral part. With this configuration, it is possible to prevent the projected light beam of the alignment index 58a from the emission end 107a of the optical fiber 107 from being vignetted by the perforated mirror 42, so that the fundus peripheral part farther from the fundus central part can be photographed. .
[0048]
[Modification 4]
In the configuration shown in FIG. 15, in order to photograph the fundus periphery farther from the center of the fundus, if the fixation target presentation position is changed to the position indicated by the broken line, the fixation target may be vignetted by the field stop 49 ′. is there. In this modification, as shown in FIG. 16, a half mirror 108 is provided between the imaging lens 45 and the quick return mirror 47 in order to prevent vignetting of the fixation target by the field stop 49 ′. The system 100 is provided on the reflection optical axis of the half mirror 108.
[0049]
[Modification 5]
In this modified example, as shown in FIG. 17 (a), four alignment index projection systems 105 for photographing the fundus periphery are provided around the perforated mirror 42, and as shown in FIG. 17 (b). A pair of alignment index projection systems 109 for photographing the fundus center is provided. The pair of alignment index projection systems 109 is composed of an LED 110 and an optical fiber 111 as in the alignment index projection system 105. FIG. 17B shows light constituting the alignment index projection system 105 for photographing the fundus periphery. Along with the exit end 107a of the fiber 107, an exit end 111a of an optical fiber constituting a pair of alignment index projection systems 109 for photographing the fundus center is shown.
[0050]
According to this modification, when photographing the fundus central part, as shown in FIG. 18 (a), a pair of alignment images 111 ′ are formed apart from each other on the screen peripheral part. When photographing the fundus periphery, the fixation target is switched to guide the direction of the line of sight. Also, the corresponding LED 110 is turned on. As shown in FIG. 7, when the alignment index 58a is deviated from the optical axis O1 of the photographing optical system 31, the reflected light beam reflected by the cornea C returns parallel to the optical axis O1 and forms an image on the optical axis O1. Therefore, as shown in FIG. 18 (b), the formation position of the alignment image 107 ′ is positioned at the center position of the screen. In this way, even without using the alignment reference position mark 104, it is possible to take a picture without vignetting of the illumination light beam in the vicinity of the fundus. Instead of providing a pair of alignment projection systems 109 for central photographing, a pair of alignment projection systems 105 for photographing peripheral portions may be projected.
[0051]
[ Reference example 2 ]
this Reference example 2 In this case, as shown in FIG. 19, the line-of-sight direction detecting means 112 is provided between the objective lens 41 and the perforated mirror. The line-of-sight direction detection means 112 arranges LEDs 113 to LED 116 that emit infrared light around the objective lens 41 and irradiates the cornea C from the LEDs 113 to LED 116 to form a virtual image (not shown). Then, as shown in FIG. 20, corneal reflection images as virtual images 113 ′ to 116 ′ are obtained on the image sensor 117, and the anterior segment image E ′ is formed on the image sensor 117 to detect the line-of-sight direction. To do. The image sensor 117 and the anterior segment are in a conjugate relationship.
[0052]
When the line of sight is directed in the direction of the optical axis O1 of the photographing optical system 31, the center Qo of the pupil image Q ′ is set at the center position of the cornea reflection images 113 ′ to 116 ′. When the line-of-sight direction changes due to the change of the fixation target, the center position Qo of the pupil image Q ′ deviates from the center position Oo of the cornea reflection images 113 ′ to 116 ′ as shown in FIG. Accordingly, the line-of-sight direction can be detected by obtaining the center position Oo and the center position Qo of the pupil image Q ′.
[0053]
The center position Qo of the pupil image Q ′ may be obtained by calculation from this low level portion because the luminance level of the pupil image Q ′ portion of the image signal output from the image sensor 117 is lower than the other portions. Further, the positions of the cornea reflection images 113 ′ to 116 ′ are higher than the other portions because the luminance levels of the cornea reflection images 113 ′ to 116 ′ of the image signal output from the image sensor 117 are higher than the other portions. It can be detected from the part. In addition, 118 is a half mirror constituting the line-of-sight direction detection means 112, 119 is a relay lens, 120 is a reflection mirror, and 121 is a television lens.
[0054]
this Reference example 2 Then, the configuration is such that the line-of-sight direction detection means 112 is provided in the imaging optical system 31 shown in FIG. 1, but the configuration in which the line-of-sight direction detection means 112 is provided in the imaging optical system 31 shown in FIGS. In this case, the alignment index is moved and switched corresponding to the detected line-of-sight direction.
[0055]
More than Example 1 and Reference Examples 1 and 2 Then, it was set as the structure which changes the presentation position of a fixation target by switching a lighting state using a plurality of fixation targets, but by moving a fixation target using one fixation target, It is good also as a structure which changes the presentation position of a fixation target.
[0056]
【The invention's effect】
Since the fundus camera according to the present invention is configured as described above, there is an effect that alignment adjustment can be easily performed when photographing the fundus periphery.
[Brief description of the drawings]
FIG. 1 shows a fundus camera according to an embodiment of the present invention. Example 1 FIG.
FIG. 2 is a plan view of the two-hole aperture shown in FIG.
FIG. 3 is a diagram showing the transmission characteristics of the half mirror shown in FIG. 1;
4A and 4B are diagrams showing a fundus image observed using a fundus camera, in which FIG. 4A shows a case where the working distance from the eye to be examined is appropriate, and FIG. Indicates the case where the working distance to the main unit is not appropriate.
FIG. 5 is an explanatory diagram of an alignment index projection principle, in which FIG. 5A shows an optical axis of an imaging optical system when an optical axis of an eye to be examined is coincident with an optical axis of an imaging optical system; FIG. 5B shows a state where the optical axis of the imaging optical system is inclined at a predetermined angle with respect to the optical axis of the eye to be inspected. It shows a state of being formed on the fundus conjugate plane by shifting from above.
6 shows a state in which a fundus image is observed on a television monitor using the fundus camera shown in FIG. 1. FIG. 6 (a) is an explanatory view of a fundus center image and an alignment image displayed on the television monitor. b) is an explanatory diagram of a fundus peripheral image and an alignment image displayed on a television monitor.
FIG. 7 is an explanatory diagram for explaining a positional shift in an optical axis direction between an alignment index image when photographing a fundus peripheral portion and an alignment index image when photographing a fundus center portion;
[Fig. 8] Reference example 1 of fundus camera FIG. 2 is a diagram illustrating a case where the light guide is moved in the optical axis direction of the photographing optical system.
FIG. 9 Reference example 1 FIG. 6 is an optical diagram showing a first modification of the above, and shows a configuration in which a parallel plane plate is detachably provided in the optical path of the alignment index projection system.
FIG. 10 Reference example 1 It is an optical diagram which shows the principal part structure of the alignment parameter | index projection system of the modification 2 of.
11 is an enlarged view of the prism shown in FIG. 10, wherein (a) is a plan view and (b) is a side view. FIG.
12 is an enlarged view of the plane parallel plate shown in FIG. 10, wherein (a) is a plan view and (b) is a side view. FIG.
FIG. 13 is a schematic diagram showing a light path of an alignment index light beam when photographing the center of the fundus.
FIG. 14 is a schematic diagram illustrating a light path of an alignment index light beam when photographing a fundus periphery.
FIG. 15 Reference example 1 It is an optical diagram which shows the modification 3 of.
FIG. 16 Reference example 1 It is an optical diagram which shows the modification 4 of.
FIG. 17 Reference example 1 FIG. 9A is an optical diagram, and FIG. 5B is an enlarged view of the vicinity of a perforated mirror in the optical diagram shown in FIG.
18A is an explanatory diagram of a fundus center image and an alignment image displayed on a TV monitor, and FIG. 18B is an explanatory diagram of a fundus peripheral image and an alignment image displayed on a TV monitor. is there.
FIG. 19 Reference example 2 of fundus camera FIG.
FIG. 20 is an explanatory diagram showing a positional relationship between a pupil image and a corneal reflection image.
FIG. 21 is an explanatory diagram showing a positional relationship between a pupil image and a corneal reflection image when the line-of-sight direction changes.

Claims (2)

An illumination system for illuminating the fundus of the eye to be examined; an imaging system for photographing the fundus of the eye to be examined;
A fixation target projection system for projecting a fixation target for eye gaze guidance of the eye to be examined toward the eye to be examined;
An alignment index projection system for projecting an alignment index for alignment with the eye to be examined on the eye to be examined;
An observation system including a monitor that displays the fundus image of the eye to be examined together with an alignment index image and an alignment reference position mark;
Fixation target position changing means for changing the position of the fixation target when photographing the central part of the fundus of the subject eye and the peripheral part of the fundus of the subject eye;
A fundus camera comprising switching means for switching the display position of the reference position mark on the monitor in correspondence with the fixation target position changing means.   The fundus according to claim 1, wherein a part of the fixation target forming light beam from the fixation target projection system is guided to the observation system, and the fixation target formation light beam is used as the alignment reference position mark. camera.

Images