JP2012040430A - Visual performance inspection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform a plurality of visual performance inspection using the same device in a state of opening both eyes and a similar state on the basis of how the human eye sees things in daily life without limiting eyesight.SOLUTION: A visual performance inspection device includes: a visual target image displaying part (2) for displaying visual target images; a visual target drawing part (13) for drawing the visual target images displayed on the visual target image displaying part (2); a visual performance inspection item selecting part (11) for selecting items of the visual performance inspection; and a visual target image generation part (12) for generating the visual target images corresponding to the inspection items selected by the visual performance inspection item selecting part (11). The visual target drawing part (13) calculates the display size and display position of the visual target images corresponding to the eye test or eyesight test selected by the visual performance inspection item selecting part (11) on the basis of a visual point distance or viewing angle and draws the visual target images with the calculated display size on the calculated display position.

Description

  The present invention relates to a visual function testing device that performs a plurality of visual function tests with a single unit.

  Conventionally, a visual function inspection device for inspecting various visual functions is known. There are many test items for visual function tests in ophthalmology. The inspection items include visual acuity, visual field inspection, binocular visual inspection, eye position inspection, and the like. These visual function inspection devices for various visual function tests are composed of specifications that are specific to the examination content of each item such as visual acuity and visual field, so it is possible to perform visual acuity, visual field, and binocular vision with a single unit. There is nothing that can be inspected.

  As a visual function inspection device, as described in the following Patent Document 1 and Patent Document 2, an apparatus capable of performing visual function inspection of two items is known.

  The visual function inspection device described in Patent Literature 1 has a function of presenting a visual target to each of the left and right eyes by a binocular separation method using an optical system, a polarizing filter, and a red-green filter, and is used for visual acuity inspection. The visual target and the visual target for binocular inspection are used in the same inspection device. Thereby, the visual function test | inspection apparatus of patent document 1 can perform two visual function tests, visual acuity and binocular vision, with one unit.

  The visual function inspection apparatus described in Patent Document 2 is configured by disposing a liquid crystal display for visual acuity inspection at the center and a light source for visual field inspection composed of a large number of LEDs in the periphery. Thereby, the visual function test | inspection apparatus of patent document 2 can perform two visual function tests, visual acuity and a visual field.

Japanese Patent No. 3168056 JP 2003-93344 A

  However, the visual function tester using the above-described technology has a dedicated device for each inspection item, and tests more than two visual functions such as visual acuity, visual field, stereoscopic vision, binocular vision, and eye position in one unit. There is no possible visual function testing device.

  Moreover, in the current visual acuity tester and visual field tester, the visual field of one eye is blocked using an eye shield or the like, and the test is performed for each eye. Furthermore, the current binocular vision inspection device achieves binocular separation with a structure in which a lens barrel is looked into, so that the field of view is limited and becomes narrow. As described above, the current visual function tester performs visual function tests in a state different from the daily appearance by blocking the field of view with the eye shield and limiting the visual field with the lens barrel.

  It is an object of the present invention to provide a visual function inspection apparatus capable of performing a plurality of visual function tests with the same apparatus in a state in which both eyes are opened and in a state close to daily appearance without restricting the visual field. .

  A visual function inspection device according to a first invention for solving the above-mentioned problem is a visual function inspection device capable of inspecting a plurality of visual functions, and includes a visual target image presentation means for presenting a visual target image, and the visual target. Corresponding to the test item selected by the visual function test item selecting unit, the visual function test item selecting unit for selecting the visual function test item, and the target image drawing unit for drawing the target video to be presented to the video presenting unit A target image generation unit that generates a target image to be generated, and the target image drawing unit includes a viewpoint distance that is a distance between the target image presentation unit and the observer, a target image and a viewpoint of the observer, A visual target corresponding to at least one of the visual acuity test, visual field test, stereoscopic vision test, binocular vision test, and eye position test selected by the visual function test item selection means based on the viewing angle formed by Calculate the display size and display position of the video, and Characterized by drawing a visual target image to display size and display position.

  The visual function testing device according to the first invention, wherein the visual image generating means generates a visual image for each of the subject's right eye and left eye. Binoculars for displaying the right eye and left eye binocular visual target images generated by the binocular visual target image generation function for each corresponding eye by separating both eyes. A target video selection presentation that has a separate target video presentation function and independently selects display or non-display for each right-eye or left-eye target video presented by the binocular separation target video presentation function. Means for displaying a target image corresponding to the stereoscopic examination selected by the visual function test item selecting means.

  The visual function testing device according to the second invention, wherein the target image generating means generates a target image for each eye of the subject's right eye and left eye. Binoculars for displaying the right eye and left eye binocular visual target images generated by the binocular visual target image generation function for each corresponding eye by separating both eyes. It has a separate visual target image presentation function, and comprises visual target image operation means that changes at least one of the display size or display position of the visual target image by a user operation, and the visual function inspection item selection means performs binocular visual inspection or When the eye position examination is selected, the target image drawing unit displays the display calculated by the target image drawing unit according to the display size or display position of the target image changed by the target image operating unit. Change the target image to the size and display position Characterized in that the fractionating.

  The visual function testing device according to any one of the first to third aspects, wherein the visual target image drawing means is a visual function capable of adjusting brightness, contrast, color, and transparency of the visual target image. It has a standard image adjusting means.

  The visual function inspection device according to any one of the first to fourth aspects, wherein the visual field used in the visual field inspection when the visual field inspection is selected by the visual function inspection item selection means. A viewing angle for calculating a viewing distance required for performing a visual field inspection at a viewing angle input by the viewing angle input unit in a screen size of the viewing angle input unit for inputting a corner and the target image presentation unit And a calculating means.

  The visual function testing device according to any of the first to fifth inventions, wherein the sixth invention is a visual acuity used in the visual acuity test when the visual acuity test is selected by the visual function test item selection means. And a visual distance input means for calculating a visual distance required for performing a visual acuity test with the visual acuity input by the visual acuity input means at the resolution of the visual target image presenting means. It is characterized by that.

  The visual function inspection device according to any one of the second to sixth inventions, wherein the seventh invention is used in the stereoscopic inspection when the stereoscopic inspection is selected by the visual function inspection item selection means. Parallax input means for inputting the parallax to be input, and viewpoint distance calculation means for calculating the viewpoint distance required for performing the stereoscopic inspection with the parallax input by the parallax input means at the resolution of the target image presentation means It is characterized by providing.

  The visual function testing device according to any one of the first to seventh inventions, wherein the eighth invention includes viewpoint distance measuring means for measuring a distance between the visual target image presenting means and an observer's viewpoint. It is characterized by.

  The visual function testing device according to any one of the second to eighth inventions, wherein the ninth invention includes a target image storage means for storing a target image generated by the target image generation means, a viewpoint Display setting storage means for storing the display size and display position of the target image calculated using the position and the viewing angle, and target images for the right eye and the left eye set by the target image selection presenting means The display order of the target images stored in the target image storage means is set using a combination of the target image selection storage means for storing display or non-display and the information stored in each storage means. A display order setting unit is provided, and the target image stored in the target image storage unit is called in accordance with the display order set by the display order setting unit, and is drawn by the target image drawing unit. .

  The visual function testing device according to any one of the first to ninth inventions, wherein the tenth invention comprises an output means for outputting a test result of the visual function test selected by the visual function test item selecting means, The inspection result corresponding to the inspection item is output in a predetermined format.

  According to the present invention, since the target image is drawn by calculating the display size and display position of the target image based on the input viewpoint distance and viewing angle, the binocular eye is not cut off without blocking the view or limiting the field of view. A plurality of visual function tests can be performed with the same apparatus in a state in which the visual field is opened and in a state close to the daily appearance without restricting the visual field.

In the visual function test | inspection apparatus shown as one Embodiment of this invention, it is a side view which shows the relationship between the viewpoint position P and the presentation surface of a target image | video presentation part. It is a block diagram which shows the example of 1 structure of the visual function test | inspection apparatus shown as 1st Embodiment of this invention. It is a figure which shows the specific example of the shape of the presentation screen of a target image | video presentation part, (a) is a flat type, (b) is an arch type, (c) is a dome shape, (d) is a polyhedral type. It is a figure which shows the target image | video presented to a target image | video presentation part, (a) is a Landolt ring, (b) is a light spot, (c) is explanatory drawing of the magnitude | size of a target image. It is a side view explaining the size which can be seen by visual angle (theta) from viewpoint position P on a visual target picture presentation part. It is a perspective view explaining the display position of a target picture on a target picture presentation part. It is a perspective view explaining arrange | positioning a target image | video on the grid line on a target image presentation part. It is a top view explaining the screen center set with respect to the viewpoint position, (a) is a case where the screen center is set at a position facing the viewpoint position, and (b) is facing the left eye. This is a case where the screen center is set as the position. It is a figure which shows the specific example of a Landolt ring. It is a front view which shows a mode that the target image | video as a light spot has been arrange | positioned with respect to the origin on the lattice line of a target image presentation part. It is a block diagram which shows the example of 1 structure of the visual function test | inspection apparatus shown as 2nd Embodiment of this invention. It is a figure which shows an example which displays the optotype image | video which provided the parallax. It is a figure explaining the distance according to the parallax at the time of displaying the optotype image which provided the parallax. It is a figure explaining a human sensory fusion, and is an explanatory figure in the ability to recognize what was shown to the right and left eyes by changing the size of the same picture as one image. It is a figure explaining a human sensory fusion, and is an explanatory figure in the ability to recognize what was shown to the right and left eyes by changing blur difference as one image. It is a block diagram which shows the example of 1 structure of the visual function test | inspection apparatus shown as 3rd Embodiment of this invention. It is a block diagram which shows one structural example of the visual function test | inspection apparatus shown as 4th Embodiment of this invention. It is a block diagram which shows one structural example of the visual function test | inspection apparatus shown as 5th Embodiment of this invention. It is a block diagram which shows one structural example of the visual function test | inspection apparatus shown as 6th Embodiment of this invention. It is a block diagram which shows the example of 1 structure of the visual function test | inspection apparatus shown as 7th Embodiment of this invention. It is a block diagram which shows one structural example of the visual function test | inspection apparatus shown as 8th Embodiment of this invention. It is a block diagram which shows the example of 1 structure of the visual function test | inspection apparatus shown as 9th Embodiment of this invention. It is a block diagram which shows one structural example of the visual function test | inspection apparatus shown as 10th Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
The visual function inspection device shown as the first embodiment of the present invention can perform a plurality of visual function inspections in a binocular open state that is close to the daily appearance, and can evaluate the daily appearance in a multifaceted manner. is there. This visual function testing device can perform a plurality of visual function tests with a single device. This visual function test is a function test for viewing, and is roughly classified into subjective and multi-objective tests. A subjective examination is an examination that is frequently performed in ophthalmic practice such as visual acuity, visual field, and binocular visual examination. On the other hand, an objective test is performed when the patient cannot respond, such as being an infant, or is unreliable. The vision test includes binocular vision and single-eye vision. The visual field examination includes a binocular visual field and a monocular visual field. Further, in this visual function testing device, a display that presents a target image has a binocular separation function. Thereby, the visual function test | inspection apparatus can switch and implement a one-eye test | inspection and a binocular test | inspection, without using an eye shield. The visual target presented by the visual function inspection device is an image or video presented for the purpose of visual function inspection, and includes a Landolt ring in visual acuity inspection, a light spot in visual field inspection, and the like.

  First, a visual function inspection apparatus capable of inspecting binocular visual acuity and binocular visual field with a single unit as a visual function inspection item will be described.

  The technical significance of this visual function inspection device will be described. In conventional visual function tests, there is a dedicated tester for each visual function test item, so when performing multiple visual function tests, movement between testers, learning of different test methods, and test results Problems such as inability to integrate. 2. Description of the Related Art Conventionally, a technique for realizing visual acuity and visual field by presenting a visual target for visual acuity inspection on a liquid crystal screen disposed in a central portion and presenting a visual target for visual field inspection with a light source disposed in the surroundings No. 93344) has been proposed. However, this technique does not have a function of changing the display size or display position of the target image according to the viewpoint distance. For this reason, the viewpoint position is fixed, and the viewpoint position cannot be changed for each visual function test item. In a general visual acuity test, the visual distance table and the observer's viewpoint distance are defined as 5 meters (m).

  In the visual field inspection, in order to measure the central visual field, the ability to present a visual target in a range of a visual field angle of about 20 degrees to 30 degrees is required. The viewing angle represents the visible range as an angle from the eye, and is a value representing how much the range is visible from the front.

  That is, as shown in FIG. 1, when the visual acuity and visual field inspection are performed at the fixed viewpoint position P with the same apparatus, the presentation surface 2a having a viewing angle of 20 degrees or more from the viewpoint position P separated by a distance B of 5 m is obtained. Necessary. Then, the range of this presentation surface 2a becomes a circle having a diameter B of about 1.76 m. When a circle having a diameter B of about 1.76 m is presented on a display (aspect ratio 4: 3), a screen size of 116 inches (4: 3 = horizontal width 2.358 m: vertical width 1.769 m) or more is required. Thus, in the configuration in which the viewpoint position P is fixed, the apparatus configuration is large and is not realistic.

  Therefore, the visual function testing device shown as the embodiment of the present invention calculates the display size and display position of the target image corresponding to the change of the viewpoint position P when the viewpoint distance and the viewing angle of the observer are input, and is arbitrarily set. The binocular visual acuity test and the binocular visual field test can be performed at the viewpoint position P.

  Such a visual function testing device is configured as shown in FIG. 2, for example. The visual function inspection device includes a control device 1 and a visual target image presentation unit 2 such as a liquid crystal display for presenting a visual target image.

  The target image presentation unit 2 displays a target image. As shown in FIG. 3, the shape of the presentation screen of the target image presentation unit 2 is a flat type as shown in FIG. 3 (a), an arch type as shown in FIG. 3 (b), and a shape as shown in FIG. 3 (c). You may comprise by a dome shape. Further, it may be configured as a multi-face type as shown in FIG. 3D combined with a flat type display, or may be configured as a head-mounted type such as a head-mounted display. The multi-face type is formed of a polygon and the number of faces is not limited to three.

  The flat type display has a feature capable of presenting a high-resolution video. The arch type and the dome type have a feature that a wide-field image can be presented because the field of view can be effectively covered. The multi-sided display has a feature capable of presenting an image with a high resolution and a wide field of view. Furthermore, the head-mounted display has a feature that enables video presentation that is not affected by external light. In addition, since this visual function inspection device uses the viewpoint distance as an input value, it is possible to fix the observer's head by mounting a chin or the like so that the viewpoint position (observer's head position) does not fluctuate. desirable.

  The control device 1 includes a visual function test item selection unit 11, a target image generation unit 12, a target image drawing unit 13, a viewpoint distance input unit 14, and a viewing angle input unit 15. Each of these units is realized by the CPU executing a program or the like stored in the ROM.

  The visual function test item selection unit 11 selects a visual function test item. As the visual function test item of FIG. 1, either binocular visual acuity or binocular visual field is selected. The visual function test item selection unit 11 includes, for example, a keyboard for operating the control device 1. The visual function test item selection unit 11 performs an operation for selecting one of the visual function test items displayed on the visual target image presentation unit 2 on the keyboard. Accordingly, the visual function test item selection unit 11 supplies the selected visual function test item information to the visual target image generation unit 12.

  The visual target image generation unit 12 generates a visual target image corresponding to the inspection item selected by the visual function inspection item selection unit 11. The target image generation unit 12 outputs the target image selected by the visual function test item selection unit 11 among the plurality of target images stored in advance to the target image drawing unit 13. In addition, the target image generation unit 12 may generate a new target image every time a visual function test item is selected. In addition, when using a Landolt ring or a complicated pattern (animal drawing, text, etc.) as a visual target image, it is desirable to create it beforehand. Simple symbols such as light spots may be generated in real time.

  When the visual acuity test is selected, the visual target image generation unit 12 generates a Landolt ring as shown in FIG. The Landolt ring is a partially cut circle and is a standard visual target for visual acuity testing. When a 1.5 mm wide cut of a Landolt ring with a diameter of 7.5 millimeters (mm) can be seen from a location 5 m away, its visual acuity is 1.0. When the visual field inspection is selected, the target image generation unit 12 generates a light spot as shown in FIG. As will be described later, the display size C of this visual target image is adjusted.

  The viewpoint distance input unit 14 inputs the distance between the visual target image presentation unit 2 and the observer's viewpoint. The viewpoint distance input unit 14 includes, for example, a keyboard that operates the control device 1. The viewpoint distance input unit 14 inputs the viewpoint distance between the observer's viewpoint position and the visual target image presentation unit 2 to the keyboard. Thereby, the viewpoint distance input unit 14 supplies the input viewpoint distance to the visual target image drawing unit 13.

  The viewing angle input unit 15 inputs an angle formed by the target image and the observer's viewpoint. That is, the viewing angle required for the observer to view the target image is input. The viewing angle input unit 15 includes, for example, a keyboard that operates the control device 1. The viewing angle input unit 15 inputs a viewing angle to the keyboard. Thereby, the viewing angle input unit 15 supplies the input viewing angle to the visual target image drawing unit 13.

  The target image drawing unit 13 draws a target image to be presented to the target image presenting unit 2. At this time, the visual target image drawing unit 13 selects the visual acuity test or visual field selected by the visual function test item selection unit 11 based on the viewpoint distance input by the viewpoint distance input unit 14 and the visual angle input by the visual angle input unit 15. The display size and display position of the target image corresponding to the examination are calculated. Then, the visual target image drawing unit 13 draws the visual target image at the calculated display size and display position. Thereby, the target image presenting unit 2 displays the target image having a display size corresponding to the input viewpoint distance and viewing angle at the display position of the target image presenting unit 2 corresponding to the input viewpoint distance and viewing angle. be able to.

[Display size calculation]
Next, processing for calculating the display size of the target image based on the viewpoint distance and the viewing angle will be described.

As shown in FIG. 5, from a viewpoint distance A between the observer's viewpoint position P and the presentation surface 2 a of the target image presentation unit 2, and a trigonometric function (expression 1a, expression 1b) of the horizontal and vertical viewing angles θ. The horizontal size B and vertical size B of the visual target image presented on the presentation surface 2a of the visual target image presentation unit 2 are calculated. This equation 1 is expressed by assuming that the horizontal size [mm] is B _W , the vertical size [mm] is B _H , the horizontal viewing angle [degree] is θ _W , and the vertical viewing angle [degree] is θ _H. ,
B _W = 2 × A × tan (θ _W / 2) (Formula 1a)
B _H = 2 × A × tan (θ _H / 2) (Formula 1b)
It becomes. In FIG. 5, the screen of the visual target image presentation unit 2 other than the viewing angle θ of the observer is shown as a non-presentation surface 2 b.

  When the target image is a square, the display size C may be determined using the viewing angle in at least one of the vertical and horizontal directions input by the viewing angle input unit 15. However, when the target image has a shape other than a square, in order to determine the display size C of the target image, it is necessary to input both the vertical and horizontal viewing angles by the viewing angle input unit 15. Alternatively, it is necessary to input a viewing angle in one direction using the viewing angle input unit 15 and further input an aspect ratio (such as 4: 3) by other means to determine the display size C of the target image having a shape other than a square. There is.

When the size of the target image generated by the target image generation unit 12 is specified as the display size C [mm] in the horizontal direction and the vertical direction as shown in FIG. The display magnification D [%] of the visual target image presented on the presentation surface 2a of the visual target image presentation unit 2 is calculated by Equation 2b. In Equation 2, the horizontal size [mm] is C _W , the vertical size [mm] is C _H , the horizontal display magnification [%] of the target image is D _W , and the vertical display magnification. [%] Is _DH . The size B _{W in} the horizontal direction and the size B _{H in the} vertical direction are obtained by Equation ₁ .
D _W = B _W / C _W (Formula 2a)
D _H = B _H / C _H (Formula 2b)

  The visual target image drawing unit 13 can present a display size C corresponding to the visual angle input by the visual angle input unit 15 on the visual target image presentation unit 2 by rendering the visual target image at the display magnification D. Thereby, even if the resolution of the visual target image presentation unit 2 is different, the visual function inspection device has a display size corresponding to the visual angle θ and the visual point distance according to the size of the pixel of the visual target image presentation unit 2. The target image can be presented.

In some cases, the size of the target image generated by the target image generation unit 12 is specified with a resolution E [vertical pixel × horizontal pixel] in the horizontal and vertical directions. In this case, based on the horizontal and vertical screen dimensions F [mm] of the visual target image presentation unit 2 and the horizontal and vertical screen resolutions G of the visual target image presentation unit 2, the length C of the visual target image is displayed. Is calculated by Equation 3. In Equation 3, the horizontal resolution of the target video is E _W , the vertical resolution is E _H , the horizontal screen size of the target video presentation unit 2 is F _W , and the vertical screen size is F _H. The horizontal screen resolution of the standard image presentation means is GW, and the vertical screen resolution is GH.
C _W = E _W × F _W / G _W (Formula 3a)
C _H = E _H × F _H / G _H (Formula 3b)

  The target image drawing unit 13 substitutes the display size C calculated by Equation 3 into Equation 2. Thereby, the target image drawing unit 13 can calculate the display magnification D of the target image presented on the screen of the target image presenting unit 2. The target image drawing unit 13 can present the target image with the display size C corresponding to the viewing angle by drawing the target image at the calculated magnification.

[Display position calculation]
Next, a process for calculating the display position of the target image based on the viewpoint distance and the viewing angle will be described.

As shown in FIG. 6, the display position of the target image is specified by an XY coordinate system with the screen center of the target image presenting unit 2 as the origin. FIG. 6 shows a state in which the observer's viewpoint position P is directly opposed to the screen center C (X ₀ , Y ₀ ) on the presentation surface 2 a of the target image presentation unit 2. The viewpoint distance between the viewpoint position P and the screen center C is A. Intersections 2a-1 to 2a between the range 2a 'represented by the viewing angles θ _W (horizontal direction) and θ _H (vertical direction) of the observer and the X axis and the Y axis on the presentation surface 2a of the target image presentation unit 2 The coordinate value (X, Y) of −4 is calculated from the following formula 4.
X = ± A × tan (θ _w / 2) −X0 (Formula 4a)
Y = ± A × tan (θ _H / 2) −Y 0 (Formula 4b)

According to Expression 4, the coordinate value X ₁ of a total of four intersections 2a-3 with two positive and negative on the X axis and the Y axis centering on the screen center C (origin) on the presentation surface 2a of the visual target image presentation unit 2 The coordinate value X _{2 of} the intersection 2a-4, the coordinate value Y1 of the intersection 2a-1, and the coordinate value Y2 of the intersection 2a-2 can be calculated.

As shown in FIG. 7, the origin that is the screen center C on the presentation surface 2 a of the visual target video presentation unit 2 and the four coordinate values [(X ₁ , 0), (X ₂ , 0) calculated by Equation 4 are used. A grid-like grid line 2c based on the grid formed by (0, Y ₁ ), (0, Y ₂ )] is set. The coordinates on the X and Y axes that are one square away from the origin are the boundaries of the viewing angle θ of the viewing angle θ with the origin as the gazing point. The coordinates on the X and Y axes that are two squares away from the origin serve as the boundary of the viewing angle of the viewing angle 2θ with the origin as the gazing point. That is, by setting each grid point on the grid line 2c to the display position of the target image, the X axis and the Y axis are based on the viewpoint distance and the viewing angle input by the viewpoint distance input unit 14 and the viewing angle input unit 15. The unit grid width for can be calculated to form a rectangular coordinate system. Thereafter, the target image drawing unit 13 may specify on which lattice point the target image is to be displayed.

  In this visual function testing device, the input values of the viewing angle in the horizontal direction (X-axis direction) and the vertical direction (Y-axis direction) with respect to the viewing angle input unit 15 may be set individually. When both the horizontal (X-axis direction) and the vertical (Y-axis direction) viewing angles input by the viewing angle input unit 15 are the same, the shape of the grid formed by the grid lines 2c is a square. When the viewing angles in the horizontal direction (X-axis direction) and the vertical direction (Y-axis direction) input by the viewing angle input unit 15 are different, the shape of the grid formed by the grid lines 2c is a rectangle.

The origin of the presentation surface 2a is not limited to the screen center C on the presentation surface 2a of the visual target image presentation unit 2. For example, as shown in FIG. 8A, the position C on the presentation surface 2a that faces the center position E _C of the left eye position E _L and the right eye position E _R of both eyes may be set as the origin. Further, as shown in FIG. 8B, the origin may be set at a position C on the presentation surface 2a that faces the left eye position E _L or the right eye position E _R. Furthermore, the origin may be set at an arbitrary position on the presentation surface 2a. In this way, when the origin is set, the unit cell width is calculated by calculating the distance difference between the newly set origin and the screen center C on the presentation surface 2a of the target image presentation unit 2 by Equation 4. Adapt to two coordinate values (X ₁ , X ₂ , Y ₁ , Y ₂ ). That is, the distance difference in the X-axis direction is added to Expression 4a, and the distance difference in the Y-axis direction is added to Expression 4b.

[Vision test]
Next, the visual acuity test by the above-described visual function testing device will be described.

  The visual acuity test is an inspection method that evaluates the ability to separate and recognize two points or two lines (minimum separation area). An angle formed by two points or two lines that can barely be discerned by the eye with respect to the eye is represented by “minute (= 1/60 degree)”, and the reciprocal thereof is evaluated as visual acuity. As an existing inspection method, the visual acuity becomes 1.0 when a land cut with a diameter of 7.5 mm and a thickness of 1.5 mm can be seen from a location where a 1.5 mm wide cut is 5 m away. In this case, as shown in FIG. 9, a 1.5 mm cut corresponds to 1 minute of the viewing angle.

  In the visual acuity test, the control device 1 sets the display size and the display position of the target image (for example, the Landolt ring) based on the viewpoint distance input by the viewpoint distance input unit 14 and the viewing angle input by the viewing angle input unit 15. To do. As the display size, a size corresponding to the visual acuity is set. Although the display position may be set to an arbitrary position, the center position of the target image presentation unit 2 is desirable. Note that the visual function test described above performs a binocular visual acuity test as a visual acuity test because there is no shielding function for presenting a target image for each eye. One-eye visual acuity inspection can be realized by a visual function inspection device described later.

  In the visual acuity test of the visual function testing device of the present embodiment, the separation width between two points or two lines is set by the visual angle θ corresponding to the visual acuity J as shown in the following formula 5. The viewing angle θ is input by the viewing angle input unit 15. Then, the visual function testing device presents a visual target image having a display size C suitable for the visual angle θ to the visual target image presentation unit 2.

J = 1 / θ (Formula 5)
Further, the visual function testing device adds a function of calculating the visual angle θ from the visual acuity J by the inverse calculation of Expression 5. Thereby, the display size C can be calculated from the visual acuity J.

  Below, a Landolt ring having a diameter of 7.5 mm, a thickness of 1.5 mm, and a cut of 1.5 mm is viewed with a cut of 1.5 mm from the viewpoint distance Am as a visual angle of 1 minute (display capable of inspecting a visual acuity of 1.0). Size) how to display. Here, the Landolt ring is generated by the visual target image generation unit 12 in response to the visual function test item selection unit 11 selecting the visual acuity test.

(1) When the target image is generated by the target image generator 12, the size of the target image (Landolt ring) is designated by the length C. At this time, from the viewpoint distance input by the viewpoint distance input unit 14, the target image presentation unit 2 is viewed and the display magnification D is calculated as follows for measuring the desired visual acuity.

  In a general visual acuity test, the width (separation width) of the cut of the Landolt ring is 1.5 mm, and the diameter of the Landolt ring is defined as 7.5 mm (5 times). Therefore, in order to display the Landolt ring break on the visual target image presentation unit 2 at a visual angle of 1 minute (1/60 degrees), the visual image of the Landolt ring may be displayed at a visual angle of 5 minutes (5 times). . The size B of the visual target image viewed from the viewpoint distance Am at a viewing angle of 5 minutes is calculated from Equation 1 using the viewing angle θ = 5 minutes. When the target image is a Landolt ring, the length B in the horizontal direction and the vertical direction of the Landolt ring is the same, and only one direction needs to be obtained. Then, the display magnification D of the Landolt ring in the visual target image presentation unit 2 is calculated by the following equation (2) using the length B of the visual target image and the size C of the designated visual target image.

(2) When the target image is generated by the target image generator 12, the size of the target image (Landolt ring) is designated by the image resolution E. At this time, from the viewpoint distance input by the viewpoint distance input unit 14, the target image presentation unit 2 is viewed and the display magnification D is calculated as follows for measuring the desired visual acuity.

  Similar to (1), the size B of the visual target image viewed from the viewpoint distance Am with a viewing angle θ of 5 minutes is calculated by Equation 1. In the case of a landmark image of the Landolt ring, the length B in the horizontal direction and the vertical direction of the Landolt ring is equal, and only one direction needs to be obtained. From Expression 3, the size B of the target image specified by the video resolution E is converted into the display size C from the screen size F and the screen resolution G of the target image presentation unit 2, and the target image is further expressed by Expression 2. The display magnification D is calculated from the size B and the display size C.

  If the separation width (cut) of the visual target (Landolt ring) displayed on the visual target image presentation unit 2 can be perceived at the display magnification D calculated in (1) or (2), the visual acuity becomes 1.0. . In order to obtain the same inspection conditions as the current visual acuity test, the viewpoint distance A between the visual target image presentation unit 2 and the observer may be set to 5 m.

[Field inspection]
The visual field inspection is an inspection for measuring a visual sensitivity distribution map based on the response of the subject to the target presentation. In this visual field inspection, the visual function inspection device measures a perceivable range without moving the eyes. The visual field measurement methods include dynamic visual field measurement and static visual field measurement. In the dynamic visual field measurement, a target is moved and an area showing a certain sensitivity is measured. In static visual field measurement, the sensitivity is measured at a fixed point without moving the target.

  In the visual field inspection, the control device 1 displays the display size and the display position of the target image (for example, a light spot) based on the viewpoint distance input by the viewpoint distance input unit 14 and the viewing angle value input by the viewing angle input unit 15. Set. The display size may be set at an arbitrary viewing angle. The display position is set on a grid with the fixed viewpoint as the origin, and the grid width is set by the viewpoint distance and the viewing angle. In addition, since the above-mentioned visual function test | inspection does not have the shielding function which presents a target image | video for every eye, a binocular visual field test | inspection is implemented as a visual field test | inspection. The single-eye visual field inspection can be realized by a visual function inspection device described later.

  In the visual field inspection of the visual function inspection device of the present embodiment, as shown in FIG. 10, the observer displays a fixed viewpoint D as the origin on the target image presentation unit 2. The observer watches this fixed viewpoint D. In this manner, with the observer's viewpoint fixed, the target E (light spot) is displayed at a grid-like position with the fixed viewpoint D as the origin. Thereby, the visual function inspection device inspects whether or not the observer can perceive the visual target E.

  The fixed viewpoint D and the target E as the origin are displayed on the intersection of the grid lines 2c having the grid width K formed on the target video presentation unit 2. The lattice line 2c is the same as that shown in FIG. The lattice width K is calculated according to the above equation 4 (X (Y) = ± A × tan (θ / 2) −X (Y)) based on the viewpoint distance A and the viewing angle θ.

  In addition, regarding the target position set on the intersection of the grid lines 2c, the visual function testing device can arbitrarily set the display order of the target. In other words, the visual function testing device can display the target image in a random display order within the range of the visual field to be measured. Furthermore, the visual function inspection device may limit the display position of each visual target image to an arbitrary range.

  Furthermore, this visual function inspection device generates a plurality of targets (light spots) having an arbitrary display size and luminance value in the same manner as the quantitative dynamic visual field inspection, and changes the size and luminance of the target. A visual field inspection may be performed. Thereby, the visual function test | inspection apparatus can test | inspect the perceptual sensitivity in a visual field test | inspection.

  Note that the display position of the visual target image in the visual acuity test is performed by designating grid points for displaying the visual target image, as in the visual field inspection. In a normal visual acuity test, a visual acuity target (Landolt ring) is displayed at the screen center C of the visual target image presentation unit 2, but may be displayed at a position away from the screen center C in the course of the visual acuity test. For example, when examining the visual acuity when facing upward, a Landolt ring is displayed on a lattice point shifted upward from the screen center C.

  As described above, according to the visual function testing device shown as the first embodiment, the display size and the display position of the target image are calculated based on the viewpoint distance and the viewing angle, and the target image is drawn. A plurality of visual function tests can be performed with the same apparatus in a state in which both eyes are opened and a daily appearance that does not limit the field of view is close to, without blocking or limiting the field of view.

[Second Embodiment]
Next, a visual function testing device according to the second embodiment will be described. In addition, about the part similar to the above-mentioned 1st Embodiment, the detailed description is abbreviate | omitted by attaching | subjecting the same code | symbol.

  The visual function testing device shown as the second embodiment can perform one-eye visual acuity, one-eye visual field, and stereoscopic vision testing in addition to the visual function testing device shown as the first embodiment described above. .

  As shown in FIG. 11, this visual function inspection device is different from the visual function inspection device described above in that the control device 1 includes a target image selection / presentation unit 20. Further, in this visual function testing device, the visual target image generating unit 12 has a binocular visual target image generating function for generating a visual target image for each of the right eye and the left eye of the subject. Further, the target image presentation unit 2 separates the right and left eye binocular target images generated by the binocular target image generation function of the target image generation unit 12 for each corresponding eye. It has a binocular separation target video presentation function to present.

  The visual target image presentation unit 2 can separate and visually recognize the visual image for the right eye and the visual image for the left eye by the observer's right eye and left eye, respectively. The target image presentation unit 2 may be composed of a display and a projection system using a current binocular separation method such as a polarization method, a spectroscopic method, a time division method, etc., or a head mounted type such as a head mounted display. You may comprise. The observer wears glasses corresponding to the method adopted by the visual target image presentation unit 2. As a result, the visual function testing device has a binocular separation function that presents different visual target images to the right and left eyes of the observer.

  The target image selection / presentation unit 20 selects display or non-display independently for each right-eye or left-eye target image presented by the binocular separated target image presentation function of the target image presentation unit 2. . The target image selection / presentation unit 20 includes, for example, a keyboard for operating the control device 1. The target image selection / presentation unit 20 performs an operation on the keyboard to select display or non-display of the right-eye or left-eye target image displayed on the target image presentation unit 2. As a result, the target image selection / presentation unit 20 supplies the selected display or non-display information to the target image generation unit 12.

  In such a visual function inspection device, the visual target image selection / presentation unit 20 displays a visual target image corresponding to the one-eye vision test, the one-eye visual field test, or the stereoscopic vision test selected by the visual function test item selection unit 11. To do.

  Specifically, in the visual function testing device, the visual function test item selection unit 11 selects a single-eye visual test, a single-eye visual field test, or a stereoscopic test. Then, the target image generation unit 12 generates a right eye target image and a left eye target image corresponding to the selected examination (a binocular target image generation function).

  When the visual function test for only one eye is selected by the visual target image selection / presentation unit 20, the visual target image generation unit 12 generates the selected right eye target image or left eye target image. To the target image drawing unit 13. When the stereoscopic vision inspection is selected, the target image generation unit 12 generates both a right eye target image and a left eye target image and supplies them to the target image drawing unit 13.

  The target image generation unit 12 generates both a right-eye target image and a left-eye target image, and uses the one-side target image selected as non-display by the target image selection / presentation unit 20 as a background color. A blank video of the same color is used.

  The target image selection / presentation unit 20 may be connected to the target image drawing unit 13 to draw only the right-eye target image or the left-eye target image. Further, the target image selection / presentation unit 20 may be connected to the target image display unit 2 and display only the right-eye target image or the left-eye target image.

  The visual target video drawing unit 13 draws the right eye visual target image and the left eye visual target image supplied from the visual target image generating unit 12 (binocular separated video drawing function). The drawing data corresponding to the right-eye target image and the drawing data corresponding to the left-eye target image are supplied to the target image presentation unit 2.

  The target image presentation unit 2 displays the right eye target image and the left eye target image using drawing data corresponding to the right eye target image and the left eye target image (both images). Eye separation video presentation function). Thereby, the right-eye target image is visually recognized only by the right eye of the observer, and the left-eye target image is visually recognized only by the left eye of the observer.

  In such a visual function inspection device, the one-eye visual acuity test and the one-eye visual field inspection are performed in the same manner as the visual function inspection device described above for generating a target image and setting the display size and display position. Then, according to the selection of the visual target image selection / presentation unit 20, the visual target image for the right eye or the visual target image for the left eye is made visible, thereby realizing a one-eye vision test and a single-eye visual field test.

  Next, stereoscopic vision inspection by the visual function inspection device shown in FIG. 11 will be described. In the stereoscopic examination, a relative depth sensation caused by fusing images with binocular parallax presented to the left and right eyes is examined. This parallax is a change in the position of the image on the retina due to a movement or difference in the relative position between the eyes and the object. With this parallax, it is possible to perceive the distance of the object with binocular parallax, which is represented by the angle between the eyes of both eyes.

  In the stereoscopic vision inspection, the display size C of the target image may be set to an arbitrary size B based on the viewing angle input by the viewing angle input unit 15. Further, in the stereoscopic inspection, the display position is set based on the viewing angle input by the viewing angle input unit 15 with the center-to-center distance (parallax) between the left-eye and right-eye target images.

  As shown in FIG. 12, the stereoscopic inspection of this visual function inspection device is performed by using one target image 100d, 100d among a plurality of binocular separated target images 100a to 100d presented on the target image presentation unit 2. 'Attach any amount of parallax between.

  The display size C of the visual target image 100 is calculated by the above formula 2 or 3 by setting an arbitrary size according to the viewing angle θ input by the viewing angle input unit 15. Further, as shown in FIG. 13, the parallax amount for recognizing stereoscopic vision is set as the viewing angle θ input by the viewing angle input unit 15, and the display position is calculated by the viewpoint distance A input by the viewpoint distance input unit 14. Is done. As described above, the visual function inspection device can adjust the distance between the target images 100d and 100d ′ for inspecting the stereoscopic vision by inputting the viewing angle θ and the viewpoint distance A. Thereby, the function of stereoscopic vision can be inspected based on the presence or absence of relative depth perception with respect to a minute amount of parallax.

  According to this visual function testing device, the binocular separated video presentation function of the visual target video presentation unit 2 can test the function of one-eye visual acuity and the one-eye visual field in a binocular open state without restricting the visual field, and Stereoscopic inspection can be performed with the same device.

[Third Embodiment]
Next, a visual function testing device according to the third embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  In addition to the visual function testing device shown as the second embodiment described above, this visual function testing device can perform binocular vision and visual position visual function testing.

  The binocular vision examination is an examination that evaluates whether or not the image given to the retina of each eye of the left and right eyes can be seen as a single vision in the visual center (brain). Simultaneous vision, fusion (sensory, motility) ), Inspection is performed for each item such as stereoscopic vision and retina correspondence.

  Simultaneous viewing refers to the ability to recognize the two types of images A and B as one image when viewing the image A with the right eye and the image B with the left eye. Stereoscopic vision is the ability to see an object in three dimensions by recognizing parallax caused by the difference between the positions of the left and right eyes. The fusion is further classified into a motor fusion and a sensory fusion. Motor fusion is the ability to recognize the left-eye image and the right-eye image presented as separate images as a single image by eye movements of convergence (cross-eye) and divergent (separation). . Sensory fusion is the ability to recognize the same image presented to the left and right eyes as a single image by changing the appearance of the same image depending on the size and blur difference.

  For example, in the sensory fusion test, for the inspection of the size difference of the target size shown in FIG. 14 (inequality image test) and the test of the difference in target blur shown in FIG. A target visual image and a left-eye visual target image are generated. Then, similar to the visual function inspection device shown as the second embodiment described above, the visual image for right eye and the visual image for left eye generated by the visual function inspection item selection unit 11 are displayed by the visual image drawing unit 13. Drawing is performed, and the target image presentation unit 2 displays the target image for the right eye and the target image for the left eye by a predetermined binocular separation method. Accordingly, the visual function testing device causes the right-eye target image to be visually recognized only by the observer's right eye, and allows the left-eye target image to be visually recognized only by the observer's left eye.

  As shown in FIG. 16, the visual function inspection device includes a visual target image operation unit 21. The visual target image operating unit 21 changes at least one of the display size or the display position of the visual target image by a user operation. The target image operation unit 21 includes an operation device such as a mouse or a button operated by the user, and the user moves the target image presented by the target image presentation unit 2 in accordance with the appearance of the target image. The signal to be output is output. Then, the target image drawing unit 13 updates the position of the target image presented to the target image presenting unit 2 based on the signal supplied from the target image operation unit 21.

  In such a visual function inspection device, a binocular visual inspection or an eye position test is selected by the visual function inspection item selection unit 11. In this case, the visual target image drawing unit 13 looks at the display size and display position calculated by the visual target image drawing unit 13 according to the display size or display position of the visual target image changed by the visual target image operation unit 21. Change the target video and draw.

  As described above, according to the visual function testing device shown as the third embodiment, the display size and display position of the target image can be changed by a user operation. Thereby, the visual function inspection apparatus can perform binocular visual inspection (simultaneous visual inspection, motility fusion inspection, sensory fusion inspection) and eye position inspection with a single device. Note that the grid lines to be displayed in the eye position examination are displayed on the presentation surface 2a as in the visual function testing apparatus shown as the first embodiment.

[Fourth Embodiment]
Next, a visual function testing device according to the fourth embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  In addition to the visual function inspection device shown as the above-described embodiment, this visual function inspection device adjusts the appearance of the target image presented on the target image presentation unit 2 as shown in FIG. Part 22.

  The visual target image adjustment unit 22 can adjust the luminance, contrast, color, or transparency of the visual target image. The target image adjusting unit 22 supplies a control signal for adjusting the luminance, contrast, color, or transparency of the target image to the target image generating unit 12. The visual target image adjustment unit 22 includes an operation device such as a keyboard and a mouse. The visual target image adjustment unit 22 adjusts the visual target image by performing an operation while viewing the visual target image displayed on the visual target image presentation unit 2 by the user.

  The target image generation unit 12 determines the luminance, contrast, color, or transparency of the target image generated according to the selection of the visual function test item selection unit 11 based on the control signal supplied from the target image adjustment unit 22. adjust. The adjusted visual target image is supplied to the visual target image drawing unit 13, drawn, and presented to the visual target image presentation unit 2.

  According to such a visual function inspection device, the sensitivity of the visual function due to the change of the visual target image can be inspected by adjusting the luminance, contrast, color, and transparency of the visual target image by a user operation.

[Fifth Embodiment]
Next, a visual function testing device according to the fifth embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 18, this visual function testing device includes a viewpoint distance calculation unit 23 instead of the viewpoint distance input unit 14, and further includes a viewing angle input unit 24.

  In this visual function inspection device, when a visual field inspection is selected by the visual function inspection item selection unit 11, the visual field angle input unit 24 inputs a visual field angle to be inspected by the visual field inspection. The viewing angle input unit 24 includes, for example, a keyboard, a mouse, a remote control, etc. operated by the user, and inputs a viewing angle that the user wants to inspect.

  The viewpoint distance calculation unit 23 calculates the viewpoint distance necessary for performing the visual field inspection at the visual field angle input by the visual field angle input unit 24 in the screen size of the target image presentation unit 2. At this time, the viewpoint distance calculation unit 23 inputs θ as the viewing angle from the viewing angle input unit 24 as shown in Expression 1 (B = 2 × A × tan (θ / 2)). In response to this, the viewpoint distance calculation unit 23 calculates the viewpoint distance A by calculating Equation 1 using θ as the viewing angle.

  As described above, the visual function testing device can present to the user a viewing distance at which the viewing angle can be examined according to the selection of the viewing test and the input of the viewing angle to be examined. Thereby, the visual function inspection device can prompt the user to bring the viewpoint position P closer to the visual target image presentation unit 2 when it is desired to inspect a wide viewing angle. Therefore, according to this visual function inspection device, visual field inspection can be performed by a simple operation without setting complicated conditions.

[Sixth Embodiment]
Next, a visual function testing device according to the sixth embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 19, this visual function testing device includes a viewpoint distance calculation unit 23 instead of the viewpoint distance input unit 14, and further includes a visual acuity input unit 25.

  The visual acuity input unit 25 inputs visual acuity used in the visual acuity test when the visual acuity test item selection unit 11 selects the visual acuity test. The viewing angle input unit 24 includes, for example, a keyboard, a mouse, a remote controller, and the like operated by the user, and inputs a visual acuity that the user wants to examine.

  The viewpoint distance calculation unit 23 calculates a viewpoint distance A required for performing a visual acuity test with the visual acuity input by the visual acuity input unit 25 in the resolution of the visual target image presentation unit 2. The viewpoint distance calculation unit 23 needs to set a shorter viewpoint distance A as the visual acuity to be examined is lower and to calculate a longer viewpoint distance A as the visual acuity to be examined is higher.

  The video presentation resolution of the image presented by the visual function inspection device needs to satisfy a predetermined visual acuity conversion value H. This visual acuity conversion value H is a value indicating how much visual acuity corresponds to one pixel of the visual target image presentation unit 2. The visual acuity conversion value H becomes higher as the video presentation resolution of the visual target video presentation unit 2 is higher because a fine visual target video can be presented.

  In order to measure the visual acuity desired by the observer, the resolution of the visual target image presentation unit 2 for distinguishing by the visual acuity is required. Therefore, when the observer wants to measure high visual acuity, a high resolution of the visual target image presentation unit 2 is required. A method for calculating the visual acuity conversion value H will be described below.

  Visual acuity is the spatial resolution of the viewing angle. Here, as shown in FIG. 5, an angle formed with respect to the viewpoint position P (hereinafter, viewing angle) is θ. The viewing angle uses “minute” as a unit, and “second” obtained by dividing the “minute” into 1/60. This value is “60 minutes” when the viewing angle θ is 1 degree.

  Usually, the minimum value (minimum separation area) of the distance between two identifiable objects is represented by the viewing angle, and the reciprocal thereof is the visual acuity value. In other words, the visual acuity that can distinguish the 1-minute interval in terms of viewing angle is 1.0, and if the 0.5-minute interval can be distinguished, the visual acuity value is 2.0, and only the 2-minute interval can be distinguished. Otherwise, the visual acuity value is 0.5.

  When such a relationship between visual acuity and visual angle is applied to the video presentation resolution displayed by the visual function testing device, the minimum separation area is represented by the size of one pixel. The reciprocal of the viewing angle (unit: minute) with respect to the size of one pixel is the visual acuity.

  Therefore, the visual acuity conversion value (J) obtained by converting the video display resolution into visual acuity is defined by the video presentation viewing angle θ [degree] and the video presentation resolution X [pixel] as shown in the following Expression 6.

J = 1 / ((θ × 60) / X) = X / (θ × 60) (Formula 6)
The video presentation viewing angle θ [degree] in Expression 6 representing the visual acuity conversion value J is expressed by Expressions 7 and 8 depending on the width B [mm] of the presentation surface 2a and the distance A [mm] between the observer and the presentation surface 2a. Is defined as follows.

tan (θ / 2) = (B / 2) / D = B / 2A (Expression 7)
θ = 2 × tan ⁻¹ (B / 2A) (Formula 8)
Then, when the viewing angle θ of Expression 8 is substituted into Expression 6, the visual acuity converted value H is expressed as Expression 9 below.
H = X / (2 × tan ⁻¹ (B / 2A) × 60) = X / (120 × tan ⁻¹ (B / 2A))
(Formula 9)

That is, the video presentation resolution X is as shown in Equation 10 below.
X = 120 × H × tan ⁻¹ (B / 2H) (Formula 10)
It becomes. As described above, if the visual acuity converted value H to be displayed, the width B of the presentation surface 2a, and the distance A between the observer and the presentation surface 2a are specified, the video presentation resolution X is uniquely determined by Expression 10.

  According to this visual function testing device, if an observer inputs a visual acuity (visual acuity conversion value) to be examined by visual acuity examination, it is possible to present a viewpoint distance A for securing a distance that allows the visual acuity examination. . Therefore, according to this visual function inspection device, it is possible to perform visual acuity inspection with a simple operation without setting complicated conditions.

[Seventh Embodiment]
Next, a visual function testing device according to the seventh embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 20, the visual function inspection device includes a viewpoint distance calculation unit 23 instead of the viewpoint distance input unit 14, and further includes a parallax input unit 26.

  The parallax input unit 26 inputs parallax to be used in the stereoscopic inspection when the stereoscopic inspection is selected by the visual function inspection item selection unit 11. The parallax input unit 26 includes, for example, a keyboard, a mouse, a remote controller, and the like operated by the user, and inputs parallax that the user wants to inspect.

  The viewpoint distance calculation unit 23 calculates the viewpoint distance A required for performing the stereoscopic vision inspection with the parallax input by the parallax input unit 26 at the resolution of the target image presentation unit 2. At this time, the visual function testing device can calculate the minimum presentation viewing angle with respect to the viewpoint distance A between the viewpoint position P and the presentation surface 2a by the reciprocal of the visual acuity conversion value H in the sixth embodiment. The viewpoint distance calculation unit 23 needs to set a longer viewpoint distance A as the parallax to be inspected is smaller, and calculate a shorter viewpoint distance A as the parallax to be inspected is larger.

  In such a visual function inspection device, when the observer inputs parallax to be measured by the parallax input unit 26, the viewpoint distance calculation unit 23 obtains the viewpoint distance A at which the parallax can be measured, and the parallax to be examined. The viewpoint distance A to be secured can be presented to the observer. Therefore, according to this visual function inspection device, a stereoscopic inspection can be performed by a simple operation without setting complicated conditions.

[Eighth Embodiment]
Next, a visual function testing device according to the eighth embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 21, this visual function inspection device includes a viewpoint distance measuring unit 27 with respect to the visual function inspection device described as the first embodiment. This viewpoint distance measurement unit 27 measures the distance between the target image presentation unit 2 and the observer's viewpoint position P. The viewpoint distance measurement unit 27 inputs the measured current viewpoint position P to the viewpoint distance input unit 14. For example, the viewpoint distance measurement unit 27 measures the head position of the observer and calculates the viewpoint distance from the head position. Alternatively, the viewpoint distance measurement unit 27 may be configured by a distance sensor provided in binocular separation glasses worn by an observer. Thereby, the viewpoint distance input unit 14 can automatically input the viewpoint distance.

  Thus, according to the visual function inspection device, it is possible to perform a visual function inspection corresponding to the observer's head position or the actual viewpoint position P without having to specify the viewpoint position P in advance. Further, according to this visual function inspection device, in the embodiment shown in FIGS. 18 to 20 described above, the necessary viewpoint distance A is calculated according to the viewing angle, visual acuity, and parallax that require inspection. Conversely, the viewing angle, visual acuity, and parallax that can be inspected with respect to the current viewpoint distance A can be presented.

[Ninth Embodiment]
Next, a visual function testing device according to the ninth embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 22, in addition to the visual function inspection device of the second embodiment described above, this visual function inspection device includes a target image selection storage unit 28, a target image storage unit 29, a display setting storage unit 30, And the display order setting part 31 is provided.

  The target image storage unit 29 stores the target image generated by the target image generation unit 12.

  The display setting storage unit 30 stores the display size and display position of the target image calculated using the viewpoint position P input by the viewpoint distance input unit 14 and the viewing angle input by the viewing angle input unit 15.

  The target image selection storage unit 28 stores the display or non-display of the target image for each right eye and left eye set by the target image selection and presentation unit 20.

  The display order setting unit 31 includes information on display or non-display of the target video for each of the right eye and the left eye stored in the target video selection storage unit 28, the target video stored in the target video storage unit 29, The display size and display position of the target image stored in the display setting storage unit 30 are input. And the display order setting part 31 sets the display order of a target image | video using these data.

  The display order setting unit 31 presents a visual target image corresponding to each visual function test item so as to perform a plurality of visual function test items in an order programmed in advance, for example. Moreover, the visual target image of each visual function test item corresponds to the viewing angle, visual acuity, and parallax previously set by the observer, and is in a display state selected by the visual target image selection / presentation unit 20.

  In the visual function testing device, according to the display order set by the display order setting unit 31, the display order setting unit 31 calls the target image stored in the target image storage unit 29 and draws it by the target image drawing unit 13. To do. Thereby, the visual function test | inspection apparatus can program the test order of a some test | inspection item, and can implement the function which can implement the screening test | inspection of a several visual function in a short time. Therefore, this visual function inspection device, for example, when it is desired to inspect the visual function after viewing a content video such as a movie by the visual target image presentation unit 2, only starts the screening inspection, and a plurality of visual function inspection items. The visual function test can be performed by presenting the target visual image.

[Tenth embodiment]
Next, a visual function testing device according to the tenth embodiment will be described. Note that parts similar to those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 23, this visual function testing apparatus outputs a test result output that outputs a test result of a visual function test selected by the visual function test item selection unit 11 in addition to the visual function test apparatus of the embodiment described above. The unit 32 is provided. The test result output unit 32 outputs a test result corresponding to each visual function test item that can be performed by the visual function testing device in a predetermined format. This predetermined format is a format in which inspection results of a plurality of visual function inspection items in accordance with preset current inspection contents can be viewed on printing paper.

  Such a visual function inspection device presents target images of a plurality of visual function inspection items in a predetermined order like the visual function inspection device shown as the ninth embodiment, for example, according to the operation of the observer The test results of visual function test items can be output. As a result, the visual function testing device can derive the visual function test result from the output result of the test result output unit 32 without the expertise of the visual function test.

  The above-described embodiment is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiment, and various modifications can be made depending on the design and the like as long as the technical idea according to the present invention is not deviated from this embodiment. Of course, it is possible to change.

DESCRIPTION OF SYMBOLS 1 Control apparatus 2 Target image | video presentation part 11 Visual function test | inspection item selection part 12 Target image | video production | generation part 13 Target image | video drawing part 14 View distance input part 15 Viewing angle input part 20 Target image | video selection presentation part 21 Target image | video operation part 22 visual target image adjustment unit 23 visual distance calculation unit 24 viewing angle input unit 25 visual acuity input unit 26 parallax input unit 27 visual distance measurement unit 28 visual image selection storage unit 29 visual image storage unit 30 display setting storage unit 31 display order Setting part 32 Inspection result output part

Claims (10)

A visual function testing device capable of testing a plurality of visual functions,
A target image presentation means for presenting a target image;
A target image drawing means for drawing a target image to be presented to the target image presenting means;
Visual function inspection item selection means for selecting items of visual function inspection;
A visual target image generation means for generating a visual target image corresponding to the inspection item selected by the visual function inspection item selection means,
The visual target image drawing means selects the visual function test item based on a viewpoint distance that is a distance between the visual target image presentation means and an observer, and a visual angle that is an angle formed between the visual target image and the observer's viewpoint. Calculating the display size and display position of the target image corresponding to at least one of the visual acuity test, visual field test, stereoscopic vision test, binocular vision test, and eye position test selected by the means, and the calculated display A visual function inspection device characterized by drawing a visual target image at a size and a display position. The target image generation means has a binocular target image generation function for generating a target image for each of the subject's right eye and left eye,
A binocular separation target image in which the target image presentation means separates the binocular target images of the right eye and the left eye generated by the binocular target image generation function and presents them for each corresponding eye. Has a presentation function,
Independently for each right-eye or left-eye target image presented by the binocular separation target image presentation function, it comprises a target image selection presentation means for selecting display or non-display.
The visual function inspection device according to claim 1, wherein the visual target image selection / presentation unit displays a visual target image corresponding to the stereoscopic inspection selected by the visual function inspection item selection unit. The target image generation means has a binocular target image generation function for generating a target image for each of the subject's right eye and left eye,
A binocular separation target image in which the target image presentation means separates the binocular target images of the right eye and the left eye generated by the binocular target image generation function and presents them for each corresponding eye. Has a presentation function,
By a user operation, provided with a target image operation means for changing at least one of the display size or display position of the target image,
When the binocular visual examination or eye position examination is selected by the visual function examination item selection means, the visual target image drawing means is the display size or display position of the visual target image changed by the visual target image operating means. The visual function testing device according to claim 1, wherein the visual target image is drawn by changing the visual target image to the display size and the display position calculated by the visual target image drawing unit.   The said target image drawing means has a target image adjustment means which can adjust the brightness | luminance of a target image, contrast, a color, and transparency, The one of Claim 1 thru | or 3 characterized by the above-mentioned. Visual function inspection device. When a visual field inspection is selected by the visual function inspection item selection means, a viewing angle input means for inputting a viewing angle used in the visual field inspection,
A visual point distance calculating unit that calculates a visual point distance required for performing a visual field inspection at a visual field angle input by the visual field angle input unit in a screen size of the visual target image presenting unit. The visual function testing device according to any one of claims 1 to 4. A visual acuity input means for inputting visual acuity used in the visual acuity test when a visual acuity test is selected by the visual function test item selection means;
2. A viewpoint distance calculating means for calculating a viewpoint distance required for performing a visual acuity test with the visual acuity input by the visual acuity input means at the resolution of the visual target image presenting means. The visual function testing device according to claim 5. Parallax input means for inputting parallax to be used in the stereoscopic inspection when the stereoscopic inspection is selected by the visual function inspection item selection means;
The viewpoint distance calculation means for calculating a viewpoint distance required for performing a stereoscopic vision inspection with the parallax input by the parallax input means at a resolution of the target image presentation means. The visual function testing device according to any one of claims 2 to 6.   The visual function inspection device according to claim 1, further comprising a viewpoint distance measuring unit that measures a distance between the visual target image presenting unit and an observer's viewpoint. Target image storage means for storing the target image generated by the target image generation means;
Display setting storage means for storing the display size and display position of the target image calculated using the viewpoint position and the viewing angle;
Target image selection storage means for storing the display or non-display of the target image for each right eye and left eye set by the target image selection presentation means;
Using a combination of information stored in each storage means, comprising display order setting means for setting the display order of the target video stored in the target video storage means,
9. The visual target image stored in the visual target image storage unit is called according to the display order set by the display order setting unit, and is drawn by the visual target image drawing unit. The visual function testing device according to any one of the above.   10. An inspection result output unit for a visual function test selected by the visual function test item selection unit is provided, and the test result corresponding to each test item is output in a predetermined format. The visual function testing device according to any one of the above.