JP6467293B2 - Visual inspection device - Google Patents

Description

  The present invention relates to a visual inspection apparatus used for visual inspection.

  One of the eye tests is a “visual test” that tests the visual function of the eye. A typical visual inspection is a “field inspection”. The visual field inspection is performed for diagnosis of visual field constriction, visual field defect, etc. caused by glaucoma or retinal detachment, for example, and various inspection apparatuses have been proposed (for example, see Patent Document 1).

  In general, visual inspection devices inspect one eye at a time. For this reason, when one eye is opened for examination, the other eye is often shielded. However, it has been found that if only the eye that is actually inspecting (hereinafter also referred to as “the eye to be examined”) is opened, there are other problems such as fatigue due to shielding and dark adaptation.

JP 2014-128493 A

  Therefore, the present inventors have proposed a visual inspection apparatus that can inspect each eye with both eyes open. This visual inspection apparatus includes a display optical system and a display element having independent left and right configurations corresponding to the left eye and right eye of a subject. A fixation target is displayed on each of the left-eye display element and the right-eye display element, and a visual inspection can be performed by fixing (fixing) the fixation target to the subject with binocular vision. It has become.

  If such a binocular open type visual inspection apparatus is used, the above-mentioned problems such as fatigue and dark adaptation due to one-eye occlusion can be solved. However, in the binocular open type visual inspection apparatus, since the display optical system and the display element are provided independently on the left and right, a new problem arises that it becomes difficult to fuse the fixation target. It became clear by examination.

  Therefore, in the present invention, when a fixation target is presented to a subject using a display optical system and display elements that are provided independently on the left and right, and the fixation target is fixed in a binocular open state, An object of the present invention is to provide a visual inspection apparatus that facilitates fusion of a visual target.

(First aspect)
The first aspect of the present invention is:
A display optical system and display elements that are provided independently on the left and right sides of the left and right eyes of the subject undergoing a visual examination are provided, and a fixation target is displayed on each of the display elements that are provided independently on the left and right sides. A possible visual inspection device,
When the distance between the pupils of the subject is PD, the presentation distance of the fixation target to the subject is L, and the convergence angle obtained by the inter-pupil distance PD and the presentation distance L is β1, the convergence A visual inspection apparatus comprising: a display control unit that controls to display the fixation target on each of the display elements based on a second convergence angle β2 that is larger than the angle β1.
(Second aspect)
The second aspect of the present invention is:
The convergence angle β1 is obtained by the following equation (1). The visual inspection device according to the first aspect, wherein the convergence angle β1 is obtained by the following equation (1).
β1 = 2 × tan ⁻¹ {PD ÷ (2 × L)} (1)
(Third aspect)
The third aspect of the present invention is:
Said 2nd convergence angle (beta) 2 is set on the conditions of less than 20 degrees. It is a visual inspection apparatus as described in the said 1st or 2nd aspect characterized by the above-mentioned.
(Fourth aspect)
The fourth aspect of the present invention is:
In the visual inspection device according to any one of the first to third aspects, the display control unit determines the second convergence angle β2 based on the following expression (2). is there.
β2 = 2 × tan ⁻¹ (40 ÷ L) (2)
(Fifth aspect)
According to a fifth aspect of the present invention,
The visual fixation device according to any one of the first to fourth aspects, wherein the fixation target is a single figure.
(Sixth aspect)
The sixth aspect of the present invention is:
The size of the fixation target is a viewing angle of 3 ° or less. The visual inspection device according to any one of the first to fifth aspects.
(Seventh aspect)
The seventh aspect of the present invention is
An apparatus main body mounted on the head of the subject;
The display optical system and the display element are provided in the apparatus main body. The visual inspection apparatus according to any one of the first to sixth aspects.

  According to the present invention, when a fixation target is presented to a subject using a display optical system and a display element provided independently on the left and right, and the fixation target is fixed in a binocular open state, It becomes easier to fuse the mark.

It is the schematic which shows the structural example of the visual inspection apparatus which concerns on embodiment of this invention. It is the schematic including the structure of the optical system of the visual inspection apparatus which concerns on embodiment of this invention. It is a block diagram including the structure of the control system of the visual inspection apparatus which concerns on embodiment of this invention. It is FIG. (1) explaining the relationship between the position of a fixation target and a convergence angle. FIG. 6 is a diagram (part 2) for explaining the relationship between the position of the fixation target and the convergence angle. The display state of the fixation target on the display element is shown. In the figure, (A) shows the display state based on the convergence angle β1, and (B) shows the display state based on the convergence angle β2. It is the schematic (the 1) which shows the other structural example of a display optical system. It is the schematic (the 2) which shows the other structural example of a display optical system.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In the embodiment of the present invention, description will be given in the following order.
1. Visual inspection device 2. Visual inspection method 3. Fixation target display position 4. Effects of the embodiment Modifications etc.

<1. Visual inspection device>
FIG. 1 is a schematic diagram showing a configuration example of a visual inspection apparatus according to an embodiment of the present invention.
The illustrated visual inspection apparatus 1 is a head-mounted visual inspection apparatus that is used by being mounted on the head 3 of a subject 2. The visual inspection device 1 generally includes a device main body 5 and a mounting tool 6 mechanically connected to the device main body 5.

  The apparatus main body 5 includes a housing 7 having a space inside. The internal space of the housing 7 is divided into left and right. This is because the visual inspection is performed separately for the left eye 8L and the right eye 8R of the subject 2. In this visual inspection, when the left eye 8L is the eye to be examined, the subject 2 sees the target through the pupil 9L of the left eye 8L, and when the right eye 8R is the eye to be examined, the subject 2 sees the target through the pupil 9R of the right eye 8R.

  The “target” described here is displayed (presented) in order to give a stimulus by light to the eyeball of the subject when examining the sight of the subject. There are no particular restrictions on the size, shape, etc. of the visual target. For example, in the case of glaucoma examination, the point of light is displayed as a target with a predetermined size, and the position of the point of light is changed to examine the presence or absence of the missing visual field and the location of the defect (specific) can do.

  The apparatus main body 5 includes a display optical system 11 and a display element 12. In the apparatus body 5, the display optical system 11 and the display element 12 are provided independently on the left and right sides so that visual inspection can be performed with both eyes open, regardless of whether the left or right eye is to be examined. That is, in one space of the housing 7, a display optical system 11L and a display element 12L are provided corresponding to the subject's right eye 8R, and in the other internal space of the housing 7, the subject's right eye 8R is provided. A display optical system 11R and a display element 12R are provided corresponding to the right eye 8R. The display optical system 11L and the display element 12L are provided mainly for visual inspection of the left eye 8L of the subject 2. The display optical system 11R and the display element 12R are provided mainly for visual inspection of the right eye 8R of the subject 2. The distance between the optical axes of the left and right display optical systems 11L and 11R can be adjusted according to the distance between the pupils of the subject 2 by an adjustment mechanism (not shown).

The mounting tool 6 is for mounting the apparatus main body 5 on the head 3 of the subject 2. The wearing tool 6 includes a belt 13 that is stretched in a U-shape from both sides of the subject 2 to the back of the head, and a belt 14 that is stretched over the top of the subject 2. Then, in a state where the length of the belt 14 is adjusted appropriately, the belt 13 is pulled and tightened from the back of the head, whereby the apparatus main body 5 can be firmly fixed and mounted on the head 3 of the subject 2. ing.
The distance between the optical axes of the display optical systems 11L and 11R described above is the distance between the pupils when the apparatus main body 5 is fixed to the head 3 of the subject 2 by the wearing tool 6 and the subject 2 faces the front. Adjust according to the distance.

  In the following description, when the left eye 8L and the right eye 8R of the subject 2 are described without distinction between left and right, the symbols L and R are omitted and the eyeball 8 and the pupil 9 are collectively referred to. Similarly, when the display optical systems 11L and 11R and the display elements 12L and 12R are described without distinction for the left eye and the right eye, the reference optical systems 11 and 11 are omitted by omitting the symbols L and R, respectively. Collectively referred to as the display element 12.

(Optical system)
FIG. 2 is a schematic view including the configuration of the optical system of the visual inspection apparatus according to the embodiment of the present invention.
As shown in the figure, the visual inspection apparatus 1 includes an observation optical system 15 for observing the eyeball 8 of the subject and the test optical system 15 in addition to the display optical system 11 and the display element 12 described above. An imaging device 16 that images the eyeball 8 of the person, an infrared light source 17 that irradiates infrared rays to the eyeball 8 of the subject, a control unit 30 that controls the entire visual inspection apparatus 1, a response switch 31, It has. Similar to the display optical system 11 and the display element 12 described above, the observation optical system 15, the imaging element 16, and the infrared light source 17 are separately provided for the left eye and the right eye of the subject. One control unit 30 and one switch 31 are provided for each visual inspection device 1. The display element 12, the switch 31, and the imaging element 16 are electrically connected to the control unit 30 as indicated by reference signs A, B, and C in the drawing.

(Display optical system)
The display optical system 11 is provided on the optical axis 18 between the eyeball position where the eyeball 8 of the subject is placed and the display surface 12 a of the display element 12. Specifically, the display optical system 11 has a configuration in which a first lens 19, a mirror 20, and a second lens group 21 are arranged in order from the eyeball position side of the subject. Hereinafter, each component will be described. In the following description, among the optical axes 18 from the eyeball position of the subject to the display element 12, the optical axis from the eyeball position to the mirror 20 is the optical axis 18a, and the optical axis from the mirror 20 to the display element 12 is the optical axis. Is the optical axis 18b.

  The first lens 19 is disposed on the optical axis 18 a from the eyeball position to the mirror 20. The first lens 19 is configured using an aspherical lens (convex lens) having positive power. The first lens 19 converges the light reflected by the mirror 20 and incident on the first lens 19 onto the pupil 9 of the subject, while the light divergence occurs when the subject views an object through the pupil 9 at a wide angle. It is to suppress. In FIG. 2, when a point of light serving as a target is displayed on the display surface 12a of the display element 12, and the subject views the target through the display optical system 11 from the eyeball position, the center of the pupil of the subject is displayed. The incident angle of the chief ray incident on the first lens 19 from is represented by the symbol θ. The incident angle θ is an angle with respect to the optical axis 18a (an angle formed between the principal ray passing through the center of the pupil and the optical axis 18a). The outer diameter (diameter) and position of the first lens 19 on the optical axis 18a are set under conditions that can secure at least a viewing angle necessary for visual inspection. Specifically, the maximum viewing angle (maximum value of θ) of the display optical system 11 using the first lens 19 is preferably 30 degrees or more and 60 degrees or less at a half field angle (60 degrees or more at all angles). , 120 degrees or less).

  The mirror 20 is disposed on the opposite side of the eyeball position on the optical axis 18a from the eyeball position to the mirror 20 with the first lens 19 interposed therebetween. The mirror 20 is configured using a mirror having wavelength selectivity. Specifically, the mirror 20 is configured using a cold mirror that reflects visible light and transmits infrared rays. The inclination of the reflecting surface of the mirror 20 with respect to the optical axis 18a is such that the angle α formed by the optical axis 18a and the optical axis 18b bent by the mirror 20 is preferably 90 degrees or less, more preferably 80 degrees or less, and still more preferably. It is set to be in the range of “40 degrees <α <70 degrees”.

  Here, when α ≦ 40 °, the display element 12 and the second lens group 21 are too close to the head of the subject, and they may interfere with the head. On the other hand, when α> 40 °, it is possible to avoid the display element 12 and the second lens group 21 from interfering with the head. On the other hand, when α ≧ 90 °, the visual inspection device 1 is likely to slip off the head when the subject tilts the head forward. On the other hand, when α <90 °, the visual inspection device 1 is less likely to slip off the head when the subject tilts the head forward.

The second lens group 21 is disposed on the optical axis 18 b from the mirror 20 to the display element 12. The second lens group 21 is configured by using three lenses 21a, 21b, and 21c. The three lenses 21a, 21b, and 21c are sequentially arranged from the mirror 20 side toward the display element 12 side. That is, the lens 21a is disposed at a position closest to the mirror 20 on the optical axis 18b, and the lens 21c is disposed at a position closest to the display element 12 on the optical axis 18b. A lens 21b is disposed between the two lenses 21a and 21c. The lens 21b is arranged near the lens 21c in a state of being separated from the lens 21a.

  The lens 21a is configured using an aspherical lens (convex lens) having positive power. The lens 21b is configured by using an aspheric lens (concave lens) having negative power, and the lens 21c is configured by using an aspheric lens (convex meniscus lens) having positive power. The outer diameter (diameter) of the lens 21a is larger than the outer diameters of the other lenses 21b and 21c, and the outer diameters of the lenses 21b and 21c are substantially equal to each other.

Here, when the Abbe number of the material constituting the first lens 19 is v1, the first lens 19 is made of a material (glass, plastic, etc.) that satisfies the relational expression “45 <v1 <80”. . On the other hand, when the Abbe numbers of the lenses 21a and 21c having the positive power among the lenses 21a to 21c constituting the second lens group 21 are both v2, each of the lenses 21a and 21c has “45 <v2 <80”. It is comprised with the material which satisfy | fills the relational expression. When the Abbe number of the lens 21b having negative power is v3, the lens 21b is made of a material that satisfies the relational expression “15 <v3 <30”.
Further, when the focal length of the first lens 19 is f1, and the focal length of the second lens group 21 is f2, these satisfy the relationship of “0 <f1 / f2 <1.0”. Further, the focal length f1 of the first lens 19 is the sum (a + b) of the optical distance a from the first lens 19 to the mirror 20 and the optical distance b from the mirror 20 to the second lens group 21 (lens 21a). ) And shorter than that.

(Display element)
The display element 12 is disposed on the optical axis 18b from the mirror 20 to the display element 12 so as to face the lens 21c of the second lens group 21. The display element 12 is configured using, for example, a flat display element such as a liquid crystal display element having a backlight. The display surface 12a of the display element 12 has a configuration in which a large number of pixels are arranged in a matrix. When an image (including a target) is actually displayed on the display surface 12a, display (on) and non-display (off) of the image can be controlled in units of pixels. The display surface 12a of the display element 12 preferably has a display size with a diagonal length of 1.5 inches or less, more preferably a display size with a diagonal length of 1 inch or less. The optical axis 18b is aligned at the center.

  In the display optical system 11 and the display element 12 having the above-described configuration, when the visual target is displayed on the display surface 12a of the display element 12, the subject 2 moves the first lens 19, the mirror 20, and the second lens from the eyeball position. The target is viewed through the group 21. In that case, if the outer diameter of the first lens 19 closest to the eyeball position is increased, visual inspection can be performed in a wider range. However, when the outer diameter of the first lens 19 is increased, the principal ray passing through the lens end is largely inclined with respect to the optical axis 18 (18a). Therefore, when the power of the first lens 19 is low, the chief ray passing through the lens end is diverged.

  Therefore, in the present embodiment, by using a lens with high power (preferably, power is 20D (dioptre) or more and 60D or less) for the first lens 19, the principal ray passing through the lens end of the first lens 19 is largely refracted. And stored in the reflection surface of the mirror 20. However, when the high-power first lens 19 is used in this way, the main light beam is condensed and focused in the middle of the optical path from the first lens 19 to the second lens group 21. For this reason, the second lens group 21 is disposed on the optical axis 18b in order to condense (image) the principal ray bundle focused in the middle of the optical path on the display surface 12a of the display element 12 again. Yes. In order to correct chromatic aberration and image magnification, the second lens group 21 is composed of three lenses 21a, 21b, and 21c.

(Observation optics)
The observation optical system 15 is for observing, for example, the anterior part of the eye including the pupil 9, the iris, the sclera, or the fundus oculi including the retina 10, using the eyeball 8 of the subject as an observation target. The observation optical system 15 is provided on the optical axis 18 from the eyeball position of the subject to the image sensor 16. Specifically, the observation optical system 15 has a configuration in which a first lens 19, a mirror 20, and a third lens 22 are arranged in order from the eyeball position side of the subject. Among these, the first lens 19 and the mirror 20 are common (shared) with the display optical system 11 described above, including the optical axis 18a. If the optical axis from the mirror 20 to the image sensor 16 is the optical axis 18c, the optical axis 18c is substantially parallel to the optical axis 18a described above.

  The third lens 22 is disposed on the optical axis 18 c from the mirror 20 to the image sensor 16. The third lens 22 is configured using an aspherical lens (convex lens) having positive power. When observing the eyeball 8 using the first lens 19 as an objective lens, the third lens 22 transmits light that enters the first lens 19 from the eyeball 8 and passes through the mirror 20 to the imaging surface 16 a of the imaging device 16. The image is formed.

(Image sensor)
The image pickup device 16 picks up an eyeball (anterior eye portion, fundus oculi portion, etc.) 8 serving as an eye to be examined. The imaging device 16 is configured using a CCD (Charge Coupled Device) imaging device having sensitivity to infrared rays, a CMOS (Complementary Metal Oxide Semiconductor) imaging device, or the like. The image pickup surface 16a of the image pickup device 16 is arranged in a direction facing the eyeball 8 on the optical axis 18c, and the optical axis 18c is aligned with the center of the image pickup surface 16a.

  The infrared light source 17 irradiates infrared rays toward the eyeball position of the subject. The infrared light source 17 is configured using a pair of infrared light emitting diodes 17a and 17b. The pair of infrared light emitting diodes 17a and 17b are arranged in an obliquely upward and obliquely downward direction with respect to the eyeball position of the subject so as not to disturb the visual field of the subject. One infrared light-emitting diode 17a irradiates the subject's eyeball 8 with infrared rays obliquely from above, and the other infrared light-emitting diode 17b irradiates the subject's eyeball 8 with infrared rays obliquely from below. It is configured to do.

  In the observation optical system 15 and the image sensor 16 having the above-described configuration, the eyeball 8 is irradiated via the first lens 19, the mirror 20, and the third lens 22 while irradiating the eyeball 8 of the subject with infrared rays from the infrared light source 17. The image is picked up by the image pickup device 16.

(Control system)
FIG. 3 is a block diagram including the configuration of the control system of the visual inspection apparatus according to the embodiment of the present invention.
The control unit 30 implements various functions (means) for visual inspection. The control unit 30 has, for example, a housing structure smaller than the apparatus main body 5 and is mounted on the back head side of the wearing tool 6. Thereby, the weight balance before and behind the apparatus main body 5 and the control part 30 can be maintained.

  The control unit 30 is configured by a computer including a combination of a central processing unit (CPU), a random access memory (RAM), a read only memory (ROM), a hard disk drive (HDD), various interfaces, and the like. And the control part 30 is comprised so that various functions may be implement | achieved, when CPU runs the predetermined program stored in ROM or HDD. The predetermined program for realizing each function is used by being installed in a computer, but may be provided by being stored in a computer-readable storage medium prior to the installation, or the computer It may be provided through a communication line connected to.

  The control unit 30 includes a miosis detection unit 41, a sensitivity map creation unit 42, and a display control unit 43 as an example of a function (means) realized by executing the program. In addition, the control unit 30 includes a memory 44 as an information storage unit.

  The miosis detector 41 has a function of detecting the miosis phenomenon of the eye to be examined. The miosis phenomenon is a phenomenon in which the pupil of the eyeball of the subject shrinks, and occurs when light enters the pupil of the subject wearing the apparatus body 5. The miosis detector 41 reduces the pupil 9 when the brightness of the visual target displayed on the display element 12 exceeds a predetermined brightness (luminance) based on the image of the pupil 9 acquired by the imaging device 16. Detect pupils.

  The sensitivity map creation unit 42 is a function for creating a sensitivity map in visual inspection. For example, in the subjective visual field inspection, the sensitivity map creation unit 42 is configured to display the brightness of the target displayed on the display element 12 when the subject presses the switch 31 in response to the target light (see FIG. (Luminance) is mapped as the sensitivity of the retina 10. In addition, in the objective visual field examination, the sensitivity map creation unit 42 determines the brightness of the visual target displayed on the display element 12 when the miosis pupil detection unit 41 detects the miosis of the pupil 9. Map as sensitivity.

  The display control unit 43 has a function of controlling an image displayed on the display element 12. The image displayed on the display element 12 includes at least an inspection image for visual inspection. The inspection image is an image displayed (presented) to the subject during the visual field inspection, and includes, for example, an image including a fixation target or a visual target in the visual field inspection.

  The memory 44 is used for storing various types of information including information necessary for visual inspection. For example, the sensitivity map creation unit 42 sequentially stores the inspection results obtained from the start to the end of the visual inspection in the memory 44, and uses the inspection results stored in the memory 44 after the end of the visual inspection. To create a sensitivity map.

  In addition to the switch 31, the image sensors 16L and 16R, and the display elements 12L and 12R described above, a terminal 45 is connected to the control unit 30 so as to be communicable by wire or wirelessly. The terminal 45 is used by an examiner such as an ophthalmologist who performs a visual inspection to perform various settings, adjustments, operations, instructions, and the like necessary for the visual inspection when using the visual inspection apparatus 1. The terminal 45 is configured using, for example, a personal computer with a monitor.

  The switch 31 is operated by a subject who undergoes visual inspection. The switch 31 is operated by a subject for response mainly in visual inspection. The switch 31 is preferably a manual switch that the subject holds and operates with a hand, and more preferably, a push type switch that the subject presses with a finger (for example, thumb or index finger) of the hand. Should be used. In this case, when the subject presses the switch 31, the switch 31 is switched from the off state to the on state, and an on signal is output from the switch 31. This ON signal is taken into the control unit 30.

<2. Visual inspection method>
Then, the visual inspection method performed using the visual inspection apparatus 1 which concerns on embodiment of this invention is demonstrated.

  In the visual inspection device 1 according to the embodiment of the present invention, dynamic quantitative visual field inspection (Goldman visual field inspection), static quantitative visual field inspection, fundus visual field inspection (microperimetry), electroretinography (ERG). Other tests can be performed. Here, the case where a static quantitative visual field inspection is performed is described as an example.

  The static quantitative visual field inspection is performed as follows. First, a fixation target is presented at the center of the visual field, and the fixation target is fixed to the subject. Next, with the subject fixation on the fixation target, the visual target is presented at one point in the field of view and the brightness is gradually increased. Then, when the target has a certain brightness, the target can be seen from the subject. Therefore, the value corresponding to the brightness when the subject can see the target is set as the retina sensitivity at the point where the target is presented at that time. Then, the same measurement is performed for each point in the field of view, thereby quantitatively examining the difference in retinal sensitivity in the field of view and creating a map. Such static quantitative visual field inspection includes a subjective visual field inspection and an objective visual field inspection. If the visual inspection apparatus 1 of the present embodiment is used, any type of inspection can be performed. This will be described below.

  The subjective visual field inspection is performed as follows. First, the head-mounted visual inspection device 1 (device main body 5) is mounted on the subject's head and the switch 31 is held in the subject's hand. Next, based on a command from the control unit 30, a fixation target is displayed on the display surface 12a of the display element 12 to cause the subject to fixate, and in that state, a visual field inspection target is applied to one point on the display surface 12a. indicate. At this time, the brightness of the target is initially darkened, and then the brightness of the target is gradually increased. Then, even if it is dark at first and the target is not visible to the subject, when the target reaches a certain brightness, the subject's retina responds to the light stimulus so that the subject can see the target. become. For this reason, when the visual target becomes visible from the subject, the subject presses the switch 31 as a response. When the subject presses the switch 31, an ON signal is sent to the control unit 30. Upon receiving this ON signal, the sensitivity map creation unit 42 sets the value corresponding to the brightness of the target point at that time as the sensitivity of the retina at that point. Thereafter, by performing the same measurement for each point in the visual field, the sensitivity map creation unit 42 quantitatively examines the difference in retinal sensitivity in the visual field and creates a sensitivity map of the retina.

  The objective visual field inspection is performed as follows. First, the head-mounted visual inspection apparatus 1 is mounted on the subject's head, and the subject is made to fixate the fixation target as described above. Next, based on a command from the control unit 30, a visual field inspection target is displayed at one point on the display surface 12 a of the display element 12. At this time, the brightness of the target is initially darkened, and then the brightness of the target is gradually increased. Then, even if it is dark at first and the target is not visible to the subject, when the target reaches a certain brightness, the subject's retina responds to the light stimulus so that the subject can see the target. become.

  At that time, the size of the pupil 9 (pupil diameter) of the subject changes according to the brightness of the visual target. Specifically, the diameter of the pupil 9 of the subject is reduced. The state change of the eyeball 8 at this time is imaged. The imaging of the eyeball 8 is performed by irradiating infrared rays from the infrared light source 17 toward the eyeball 8, and the image light of the eyeball 8 obtained thereby is transmitted to the imaging element 16 via the observation optical system 15 (19, 20, 22). This is performed by forming an image on the imaging surface 16a. The timing for starting imaging of the eyeball 8 may be set, for example, before the display of the visual target on the display surface 12a or simultaneously with the display of the visual target. Incidentally, since the human retina has no sensitivity to infrared rays, it does not affect the state change of the eyeball 8.

  The image data of the eyeball 8 imaged using the image sensor 16 is taken into the control unit 30. At this time, the miosis detector 41 determines whether or not the pupil diameter of the subject has changed (reduced) in response to the brightness of the target in the process of gradually increasing the brightness of the target. Judgment is made based on image data sent from. When the miosis detection unit 41 determines that the pupil diameter of the subject has changed, the sensitivity map creation unit 42 sets the value corresponding to the brightness of the target point at that time to the sensitivity on the retina at that point. And Thereafter, the sensitivity map creation unit 42 quantitatively examines the difference in sensitivity on the retina in the field of view by automatically performing the same measurement for each point in the field of view automatically. Create it automatically.

  Note that the objective visual field test uses a single upper threshold stimulation method in which a bright target is displayed on one point of the display surface 12a of the display element 12 and a sensitivity map is created by observing the degree of reduction of the pupil diameter. May be.

<3. Display position of fixation target>
Next, under what conditions the display control unit 43 sets the display position of the fixation target will be described with reference to FIGS.

FIG. 4 is a diagram for explaining the relationship between the position of the fixation target and the convergence angle.
In FIG. 4, the fixation target M is indicated by a cross-shaped figure, the distance between the pupils of the subject is indicated by PD, and the presentation distance of the fixation target is indicated by L. The inter-pupil distance PD is a center-to-center distance between the pupil 9L of the left eye 8L and the pupil 9R of the right eye 8R. In general, the inter-pupil distance PD for adults is typically 52 mm or greater and 76 mm or less, and is approximately 60 mm on average.

  The fixation target presentation distance L is a visual distance when the subject views the fixation target displayed on the display surface 12 a of the display element 12 through the display optical system 11. The fixation target presentation distance L is the arrangement and characteristics of the lenses constituting the display optical system 11 even if the physical (mechanical) distance from the eyeball position of the subject to the display element 12 is constant. Etc., it becomes longer or shorter accordingly. That is, the fixation target presentation distance L is uniquely determined by the arrangement and characteristics of the lenses constituting the display optical system 11. For this reason, in this embodiment, the arrangement and characteristics of the lenses constituting the display optical system 11 are set so that the fixation target presentation distance L is a predetermined distance suitable for visual inspection. For example, the fixation target presentation distance L is set to 1 m (1000 mm).

Now, when the fixation target M is displayed at the P1 position facing the subject, and when the subject fixes the fixation target M simultaneously with both eyes 8L and 8R, the left eye 8L and the right eye 8R are respectively Move to face inward. Such a movement of the eyeball is called a vergence movement, and the greater the degree of the vergence movement, the stronger the tendency of the vergence. At this time, the convergence angle β1 is defined by an angle formed by a line segment connecting the fixation target M and the center of the pupil 9L of the left eye 8L and a line segment connecting the fixation target M and the center of the pupil 9R of the right eye 8R. . The convergence angle β1 is obtained geometrically by the following equation (1) using the above-described inter-pupil distance PD of the subject and the presentation distance L of the fixation target as calculation parameters. As can be seen from this equation, the convergence angle β1 decreases as the fixation target presentation distance L increases, and increases as the fixation target presentation distance L decreases.
β1 = 2 × tan ⁻¹ {PD ÷ (2 × L)} (1)

  When the present inventors initially display the fixation target M on the display surface 12a of the display element 12, the convergence angle β1 is obtained by the above equation (1), and the fixation target is located at a position specified by the convergence angle β1. We thought that the display position of M should be set. In general, the convergence angle is minimum (almost zero) when viewing an object at infinity, and takes a larger value (positive value) as the object approaches the subject. For this reason, the display position of the fixation target M is, for example, a position on the display surface 12a through which the subject's line of sight passes when viewing an object at infinity (hereinafter referred to as “line-of-sight passage position at infinity”). Is also present in the center of the display surface 12a of the display element 12 and presents the fixation target M at a position closer to infinity, the position shifted from the line-of-sight passage position at infinity. Is set. In addition, the display position of the fixation target M is set at a position deviated by a predetermined amount from the line-of-sight passage position at infinity in consideration of the inclination of the line of sight when viewing the object at the convergence angle β1 (β1 / 2) Is done. Therefore, assuming that the line-of-sight passage position at infinity exists in the center of the display surface 12a, the left and right display elements 12L and 12R when the display position of the fixation target M is set based on the convergence angle β1. The display state is as shown in FIG.

However, the inventors have actually made a binocular open type visual inspection device and set the display position of the fixation target M on the display surface 12a of the left and right display elements 12 based on the convergence angle β1. As a result, it was found that the fusion function is difficult to work even for a subject having no abnormality such as binocular diplopia. Fusion refers to the function of recognizing the image of the object viewed with the left eye and the image of the object viewed with the right eye as one image in the brain when the same object is viewed with both eyes. When the fixation target is presented with both eyes open, if the fusion is not performed well in the subject's brain, the fixation target will appear to be blurred from the subject. Difficult to do. As a result, even in the same subject, the test results tend to vary.

  Therefore, the inventors shift the display position of the fixation target M on the display element 12L and the display position of the fixation target M on the display element 12R by a predetermined amount in the horizontal direction (left-right direction) of the display surface 12a, respectively. I examined whether there was a difference in the ease of fusion. As a result, it has been found that when the fixation target M is displayed on the display surfaces 12a of the left and right display elements 12L and 12R so as to satisfy a certain condition, it is easy to perform fusion. Based on this knowledge, in the present embodiment, when the display control unit 43 displays the fixation target M on the left and right display elements 12L and 12R, the display position of the fixation target M is set under the following conditions. The structure to be adopted is adopted.

  That is, as shown in FIG. 5, the display control unit 43 is specified by a second convergence angle β2 that is larger than the convergence angle β1 obtained by the subject's interpupillary distance PD and the fixation target presentation distance L. The display position of the fixation target M is set at the position. Specifically, the display position of the fixation target M with respect to the left eye 8L is set to the P2 position shifted to the right from the P1 position when viewed from the subject, and the display position of the fixation target M with respect to the right eye 8R. Is configured to be set at the P3 position shifted to the left from the P1 position when viewed from the subject.

  Accordingly, for example, when the display position of the fixation target M is specified based on the convergence angle β1, the fixation state is set based on the second convergence angle β2 if the display state is as shown in FIG. When the display position of the mark M is specified, the display state is as shown in FIG. Specifically, the fixation target M is displayed on the left display element 12L as viewed from the subject at a position shifted to the right by a predetermined amount S from the convergence angle β1. Further, the fixation target M is displayed on the display element 12R on the right side as viewed from the subject at a position shifted to the left side by a predetermined amount S from the convergence angle β1.

  In this way, when the fixation target M is displayed at the position specified by the second convergence angle β2, the left eye 8L is compared with the case where the fixation target M is displayed at the position specified by the convergence angle β1. Each of the right eyes 8R is directed more inward. For this reason, the degree of the vergence movement in the fixation state increases.

  However, when the second convergence angle β2 is 20 ° or more, the fixation target M visually exists at a short distance of about 20 cm, so that the subject makes the left and right eyeballs more converging. There is a need. For this reason, we are anxious about the physical burden of the subject for maintaining a fixation state becoming large. Therefore, the second convergence angle β2 is preferably set under a condition of less than 20 °, more preferably less than 15 °, and even more preferably less than 10 °.

Further, when the display position of the fixation target M is set, the display control unit 43 determines the second convergence angle β2 that is the basis thereof, for example, by the following method.
That is, when the distance between the pupils PD of the subject is measured when the apparatus main body 5 is mounted on the subject's head, the distance between the pupils PD obtained by the measurement and the configuration of the display optical system 11 are determined. The convergence angle β1 is determined from the target presentation distance L, and the second convergence angle β2 is determined by multiplying the convergence angle β1 by a predetermined coefficient (a value greater than 1.0). In this case, the predetermined coefficient may be set to 1.3, for example. Further, since the distance between the optical axes of the left and right display optical systems 11L and 11R is adjusted in accordance with the distance between pupils PD of the subject, the distance between the optical axes after adjustment is used instead of the distance between pupils PD. May be.

  In addition, by calculating and operating at least one of the interpupillary distance PD of the subject and the fixation target presentation distance L, which are calculation parameters for the convergence angle β1, the second convergence angle β2 is calculated. You may decide. For example, when operating the numerical value of the fixation target presentation distance L, a distance shorter than the presentation distance L determined by the actual configuration of the display optical system 11 (for example, “L × 0.8 is applied to set the convergence angle. The second convergence angle β2 may be determined according to the calculation result, and when the numerical value of the interpupillary distance PD of the subject is manipulated, the interpupillary distance PD obtained by actual measurement is calculated. The convergence angle may be calculated by applying a longer distance (for example, a distance corresponding to “PD × 1.2”), and the second convergence angle β2 may be determined according to the calculation result.

Moreover, the inter-pupil distance PD of an adult subject is set to 76 mm at the maximum. Therefore, regardless of the numerical value of the inter-pupil distance PD obtained in actual measurement, the convergence angle is calculated by applying a constant condition of PD = 80 mm, and the second convergence angle β2 is determined according to the calculation result. Also good. Specifically, the second convergence angle β2 may be determined based on the following equation (2). In the formula, the unit of the presentation distance L is “mm”.
β2 = 2 × tan ⁻¹ (40 ÷ L) (2)

Since the numerical value of the interpupillary distance PD obtained by actual measurement is in the range of 52 mm or more and 76 mm or less, if the second convergence angle β2 is determined based on the above equation (2), an adult subject For all, the fixation target M can be displayed at a position where the tendency of congestion is strengthened. This is the same when the second convergence angle β2 is determined under the condition of the following expression (3).
2 × tan ⁻¹ (40 ÷ L) ≦ β2 <20 ° (3)

<4. Effects of the embodiment>
In the embodiment of the present invention, the left and right display elements 12L and 12R are based on the second convergence angle β2 larger than the convergence angle β1 obtained by the subject's interpupillary distance PD and the fixation target presentation distance L. Each of the fixation targets M is displayed on the screen. Thereby, the fixation target M can be fixed in a state where both eyes of the subject are more greatly converged than when the display position of the fixation target M is set based on the convergence angle β1. In this way, when the fixation is strengthened and fixed, when a small figure is displayed as the fixation target M on the left and right display elements 12L and 12R, the image of the fixation target M viewed with the left eye 8L and the right eye 8R. It becomes easy to fuse the image of the fixation target M that has been seen. For this reason, it becomes easy to maintain a fixation state by visual inspection. As a result, it is possible to obtain a stable inspection result with little variation.

  Further, when displaying the fixation target M composed of a single figure on each of the left and right independent display elements 12L and 12R, or when displaying the fixation target M having a viewing angle within 3 °, When the display position is determined based on the convergence angle β1, there is a strong tendency that the fusion is particularly difficult. Therefore, when the fixation target M is a single figure, the size of the fixation target M is within a viewing angle of 3 °, or both, the display position of the fixation target M is By determining based on the convergence angle β2 of 2, a more remarkable effect can be expected.

  In the present embodiment, since the second convergence angle β2 is determined under a condition of less than 20 °, the fixation state can be easily maintained without imposing an excessive physical burden on the subject. .

  Further, when determining the second convergence angle β2, the second condition is applied by applying a constant condition of PD = 80 mm, which is larger than the upper limit value of the standard range (52 mm or more and 76 mm or less) of the interpupillary distance PD. If the convergence angle β2 is determined, it is not necessary to use the measured value of the inter-pupil distance PD. For this reason, the procedure of display control by the display control unit 43 can be simplified.

<5. Modified example>
The technical scope of the present invention is not limited to the above-described embodiments, and includes various modifications and improvements as long as the specific effects obtained by the constituent elements of the invention and combinations thereof can be derived.

  For example, in the above-described embodiment, the mounting tool 6 of the visual inspection device 1 is configured using the belts 13 and 14, but as long as the device main body 5 can be mounted on the head 3 of the subject 2, whichever You may employ | adopt the mounting tool 6 of a structure. However, if the position of the apparatus body 5 moves during the visual inspection, a correct inspection result cannot be obtained. For this reason, as a structure of the mounting tool 6, it is preferable that it is a structure which can fix the apparatus main body 5 to the head 3 of the subject 2 properly.

  In the above embodiment, the head-mounted visual inspection apparatus 1 that is used with the apparatus main body 5 attached to the head 3 of the subject 2 has been described as an example. However, the present invention is not limited to this. Any device may be used as long as it includes a display optical system and display elements having independent structures on the left and right sides, and can perform visual inspection with both eyes open.

  Moreover, in the said embodiment, although the display element 12 was comprised using the liquid crystal display element, this invention is not limited to this, For example, the display element 12 is comprised using an organic EL (Electro Luminescence) display element etc. May be.

  In the above embodiment, the display optical system 11 is configured with a total of four lenses, and the observation optical system 15 is configured with a total of two lenses (one of which is shared with the display optical system 11). The number and shape of lenses constituting the optical system, the lens interval in the optical axis direction, and the like can be changed as necessary. However, the second lens group 21 is preferably composed of a plurality of lenses in order to correct chromatic aberration and image magnification by combining a lens having a positive power and a lens having a negative power. Further, the mirror 20 may be constituted by a dichroic mirror.

As an example, other configuration examples of the display optical system are shown in FIGS.
7 is different from the above embodiment in that the lens 21c belonging to the second lens group 21 of the display optical system 11 can be moved in the optical axis direction by a lens moving mechanism (not shown). When this configuration is adopted, it is possible to adjust the diopter according to the visual acuity of the subject.

  On the other hand, in FIG. 8, the second lens group 21 of the display optical system 11 is configured by using a total of four lenses 21a to 21d by adding a lens (convex lens) 21d, and the display surface 12a of the flat display element 12. The point which reduced the magnitude | size of is different from the said embodiment. When this configuration is adopted, the visual target can be displayed more clearly to the subject. Also in this configuration, it is possible to adjust the diopter according to the visual acuity of the subject by making the lens 21c movable in the optical axis direction.

DESCRIPTION OF SYMBOLS 1 ... Visual inspection apparatus 2 ... Subject 3 ... Head 5 ... Apparatus main body 8 ... Eyeball 9 ... Pupil 11 ... Display optical system 12 ... Display element 12a ... Display surface 15 ... Observation optical system 16 ... Imaging element 30 ... Control part 31 ... switch 43 ... display control unit M ... fixation target β1 ... convergence angle β2 ... second convergence angle

Claims (7)

A display optical system and display elements that are provided independently on the left and right sides of the left and right eyes of the subject undergoing a visual examination are provided, and a fixation target is displayed on each of the display elements that are provided independently on the left and right sides. A possible visual inspection device,
When the distance between the pupils of the subject is PD, the presentation distance of the fixation target to the subject is L, and the convergence angle obtained by the inter-pupil distance PD and the presentation distance L is β1, the convergence A visual inspection apparatus comprising: a display control unit that controls to display the fixation target on each of the display elements based on a second convergence angle β2 that is larger than the angle β1. The visual inspection apparatus according to claim 1, wherein the convergence angle β1 is obtained by the following equation (1).
β1 = 2 × tan ⁻¹ {PD ÷ (2 × L)} (1) The visual inspection apparatus according to claim 1 or 2, wherein the second convergence angle β2 is set under a condition of less than 20 °. The visual inspection device according to claim 1, wherein the display control unit determines the second convergence angle β <b> 2 based on the following expression (2).
β2 = 2 × tan ⁻¹ (40 (mm) ÷ L (mm) ) (2)


The visual inspection apparatus according to claim 1, wherein the fixation target is a single figure. The visual inspection apparatus according to claim 1, wherein a size of the fixation target is within a viewing angle of 3 °. An apparatus main body mounted on the head of the subject;
The visual inspection apparatus according to claim 1, wherein the display optical system and the display element are provided in the apparatus main body.

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