JP5772116B2 - Ophthalmic imaging equipment - Google Patents

Description

  The present invention relates to an ophthalmic imaging apparatus that images a subject's eye and displays it on a monitor.

  2. Description of the Related Art Conventionally, an ophthalmologic photographing apparatus that captures a fundus, an anterior eye portion, or the like of a subject's eye and displays the captured image on a monitor is known. In such an apparatus, an ophthalmologic apparatus that employs a liquid crystal display as a monitor and has a mechanism for rotating the liquid crystal display up and down to improve the visibility of a displayed image even when the position of the examiner moves. It has been known. (For example, refer to Patent Document 1).

Japanese Patent Laid-Open No. 2006-26096

  Even in the case where the display angle of the monitor can be changed as in Patent Document 1, the angle (viewing angle) when the examiner views the monitor is not necessarily the viewing angle of the monitor (the range in which the display can be normally viewed). The angle is not always within the range of the angle from the front. In particular, when a liquid crystal display is used as the monitor, the appearance of the captured image is easily changed depending on the viewing angle with respect to the monitor. However, on the other hand, if the photographed image displayed on the monitor is visible to the examiner even if it is outside the viewing angle of the monitor, the quality of the image is judged based on the photographed image visually recognized in that state There is. When the photographed image displayed on the monitor is evaluated outside the viewing angle of the monitor, even if the photographed image is photographed under an appropriate photographing condition, it is viewed as very bright or very dark and is regarded as defective. there is a possibility. On the other hand, even if the image was shot under inappropriate shooting conditions, the shot image displayed on the monitor may be evaluated outside the viewing angle of the monitor, and the shot image may be considered good. There is also.

  The present invention provides an ophthalmologic photographing apparatus capable of appropriately determining the quality of a photographed image displayed on a monitor when a liquid crystal display is employed as the monitor of the ophthalmic photographing apparatus in view of the above-described problems of the prior art. Is a technical issue.

  In order to solve the above problems, the present invention is characterized by having the following configuration.

(1) In an ophthalmologic photographing apparatus having a photographing optical system for photographing a subject's eye and a display control means for displaying a photographed image obtained by the photographing optical system on a liquid crystal display, the display control means As a chart for guiding the viewing angle with respect to the liquid crystal display, the first chart portion is viewed with the same appearance as the first chart portion within an appropriate viewing angle with respect to the liquid crystal display, and outside the proper viewing angle. The second chart portion visually recognized with a different appearance from the first chart portion is displayed on the liquid crystal display so as to be observed side by side .
(2) A photographing optical system for photographing a subject's eye, a liquid crystal display for displaying a photographed image obtained by the photographing optical system, and a chart for guiding a viewing angle with respect to the liquid crystal display together with the photographed image Display control means for displaying on the liquid crystal display, and the chart has a checkered first chart portion formed so that there is a change in gradation of light and dark alternately at a predetermined pixel interval, A second chart part having a whole area formed with intermediate gradations that are intermediate gray values of one chart part, and the display control means is arranged in a state where the first chart part and the second chart part are adjacent to each other. It is displayed on the liquid crystal display as a chart.

  ADVANTAGE OF THE INVENTION According to this invention, when a liquid crystal display is employ | adopted as a monitor of an ophthalmologic imaging apparatus, the quality of the picked-up image displayed on a monitor can be determined appropriately.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory diagram of an external configuration of a fundus camera which is a kind of ophthalmologic photographing apparatus. The fundus camera includes a base 1, a movable base 2 that can be moved in the left and right direction (X direction) and front and rear (working distance, Z direction) with respect to the base 1 by operating the joystick 4, and the movable base 2. An imaging unit 3 provided so as to be movable in a three-dimensional direction and containing an optical system to be described later, a driving unit 6 for moving the imaging unit 3 in a three-dimensional (XYZ) direction with respect to the subject's eye, and a subject A face support unit 5 fixed to the base 1 for supporting the person's face and a display unit (monitor) 8 provided on the examiner side of the photographing unit 3 are configured. A liquid crystal display having a touch panel function is used for the monitor 8 used in the present embodiment, and the monitor 8 is attached to the photographing unit 3 so as to be rotatable in the vertical direction so that the display angle can be changed. The monitor 8 is rotated (tilted) in the vertical direction, for example, by providing a rotation axis at the upper end of the monitor 8 and attaching the rotation axis to the apparatus main body (imaging unit 3). Thus, the monitor 8 is rotated in the vertical direction. The monitor 8 displays an anterior eye portion observation image and a fundus observation (photographing) image of the subject's eye photographed by the photographing unit 3. In this embodiment, the monitor 8 can be rotated in the vertical direction. However, the present invention is not limited to this, and the monitor 8 may be configured to be able to rotate in the horizontal direction or the vertical and horizontal directions.

  Next, the configuration of the optical system and the control system provided inside the photographing unit 3 will be described. FIG. 2 is a schematic configuration diagram of an optical system and a control system of the fundus camera. The optical system includes an illumination optical system 10, a fundus observation / imaging optical system 30 for observing and photographing the fundus of the subject's eye E, and an anterior ocular segment observation optical system 40.

  The illumination optical system 10 is roughly divided into an observation illumination optical system and a photographing illumination optical system. The observation illumination optical system includes an observation light source 11, such as a halogen lamp, a visible light cut filter 12, a lens 13, a prism 16 for reflecting infrared light and transmitting visible light, a ring slit 17, and a lens 18. A mirror 19, a black spot plate 20 having a black spot at the center, a relay lens 21, a perforated mirror 22, a dichroic mirror (wavelength selection mirror) 24 as an optical path branching member, and an objective lens 25. The fundus of the human eye E is illuminated. On the other hand, the photographing illumination optical system includes an optical system from a prism 16 excluding a visible photographing light source 14 such as a flash lamp, a lens 15 and a dichroic mirror 24 to an objective lens 25, and is examined by a visible light beam from the photographing light source 14. The fundus of the human eye E is illuminated. The dichroic mirror 24 has a wavelength characteristic that transmits infrared light from the observation illumination optical system and reflects infrared light from an alignment index projection optical system (not shown). Further, the dichroic mirror 24 is obliquely installed so that it can be inserted into and removed from the optical path. The dichroic mirror 24 is obliquely provided in the optical path when observing the fundus using the observation illumination optical system, and is removed from the optical path when photographing the fundus using the imaging illumination optical system. It has become.

  The fundus oculi observation / imaging optical system 30 is roughly classified into a fundus oculi observation optical system and a fundus oculi imaging optical system. The fundus observation optical system includes an objective lens 25, a perforated mirror 22, a focusing lens 32 movable in the optical axis direction, an imaging lens 33, a flip-up mirror 34 that can be inserted and removed from the optical path, a relay lens 36, and a sensitivity in the infrared region. A fundus image illuminated with an infrared light source is photographed. On the other hand, the fundus photographing optical system shares the optical system from the objective lens 25 to the imaging lens 33 with the fundus observation optical system, and has a sensitivity for the visible region arranged behind the imaging lens 33. A two-dimensional image sensor 35 is provided, and at the time of photographing, the flip-up mirror 24 and the flip-up mirror 34 are retracted from the optical path, and the fundus image illuminated by the photographing light source 14 is received and photographed by the two-dimensional image sensor 35.

  The anterior ocular segment observation optical system 40 includes a field lens 41, a mirror 42, a diaphragm 43, a relay lens 44, a two-dimensional image sensor 45, and the like on the reflection side of the dichroic mirror 24. The anterior ocular segment observation optical system 40 receives an anterior ocular segment image illuminated by infrared light from an anterior ocular segment illumination light source (not shown) by the two-dimensional imaging element 45 to obtain a captured image of the anterior ocular segment.

  The control unit 80 includes each two-dimensional imaging device (35, 38, 45), a monitor 8, a memory 81 as a storage unit, a control unit 82 for setting shooting conditions such as a shooting light amount and various operations, and the like. Is connected. The control unit 80 performs overall drive control of the ophthalmologic photographing apparatus such as drive control of the flip-up mirror with respect to the optical path. In addition, the control unit 80 performs control to display an anterior ocular segment image or a fundus observation image (photographed image) on the screen of the monitor 8 in accordance with input signals from the two-dimensional imaging elements 35, 38, and 65. In the present embodiment, when a fundus image is displayed on the monitor 8, control is performed to display a predetermined chart on the screen together with the fundus image for inducing a viewing angle with respect to the monitor.

Next, a chart formed on the monitor 8 will be described. FIG. 3 is a schematic diagram showing a state where the chart 100 is displayed together with the fundus image, and FIG. 4 is a schematic diagram for explaining the display form of the chart 100.
Normally, in a liquid crystal display, when the viewing angle with respect to the screen is changed in the vertical and horizontal directions when the screen is viewed from the front, the apparent brightness and color of the display content (captured image) change. For this reason, when the examiner makes a diagnosis by observing the fundus image, the viewing angle indicated by the manufacturer providing the liquid crystal display (the display content can be normally viewed from the center of the display). It is necessary to view the photographed image within the range of the central angle when the range is represented by a sector. In the present embodiment, the chart 100 is displayed on the left and right sides of the fundus image 110 displayed on the monitor 8, and the captured image (fundus image) is viewed at a viewing angle so that the chart 100 can be seen in a predetermined state. The image can be confirmed in an appropriate display state. In the present embodiment, as shown in FIG. 3, a fundus image 110 is displayed at the center of the screen of the monitor 8, and a chart 100 is displayed on the left and right sides thereof. The chart 100 may be displayed anywhere on the screen, but it is preferable that a pair of the charts 100 be displayed near the horizontal line L ₀ that is adjacent to the right and left of the fundus image 110 and passes through the center of the screen. As described above, the viewing angle with respect to the captured image can be more appropriately guided by being displayed in the vicinity of the horizontal line passing through the vicinity of the center of the fundus image displayed on the monitor.

As shown in FIG. 4, the chart 100 is formed by displaying two types of chart portions 100a and 100b adjacent to each other. In the present embodiment, square chart portions 100a and chart portions 100b having the same shape are arranged alternately (alternately), and are represented as one square chart 100. The chart 100a is formed of a gray scale checkered pattern in which chart 100a ₁ portions having bright luminance and 100a ₂ portions having dark luminance are alternately arranged. Each minimum grid made up of black and white is represented by one pixel of the monitor. On the other hand, the entire area of the chart 100b is formed so as to have a gray scale luminance of an intermediate gradation of gradation change at one-pixel intervals according to the chart 100a (100a ₁ , 100a ₂ ) (solid coating). Usually, the display of the liquid crystal display is controlled based on a predetermined gamma characteristic. For example, when the gamma value of the monitor 8 is 2.2, the relationship between the input value of the gradation (256 gradations) of the image data to be displayed and the brightness (output value) during normal reproduction is shown in FIG. Such a curve (gamma characteristic A in the figure) is obtained. For this reason, the chart 100 displayed on the monitor 8 considers the gamma characteristic of the monitor 8 so as to be visually recognized with an ideal color development (color development C in the figure, that is, a gamma value of 1.0). It is determined using a chart correction curve (for example, a gamma value of 0.45 and a gamma characteristic B in the figure) adjusted accordingly. Therefore, in order for the charts 100a and 100b to be visually recognized with the ideal color C on the screen of the monitor 8, the chart 100a on the gamma characteristic B corresponding to the charts 100a ₁ and 100a ₂ and the chart 100b on the ideal color C ₁ ′, 100a ₂ ′ and chart 100b ′ are output. Note that conditions (for example, display position, size, display gradation, gamma correction value, etc.) necessary for forming such a chart 100 are stored in the memory 81 in advance. When the captured fundus image is displayed on the screen of the monitor 8, the control unit 80 displays the chart 100 on the screen together with the fundus image according to the chart display conditions stored in the memory 81. Such charts are provided with a change switch for changing the display conditions of the chart so that various changes can be made according to the settings of the monitor display conditions (for example, contrast and gamma correction). It is also possible to automatically change the chart display conditions based on the above.

  It should be noted that the shading pattern (checkered pattern) chart 100a made up of such a minimal lattice utilizes the fact that it is perceived by being neutralized as an intermediate shading value, and has an appropriate viewing angle with respect to the monitor. In this case, the appearance of the chart 100a is not a checkered pattern, but the entire area is perceived as uniform brightness as an intermediate gradation, and the appearance of the chart 100b is indistinguishable.

In this embodiment, two types of charts 100a and 100b are alternately arranged vertically and horizontally to form one square chart 100. However, the present invention is not limited to this, and two types of charts are arranged on a monitor for observation. Any display form that can be used. In the present embodiment, the checkerboard pattern formed on the chart 100a is changed in tone for each pixel. However, the present invention is not limited to this, and the checkerboard pattern is neutralized to obtain an intermediate tone value (intermediate tone value). ) As long as it can be perceived as a pixel interval.
Furthermore, in the present embodiment, the charts 100a and 100b are both displayed in gray scale. However, the present invention is not limited to this, and the same chart is formed for each color of R (red), G (green), and B (blue). Can also be displayed on the monitor screen.

  Next, an operation of the fundus camera having the above configuration will be described. First, in a state where the face of the subject is supported by the face support unit 5, the movable table 2 is moved by the operation of the joystick 4 so that the photographing unit 3 approaches the eye of the subject. When an anterior ocular segment image of the subject's eye illuminated by infrared light is acquired by the anterior ocular segment observation optical system 40 and displayed on the monitor 8, the control unit 80 projects an alignment (not shown) projected onto the cornea. The drive unit 6 is driven based on the light receiving state of the index image, and the imaging unit 3 is moved in a three-dimensional direction to align the imaging unit with the eye of the subject. After the proper alignment is obtained, the control unit 80 performs focus adjustment on the fundus using the fundus observation optical system. Focus adjustment is performed by moving the focusing lens 32 in the optical axis direction so that a split index (not shown) projected on the fundus matches.

  When predetermined alignment and focus states are obtained, the examiner presses the photographing switch to photograph the fundus image of the subject's eye. When the photographing switch is pressed, the control unit 80 retracts the flip-up mirrors 24 and 34 from the optical path and causes the photographing light source 14 to emit visible flash light. The flash light illuminates the fundus of the subject's eye through the photographing illumination optical system, and the reflected light from the fundus is received by the two-dimensional image sensor 35 of the fundus photographing optical system to photograph a fundus image. The control unit 80 displays the obtained fundus image 110 on the monitor 8 and displays a pair of the chart 100 described above on the left and right of the fundus image 110. In order to check the photographing state of the fundus image displayed on the monitor 8, the examiner sets the viewing angle with respect to the monitor 8 (screen) to an appropriate angle.

  FIG. 6 is a schematic diagram showing a display state of the chart 100 that changes in appearance depending on the viewing angle of the subject's eye with respect to the monitor 8. FIG. 6A shows the monitor 8 viewed from the upper oblique direction exceeding the viewing angle, and FIG. 6C shows the monitor 8 viewed from the lower oblique direction exceeding the viewing angle. When the screen of the monitor 8 is viewed at a viewing angle exceeding the viewing angle of the monitor 8, the gamma value is greatly different from the gamma value used for gamma correction of the liquid crystal display (monitor 8) used. The brightness of the chart unit 100b is an intermediate gradation with respect to the minute shading (black and white) constituting the chart unit 100a. This intermediate gradation is determined based on a gamma curve corresponding to the gamma value used for gamma correction. Yes. Therefore, when the chart 100 is viewed from outside the viewing angle of the liquid crystal display, the intermediate gradation perceived by the chart 100a and the intermediate gradation perceived by the chart 100b appear to be different, and therefore FIG. As shown in a) and (c), the chart 100 is perceived as a spotted pattern in which the brightness of the chart portion 100a and the chart portion 100b is different. On the other hand, when the chart 100 is viewed within the viewing angle of the liquid crystal display, the chart portion 100a and the chart portion 100b have the same brightness as shown in FIG. 6B, and are integrated without being distinguished. Will be visible.

  The examiner observes the fundus image 110 displayed on the monitor 8 in such a state that the viewing angle is maintained so that the chart unit 100a and the chart unit 100b can be seen integrally, and thus the photographed fundus image 110 is displayed. Appropriateness can be judged appropriately. The examiner confirms that the fundus image displayed on the monitor 8 is obtained under appropriate photographing conditions (light quantity, etc.), and then stores the fundus image photographed using the control unit 82 in the storage unit 81. . In addition, the range (viewing angle) where the chart part 100a and the chart part 100b are seen as a unit is the same as or smaller than the viewing angle of the monitor. The viewing angle with respect to the monitor 8 may be adjusted by moving the subject's eyes in the vertical direction with respect to the monitor 8 or by relatively rotating the monitor 8 in the vertical direction. The angle may be adjusted.

  In the present embodiment, the chart is displayed at the same time when the fundus image captured with visible light is displayed on the monitor. However, the present invention is not limited to this, and the present invention is not limited to this. Alternatively, the chart may be displayed when the plurality of stored fundus images are displayed again on the monitor screen. Further, in the present embodiment, the fundus camera has been described as an example of the ophthalmologic photographing apparatus, but the present invention is not limited to this, and the present invention is not limited thereto, such as a device for photographing corneal endothelial cells or a device for obtaining retinal tomographic images. The present invention can be applied to an ophthalmologic photographing apparatus that acquires a photographed image and displays it on a monitor.

It is the model which showed the external appearance structure of the fundus camera in this embodiment. It is the schematic which showed the optical system and control system of the fundus camera in this embodiment. It is the figure which showed the example in which the fundus image and the chart were displayed on the screen of the monitor. It is the figure which showed the structure of the chart in this embodiment. It is the figure which showed the gamma characteristic of the monitor in this embodiment, and the gamma correction of the chart. It is the figure which showed a mode that the appearance of a chart changed with the visual recognition angles with respect to a monitor.

3 photographing unit 8 monitor 80 control unit 100 chart 100a chart unit 100b chart unit 110 fundus image

Claims (3)

In an ophthalmologic photographing apparatus having a photographing optical system for photographing a subject's eye and display control means for displaying a photographed image obtained by the photographing optical system on a liquid crystal display ,
The display control means is a chart for guiding a viewing angle with respect to the liquid crystal display.
A first chart part and a second chart part visually recognized with the same appearance as the first chart part within an appropriate viewing angle with respect to the liquid crystal display and visually recognized with an appearance different from the first chart part outside the appropriate viewing angle. Are displayed on the liquid crystal display so that they can be observed side by side.
An ophthalmologic photographing apparatus characterized by that. 2. The ophthalmologic photographing apparatus according to claim 1, wherein the chart includes a checkered chart unit formed as a first chart unit so as to alternately change light and dark gradations at predetermined pixel intervals, and the first chart unit . said first chart portion of the intermediate gray values to become the entire at halftone are formed chart portion as 2 chart portion consists, wherein the display control unit adjacent the first chart portion and the second chart portion An ophthalmologic photographing apparatus, wherein the chart is displayed on the liquid crystal display as the chart. An imaging optical system for imaging the subject's eye;
A liquid crystal display for displaying a photographed image obtained by the photographing optical system;
Display control means for causing the liquid crystal display to display a chart for inducing a viewing angle with respect to the liquid crystal display together with the photographed image,
The chart has a checkered pattern-shaped first chart portion formed so as to have a light-dark gradation change alternately at a predetermined pixel interval, and an intermediate gradation that is an intermediate gradation value of the first chart portion. A second chart portion formed,
The ophthalmologic photographing apparatus, wherein the display control means causes the liquid crystal display to display the first chart part and the second chart part adjacent to each other as the chart .