JP6529862B2 - Eye inspection device - Google Patents

Description

  The present invention relates to an eye inspection apparatus.

  One of the eye tests is an eye muscle function test to check for eye movement disorder. A Hess screen is used for this examination. The Hess screen is a grid-like screen having a plurality of crossing points. In the eye muscle function test, the distance between the hess screen and the subject is set so that one mesh of the hess screen is 5 ° in terms of eye position.

Hereinafter, the configuration of a conventional eye inspection apparatus that performs an eye muscle function will be described.
The conventional eye inspection apparatus fixes, for example, a projector for presenting a Hess screen to a subject, a large screen for projecting a Hess screen projected by a projector, and a head of the subject It comprises the fixing tool for, the spectacles which a subject is made to wear, and the indicator for making a subject instruct | indicate a spot.

  A projector projects and displays a red hess screen on a large white screen installed in a dark room or the like. The fixing tool is for fixing the head of the subject at a position separated by a predetermined distance from the installation position of the large screen (the presentation position of the screen). The glasses have a red lens and a green lens, and one lens is worn on one eye of the subject and the other lens is worn on the other eye of the subject. The indicator is capable of displaying an arbitrary green spot on the screen by emitting green light in a direction in which the subject points the indicator.

Next, the procedure of an examination using the above-mentioned conventional eye examination apparatus will be described.
First, the head of the subject is fixed by a fixing tool, and the subject wears glasses. At this time, a red lens is worn on one eye of the subject, and a green lens is worn on the other eye. Here, first, it is assumed that a red lens is attached to the left eye of a subject and a green lens is attached to the right eye.

  Next, the subject is shown the hess screen which has been photographed on a large screen by the projector. At this time, the hess screen is displayed in red, whereas the red lens reflects red light, and the green lens transmits red light. For this reason, the Hess screen can be seen by the left eye wearing a green lens, but the Hess screen can not be seen by the right eye wearing a red lens. Therefore, the subject sees the screen with only the left eye.

  Next, the subject is provided with an indicator, and the indicator is operated so that the position of the spot matches the position of each crossover point of the screen designated by the examiner (such as an ophthalmologist) in order. At this time, the spot of the indicator is displayed in green on the screen, whereas the green lens reflects green light and the red lens transmits green light. For this reason, although a spot can be seen by the right eye wearing a red lens, a spot can not be seen by the left eye wearing a green lens. Therefore, the subject sees the spot only with the right eye.

  Thereby, when the examinee sees one crossing point of the screen with the left eye, it is judged from the position of the spot on the screen where this crossing point is seen by the right eye of the subject can do. In this case, a screen test is performed with the right eye as the subject's eye. In the case of this screen test, if there is a movement disorder in the right eye of the subject, a large deviation occurs between the position of the crossing point of the screen and the position of the spot.

  After that, when the examination of the right eye is finished, the lens position of the glasses is changed from side to side, and the same examination as described above is performed. Thus, the subject looks at the spot with the left eye while looking at the hess screen with the right eye. For this reason, a Hess-Screen test is performed with the left eye as the subject's eye.

  The examination result obtained by the above examination is recorded on the examination sheet by the examiner as needed. On the inspection sheet, the same grid as that of the Hess screen is printed. The examiner marks the position indicated by the subject with a spot so as to be copied onto the inspection sheet at each of a plurality of intersection points around the center of the screen. Thereby, a Hess chart (Hess Chart) which shows a test result is obtained. In addition to the squares described above, the shape of the markings connected by the lines is drawn on the hess chart. In the case of a subject without movement disorders in both eyes, hescharts of figures having similar shapes and sizes can be obtained with the left eye and the right eye. On the other hand, in the case of a subject who has a movement disorder in one eye, hescharts of figures whose shapes and sizes are significantly different between the right eye and the left eye can be obtained.

  However, in the conventional eye inspection apparatus described above, it is necessary for the subject to indicate the position of the spot using an indicator at each crossing point of the screen. Also, the examiner needs to be present at all times during the examination. For this reason, there was a drawback that the burden on the subject and the examiner is considerably large when examining the eye movement disorder.

  The main object of the present invention is to provide an eye examination apparatus capable of reducing the burden on a subject and an examiner when examining an eye movement disorder.

(First aspect)
The first aspect of the present invention is
Mark presenting means capable of presenting marks individually to the left eye and the right eye of the subject;
Imaging means for individually imaging the left eye and the right eye of the subject;
The left eye and the right eye when the eyeball of the subject moves in the direction of the presentation position of the test visual target when the test target is presented to one eyeball of the subject by the visual target presenting means A detection unit that detects a difference in the amount of eye movement of the eye based on image data of the left eye and the right eye captured by the imaging unit;
An eye inspection apparatus comprising:
(Second aspect)
The second aspect of the present invention is
The target presenting means presents a central target at a central position of a field of view with respect to at least one of the left eye and the right eye of the subject, and the target presenting means of the left eye and the right eye of the subject Presenting the examination target at a position different from the presentation position of the central target with respect to any one of the eyeballs,
The detection means is image data of the left eye and the right eye captured by the imaging means when the subject sees the central visual target presented by the visual target presenting means with one eye or both eyes; The left eye and the right eye using the image data of the left eye and the right eye captured by the imaging means when the subject is looking at the test visual target presented by the visual target presenting means with one eye And the eye inspection apparatus according to the first aspect.
(Third aspect)
The third aspect of the present invention is
The eye examination apparatus according to the first or the second aspect, further comprising: an output means for outputting a detection result of the detection means.
(Fourth aspect)
The fourth aspect of the present invention is
The eye inspection apparatus according to the third aspect, wherein the output means outputs the detection result in the form of a hess chart.
(Fifth aspect)
The fifth aspect of the present invention is
The eye examination apparatus is an eye muscle function examination apparatus for examining an eye muscle function. The eye examination apparatus according to any one of the first to fourth aspects.
(Sixth aspect)
The sixth aspect of the present invention is
The visual target presenting means and the imaging means are built in an apparatus main body mounted on the head of the subject. Any one of the first to fifth aspects described above. It is an eye inspection apparatus.

  According to the present invention, it is possible to reduce the burden on the subject and the examiner when examining the eye movement disorder.

It is a schematic diagram showing an example of composition of an eye examination device concerning an embodiment of the present invention. It is the schematic containing the structure of the optical system of the eye inspection apparatus which concerns on embodiment of this invention. It is a block diagram including composition of a control system of eye inspection equipment concerning an embodiment of the present invention. It is a figure for demonstrating the presentation position of a visual target. It is a figure which shows the state which presented the central visual target. It is a schematic diagram which shows the image data of the eyeball of a subject when looking at a central visual target. It is a figure which shows the state which presented the test target. It is a schematic diagram which shows the image data of the eyeball of a subject when looking at a test subject. It is a figure which shows the example of an output of a test result.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
The embodiment of the present invention will be described in the following order.
1. Configuration of eye examination apparatus Procedure of eye examination 3. Effects of the embodiment Modified example etc

<1. Configuration of eye examination apparatus>
FIG. 1 is a schematic view showing a configuration example of an eye inspection apparatus according to an embodiment of the present invention.
The illustrated eye inspection apparatus 1 is a head-mounted inspection apparatus used by being attached to the head 3 of the subject 2. The eye examination apparatus 1 mainly includes an apparatus body 5 and a mounting tool 6 mechanically connected to the apparatus body 5.

  The device body 5 is provided with a housing 7 having a space inside. The internal space of the housing 7 is divided into left and right. The reason is that the examination is separately performed by the left eye 8L and the right eye 8R of the subject 2. In this embodiment, as one of the eye examinations, the presence or absence of eye movement disorder caused by ophthalmoplegia or the like, that is, the eye muscle function is examined. In this examination, a subject is presented with a visual target.

  The "target" to be presented to the subject is displayed (presented) in order to give a stimulus by light to the eye of the subject when examining the presence or absence of the eye movement disorder of the subject. There are no particular restrictions on the size, shape, etc. of the target. The eye examination apparatus presents a "center target" and an "examination target" to the subject. The “central visual target” is a visual target presented at the central position of the field of view of the subject in order to cause the subject to fixate in front view. The “examination target” is a target presented at a position different from the central target in order to examine whether or not the eye movement of the subject is abnormal. The presentation position of the test target will be described in detail later.

  The device body 5 incorporates a display optical system 11 and a display element 12. The display optical system 11 and the display element 12 are independent of each other on the device body 5 so that the left and right eyes of the subject can be individually presented with visual targets regardless of whether the left or right eye is the subject eye Provided in That is, in one space of the case 7, the display optical system 11L and the display element 12L are provided corresponding to the left eye 8L of the subject, and in the other internal space of the case 7, the subject's A display optical system 11R and a display element 12R are provided corresponding to the right eye 8R. 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 device body 5 on the head 3 of the subject 2. The wearing tool 6 includes a belt 13 which is stretched in a U-shape from both head portions of the subject 2 to the back of the head and a belt 14 which is stretched around the top of the head of the subject 2. Then, in a state where the length of the belt 14 is appropriately adjusted, by pulling and tightening the belt 13 from the occipital region, the device body 5 can be firmly fixed and mounted on the head 3 of the subject 2 ing.

  In the following description, when the left eye 8L and the right eye 8R of the subject 2 are described without distinction between right and left, the reference signs L and R are omitted and they are collectively referred to as the eye 8 and the pupil 9. Similarly, in the case where the display optical systems 11L and 11R and the display elements 12L and 12R described above are described without distinction for left eye and right eye, the reference signs L and R are omitted and the display optical system 11, 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 eye inspection apparatus according to the embodiment of the present invention.
As shown, in addition to the display optical system 11 and the display element 12 described above, the eye inspection apparatus 1 has an observation optical system 15 for observing the eye 8 of the subject, and an examination optical system 15 through the observation optical system 15 Image sensor 16 for imaging the eye 8 of the person, an infrared light source 17 for irradiating the eye 8 of the subject with infrared rays, a control unit 30 for controlling the entire eye inspection apparatus 1, and operation of the subject for response And 31. The observation optical system 15, the imaging device 16, and the infrared light source 17 are incorporated in the apparatus main body 5 similarly to the display optical system 11 and the display element 12 described above. The control unit 30 and the subject operation unit 31 are provided one for each visual inspection apparatus 1. The display element 12, the subject operation unit 31, and the imaging element 16 are electrically connected to the control unit 30, as indicated by reference symbols 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 disposed and the display surface 12 a of the display element 12. Specifically, the display optical system 11 has a configuration in which the first lens 19, the mirror 20, and the second lens group 21 are disposed in order from the eyeball position side of the subject. Each component will be described below. In the following description, of the optical axis 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 As an 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 aspheric 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 on the pupil 9 of the subject, while diverging the light when the subject looks at an object at a wide angle through the pupil 9 It is to suppress. In FIG. 2, a point of light serving as a visual target is displayed on the display surface 12 a of the display element 12, and when the subject looks through the display optical system 11 from the eyeball position, the pupil center of the subject The incident angle of the chief ray incident on the first lens 19 from the angle .theta. The incident angle θ is an angle based on the optical axis 18a (an angle formed by the principal ray passing through the pupil center 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 ensure at least a viewing angle necessary for inspection.

  The mirror 20 is disposed on the optical axis 18 a from the eye position to the mirror 20 on the opposite side of the eye position 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 light. The inclination of the reflection surface of the mirror 20 with respect to the optical axis 18a is such that the angle α between the optical axis 18a bent by the mirror 20 and the optical axis 18b is preferably 90 degrees or less, more preferably 80 degrees or less, still more preferably It is set to be in the range of “40 degrees <α <70 degrees”.

  Here, in the case of α ≦ 40 °, the display element 12 and the second lens group 21 may be too close to the head of the subject, and they may interfere with the head. On the other hand, when α> 40 °, interference between the display element 12 and the second lens group 21 with the head can be avoided. On the other hand, in the case of α> 90 °, when the subject leans the head forward, the eye inspection apparatus 1 tends to slip off the head. On the other hand, in the case of α ≦ 90 °, when the subject leans the head forward, the eye inspection apparatus 1 does not easily slip off the head.

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

  The lens 21a is configured using an aspheric lens (convex lens) having positive power. The lens 21 b is configured using an aspheric lens (concave lens) having negative power, and the lens 21 c is configured 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, assuming that the Abbe number of the material forming the first lens 19 is v1, the first lens 19 is made of a material (glass, plastic, etc.) satisfying the relational expression “45 <v1 <80”. . On the other hand, assuming that the Abbe numbers of the lenses 21a and 21c having positive power among the lenses 21a to 21c constituting the second lens group 21 are both v2, each lens 21a and 21c is “45 <v2 <80”. It is made of a material that satisfies the relation of Also, assuming that 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, assuming that 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”. Furthermore, the focal length f1 of the first lens 19 is the sum 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) (a + b It is shorter than that).

(Display element)
The display element 12 is disposed on the optical axis 18 b from the mirror 20 to the display element 12 so as to face the lens 21 c 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 provided with a backlight. The display surface 12 a of the display element 12 has a configuration in which a large number of pixels are arranged in a matrix. Then, when an image (including a visual target) is actually displayed on the display surface 12a, display (on) and non-display (off) of the image can be controlled in pixel units. 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.

(Observation optical system)
The observation optical system 15 is for observing the eyeball 8 of the subject, for example, the anterior part of the eye including the pupil 9, iris, sclera and the like, or the fundus including the retina 10 and the like. The observation optical system 15 is provided on the optical axis 18 from the eyeball position of the subject to the imaging element 16. Specifically, the observation optical system 15 has a configuration in which the first lens 19, the mirror 20, and the third lens 22 are disposed 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 18 a. Further, when an optical axis from the mirror 20 to the image pickup device 16 is an optical axis 18c, the optical axis 18c is substantially parallel to the above-described optical axis 18a.

  The third lens 22 is disposed on the optical axis 18 c from the mirror 20 to the imaging device 16. The third lens 22 is configured using an aspheric lens (convex lens) having positive power. When observing the eyeball 8 using the first lens 19 as an objective lens, the third lens 22 makes the light incident on the first lens 19 from the eyeball 8 and transmitted through the mirror 20 to the imaging surface 16a of the imaging device 16 It is made to image.

(Image sensor)
The imaging device 16 images the eye 8 of the subject via the observation optical system 15 described above. The imaging device 16 is configured using a charge coupled device (CCD) imaging device having sensitivity to infrared light, a complementary metal oxide semiconductor (CMOS) imaging device, or the like. The imaging surface 16a of the imaging element 16 is disposed on the optical axis 18c in a direction facing the eye 8 and the optical axis 18c is aligned with the center of the imaging surface 16a.

  The infrared light source 17 emits infrared light 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 obliquely above and below the eyeball position of the subject so as not to obstruct the field of view of the subject. Then, one infrared light emitting diode 17a irradiates infrared light to the eye 8 of the subject from diagonally above, and the other infrared light emitting diode 17b irradiates infrared light to the eye 8 of the subject from diagonal lower Is configured to

  In the observation optical system 15 and the imaging device 16 configured as described above, the eye 8 of the subject is irradiated with infrared light from the infrared light source 17, and the eye 8 is transmitted through the first lens 19, the mirror 20 and the third lens 22. Is taken by the image sensor 16. The observation optical system 15, the image sensor 16, and the infrared light source 17 are provided independently of each other so that the left eye 8L and the right eye 8R of the subject can be imaged individually. In the following description, the imaging device 16 for imaging the left eye 8L is referred to as "imaging device 16L", and the imaging device 16 for imaging the right eye 8R is referred to as "imaging device 16R".

(Control system)
FIG. 3 is a block diagram including a configuration of a control system of the eye examination apparatus according to the embodiment of the present invention.
The control unit 30 implements various functions (means) in the eye examination. The control unit 30 has, for example, a casing structure smaller than the device body 5 and is mounted on the occipital region of the mounting tool 6 (see FIG. 1). Thereby, the weight balance of the apparatus main body 5 and the control part 30 before and behind 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), and various interfaces. The control unit 30 is configured to realize various functions by the CPU executing a predetermined program stored in the ROM or the HDD. A predetermined program for realizing each function is installed and used in a computer, but may be provided stored in a computer readable storage medium prior to the installation, or a computer It may be provided through a communication line connected to the

  The control unit 30 includes an inspection processing unit 41, an inspection result output unit 42, and a display control unit 43 as an example of the function (means) realized by the execution of the program. The control unit 30 also includes a memory 44 as an information storage unit.

  The examination processing unit 41 performs various processes on the eye muscle function examination. The inspection processing unit 41 uses the image data of the eyeball 8 captured by the imaging device 16 to specify the eye position of the eyeball 8, detects the amount of movement of the eyeball 8, and further processes the left eye 8L and the right eye 8R. Processing to detect the difference in the eye movement amount of The eye position means the direction in which the eyeball is facing (the direction of the line of sight).

  The test result output unit 42 outputs the test result of the eye muscle function test. As a specific output form of the inspection result, preferably, an output by display, an output by printing, etc. can be considered, but in addition to this, various forms such as an output by mail transmission, an output by voice, etc. Conceivable. Any of the output forms may be adopted in practicing the present invention. In the present embodiment, the case where the test result of the eye muscle function test is output by display will be described as an example.

  The display control unit 43 is a function of controlling an image displayed on the display element 12 when performing an eye muscle function test. The image displayed on the display element 12 includes at least the above-described central visual target and the inspection visual target.

  The memory 44 is used to store various types of information, including the information necessary for the eye muscle function test. For example, the test processing unit 41 stores information obtained from the start to the end of the eye muscle function test in the memory 44, and the test result output unit 42 stores the information in the memory 44 after the end of the eye muscle function test. Using the stored information, data for output of inspection results and the like are created.

  A terminal 45 is communicably connected to the control unit 30 in a wired or wireless manner, in addition to the subject operation unit 31, the imaging devices 16L and 16R, and the display devices 12L and 12R described above. The terminal 45 is operated by an examiner such as an ophthalmologist who performs an eye muscle function test when using the eye inspection apparatus 1 to perform various settings, adjustments, instructions, etc. necessary for the test. . The terminal 45 is configured using, for example, a personal computer with a monitor.

  The subject operation unit 31 is operated by a subject who receives an eye muscle function test. The subject operation unit 31 is mainly operated by the subject for response. The subject operation unit 31 is preferably a manual subject operation unit that the subject holds and operates with a hand, and more preferably, the finger of a hand (for example, a thumb or a forefinger) It is preferable to use a pressing-type subject operation unit that performs pressing operation in In such a case, when the subject presses the subject operation unit 31, the subject operation unit 31 is switched from the off state to the on state, and the on signal is output from the subject operation unit 31. The on signal is taken into the control unit 30.

<2. Procedure of eye muscle function test>
Then, the procedure (eye muscle function inspection method) of an inspection using eye inspection device 1 concerning an embodiment of the present invention is explained.

First, the presenting position of the visual target will be described prior to the description of the specific inspection procedure.
Presentation of the visual target to the subject is performed by displaying the visual target on the display surface 12 a of the display element 12. The central visual target is presented at the central position of the visual field of the subject, and the examination visual target is presented around it. Therefore, when the apparatus main body 5 is configured such that the center of the field of view of the subject coincides with the center of the display surface 12a of the display element 12, the display position of the central visual target is set to the center of the display surface 12a. The display position of the test target is set around it.

  Further, the presentation position of the visual target will be described, for example, as shown in FIG. 4 using a figure imitating a hess screen. However, the presenting position of the visual target illustrated here is just an example.

  The presentation positions of the visual targets include the presentation position P0 of the central visual target and the presentation positions P1 to P8 of the test visual target. The presentation position P0 of the central visual target is set at the center of the screen. The center of the screen corresponds to the center of the subject's field of view. The presenting positions P1 to P8 of the test target are set around the presenting position P0 of the central target. More specifically, the presenting position P1 of the test target is set above the presenting position P0 of the central target, and the presenting position P2 of the test target is set below the presenting position P0 of the central target . The presenting position P3 of the test target is set to the left of the presenting position P0 of the central target, and the presenting position P4 of the test target is set to the right of the presenting position P0 of the central target. The presenting position P5 of the test target is set at the upper left of the presenting position P0 of the central target, and the presenting position P6 of the test target is set at the upper right of the presenting position P0 of the central target. The presenting position P7 of the test target is set to the lower left of the presenting position P0 of the central target, and the presenting position P8 of the test target is set to the lower right of the presenting position P0 of the central target.

On the above-mentioned screen, presentation of targets is performed, for example, in the following order (1) to (8).
(1) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P1.
(2) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P2.
(3) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P3.
(4) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P4.
(5) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P5.
(6) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P6.
(7) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P7.
(8) The central visual target is presented at the presentation position P0, and then the examination visual target is presented at the presentation position P8.

  As described above, when the central visual target and the test visual target are presented in order and each visual target is shown to the subject, the eyeball of the subject is the presentation position P0 of the central visual target and the presentation position P1 of the test visual target. It moves as follows according to ~ P9. That is, when the target is presented as in the above (1), the eyeball of the subject moves upward from the state of the front view, and when the target is presented as in the above (2) The eyeballs of the person move downward from the front view state. In addition, when the target is presented as in the above (3), the eyeball of the subject moves leftward from the state of front view, and when the target is presented as in the above (4), the test The eyeball of the person moves to the right from the state of front view. In addition, when the target is presented as in the above (5), the eyeball of the subject moves from the state of front view to the upper left, and when the target is presented as in the above (6) The eyeball of the person moves from the front view to the upper right. In addition, when the target is presented as in (7) above, the subject's eye moves from the front view to the lower left direction, and when the target is presented as in (8) above, the subject is examined The eyeballs of the person move from the front view to the lower right.

Thereby, it can be inspected whether there is any abnormality in the movement of the eyeball shown to the following (a)-(h).
(A) Movement of eyeball when looking upward from the state of front view.
(B) Movement of the eyeball when looking down from the state of front view.
(C) Movement of eyeball when looking left from the state of front view.
(D) Movement of the eyeball when looking to the right from the state of front view.
(E) Movement of the eyeball when looking left upper from the state of front view.
(F) Movement of the eyeball when looking from the front view to the upper right.
(G) Movement of the eyeball when looking left downward from the state of front view.
(H) Movement of the eyeball when looking downward to the right from the front view state.

Next, the procedure of the eye muscle function test will be described.
First, the head mount type eye examination apparatus 1 (apparatus main body 5) is attached to the head of the subject, and the subject operation unit 31 is held by the subject's hand. Next, the examiner operates the terminal 45 to instruct the control unit 30 to display (present) the central visual target. Then, in response to this instruction, the display control unit 43 first displays the central visual indicator on the display surface 12 a of the display element 12. The display position of the central visual target is a position corresponding to the presentation position P0 described above. As a result, as shown in FIG. 5, the center target M0 is presented to the subject at the presentation position P0. After presenting the central target in this manner, the examiner instructs the subject to press the subject operation unit 31 while looking at the central target.

  In addition, only the central visual target may be displayed on the display element 12, or the central visual target may be displayed together with the grid of the hess screen. Further, the central visual target may be displayed on only one of the display elements 12L and 12R, or may be displayed on both of them. When the central visual indicator is displayed on only one of the display elements 12L and 12R, the subject will see the central visual indicator with one eye, and the central visual indicator is displayed on both of the display elements 12L and 12R The subject will see this central visual target with both eyes. When the subject sees the central visual target with both eyes, the subject himself / herself sees the image of the central visual target seen with the left eye 8 L and the image of the central visual target seen with the right eye 8 R It will be recognized as a single image in the brain of In the following description, viewing an object such as a target with one eye with a subject is also referred to as "one-eye vision" and viewing with both eyes is also referred to as "binocular vision".

  Next, when the subject presses the subject operation unit 31 according to the instruction of the examiner, an on signal is sent from the subject operation unit 31 to the control unit 30. Then, as shown in FIG. 6, the control unit 30 checks the image data DL0 of the left eye 8L captured by the imaging device 16L and the image data DR0 of the right eye 8R captured by the imaging device 16R. Each is fetched at the timing when the on signal is sent from the user operation unit 31. At this time, the control unit 30 stores the acquired image data DL0 and DR0 of the left eye 8L and the right eye 8R in the memory 44 in association with the presentation position P0 of the central visual target. Thereby, the image data DL0 and DR0 of the left eye 8L and the right eye 8R captured by the imaging elements 16L and 16R are stored in the memory 44 when the subject is binocularly or unilaterally viewing the central visual target. Ru.

  Next, the inspection processing unit 41 specifies the eye positions of the left eye 8L and the right eye 8R using the image data of the eyeballs 8 (8L, 8R) stored in the memory 44 as described above. At this time, the eye position to be specified is the eye position when the subject is looking at the central target with one eye or both eyes. Incidentally, although various methods have conventionally been proposed as methods for specifying the eye position using image data of the eyeball, any method may be applied in practicing the present invention. As an example, the relative position of the pupil and the position of the reflected light at the cornea of the illumination light illuminating the eye are specified by performing image processing on the image data of the eye. There is a method of specifying the eye position from the positional relationship.

  Thereafter, the examiner operates the terminal 45 to instruct the control unit 30 to display the examination visual mark. Then, in response to this instruction, the display control unit 43 displays the examination target on the display surface 12 a of the display element 12. The test target may be displayed in a state in which the display of the central target is extinguished, or may be displayed in a state in which the central target is displayed. Further, only the inspection target may be displayed on the display element 12, or the inspection target may be displayed together with the grids of the screen. The display position of the test target is a position corresponding to the above-described presentation position P1. As a result, as shown in FIG. 7, the test target M1 is presented to the subject at the presentation position P1. At that time, the display control unit 43 controls to display the inspection target on only one of the display elements 12L and 12R. Therefore, the subject sees the test target M1 presented at the presentation position P1 by the display element 12 with one eye. Here, as an example, a test chart is displayed only on the display element 12L, and the test chart is viewed by the subject with the left eye 8L. At this time, the examiner instructs the subject to press the subject operation unit 31 while looking at the examination target.

  Incidentally, when the examination target is displayed only on the display element 12L, the subject sees the examination target with only the left eye 8L. However, since the human eye catches the object by the joint eye movement (peeling movement) in which both eyes point in the same direction, the left eye 8L and the right eye 8R can display the examination target only on the display element 12L. , Move together in the direction of the presentation position of the test target. This point is the same as when the inspection target is displayed only on the display element 12R.

  Next, when the subject presses the subject operation unit 31 in accordance with the instruction of the examiner, an on signal is sent from the subject operation unit 31 to the control unit 30 again. Then, as shown in FIG. 8, the control unit 30 checks the image data DL1 of the left eye 8L captured by the imaging device 16L and the image data DR1 of the right eye 8R captured by the imaging device 16R. Each is fetched at the timing when the on signal is sent from the user operation unit 31. At this time, the control unit 30 stores the acquired image data DL1 and DR1 of the left eye 8L and the right eye 8R in the memory 44 in association with the presenting position P1 of the examination index. Thereby, the image data DL1 and DR1 of the left eye 8L and the right eye 8R captured by the imaging elements 16L and 16R are stored in the memory 44 when the subject is looking monocularly on the examination target.

  Next, the inspection processing unit 41 specifies the eye positions of the left eye 8L and the right eye 8R using the image data of the eyeballs 8 (8L, 8R) stored in the memory 44 as described above. The eye position to be specified at this time is the eye positions of the left eye 8L and the right eye 8R when the subject looks at the examination target with only the left eye 8L.

  Next, the inspection processing unit 41 detects the eye movement amount of the left eye 8L and the eye movement amount of the right eye 8R, and then detects the difference between the eye movement amount of the left eye 8L and the eye movement amount of the right eye 8R. The result is stored in the memory 44. The eye movement amount is the eye position specified based on the image data of the eye 8 when the subject is looking at the central visual target, and the image data of the eye 8 when the subject is looking at the examination target Based on the displacement amount of the eye position specified based on, it detects. The eye movement amount is separately detected by the left eye 8L and the right eye 8R, and the difference between them is detected as the difference between the eye movement amount of the left eye 8L and the eye movement amount of the right eye 8R. As a method of detecting the eye movement amount, there is a method in which the above-described eye position specifying method is applied to the starting point and the end point of eye movement, and the difference between eye positions is the movement amount. In the practice of the present invention, eye movement may be detected using a method other than the above.

  The above is the description of the examination procedure in the case where the central visual target and the examination visual target are presented in the order of the above (1), but the same examination procedure as this is mainly performed in the respective order of the above (2) to (8) Repeat also when presenting the target and the test target. In that case, the image data of the eyeball 8 when the subject is looking at the central visual target may be taken each time the central visual target is presented to the subject, or the central visual target may be read first to the subject. It may be captured only when presented.

  Thereafter, the display control unit 43 controls the display target 12R to display the examination target only in accordance with an instruction from the terminal 45, thereby switching the target presenting the examination target from the left eye 8L to the right eye 8R. Repeat the same inspection procedure as above.

  This completes the eye muscle function test. Thereafter, the test result output unit 42 outputs the detection result (test result) of the eye muscle function test detected by the test processing unit 41 according to the above-described test procedure. At that time, the inspection result output unit 42 uses the information stored in the memory 44 by the inspection processing unit 41 during the inspection to create output data of the inspection result, and outputs the output data to the terminal 45 by wire or wirelessly. By transmitting, the monitor of the terminal 45 displays the inspection result. The inspection result can also be printed out on a sheet, if necessary. In that case, a printer may be connected to the control unit 30 or the terminal 45, and the output data of the inspection result may be transmitted to this printer.

  The output data of the inspection result is preferably created so that it can be output in the form of a Hess chart. Below, the example of an output of a specific example test result is shown.

FIG. 9 (A) shows the test result of the left eye in the form of a hesschart, and FIG. 9 (B) shows the test result of the right eye in the form of a hesschart.
The test result of the left eye shown in FIG. 9A is the left when the subject looks at the test target of each presentation position (position shown by a black circle in the drawing) P1 to P8 using the right eye 8R. It reflects the difference between the eye movement amounts of the eye 8L and the right eye 8R. Specifically, at each of the presentation positions P1 to P8, where the amount of movement of the left eye 8L is large compared to the amount of movement of the right eye 8R, the test result is plotted outside the display position of the test target (in FIG. When the amount of movement of the left eye 8L is small, the test result is plotted inside the presenting position of the test target. Similarly to this, the test result of the right eye shown in FIG. 9 (B) is the left eye 8L and the right when the subject looks at the examination target of each presentation position P1 to P8 using the left eye 8L. It reflects the difference in eye movement of the eye 8R.

  In the eye muscle function test described above, if there is no eye movement disorder in both eyes, the left eye 8L and the right eye 8R move approximately the same amount according to the presenting position of the examination target, so the left eye 8L and the right eye 8R The difference in eye movement is relatively small. On the other hand, when one eye has no movement disorder and the other eye has movement disorder, the movement of the other eye is worse than the movement of one eye. Therefore, the difference between the eye movement amounts of the left eye 8L and the right eye 8R becomes relatively large. Therefore, the examiner can determine the presence or absence of the eye movement disorder, the degree of the disorder, and the like by viewing the examination result displayed on the monitor of the terminal 45. For example, in the test results shown in FIGS. 9A and 9B, since the size of the figure indicating the movement of the right eye is considerably smaller than that of the left eye, movement disorder occurs in the right eye I understand that.

<3. Effect of embodiment>
In the eye examination apparatus 1 according to the embodiment of the present invention, when the test subject is presented to the subject using the display element 12, and the eyeball of the subject moves in the direction of the presentation position of the test subject The presence or absence of eye movement disorder is examined by detecting the difference in eye movement of the left eye 8L and the right eye 8R using the image data of the left eye 8L and the right eye 8R captured by the imaging elements 16L and 16R. be able to. This eliminates the need for the subject to indicate the position of a spot or the like on the screen using an indicator or the like as in the prior art. For this reason, the burden on the subject can be reduced at the time of the examination of the eye movement disorder.

  Further, in the present embodiment, since the inspection result output unit 42 displays and outputs the detection result by the inspection processing unit 41 on the monitor of the terminal 45, the examiner sees the detection result displayed on the monitor The presence or absence of can be determined. This eliminates the need for the examiner to copy on the inspection sheet the position of the spot that the subject instructed with the indicator or the like as in the prior art. For this reason, it is possible to reduce the burden on the examiner when examining the eye movement disorder.

  In addition, since the inspection result output unit 42 outputs the detection result by the inspection processing unit 41 in the form of a hesschart, the examiner determines the eye movement disorder according to the conventional diagnostic method from the heschart indicated by the detection result. Can be diagnosed.

  Further, in the above embodiment, the display optical system 11, the display element 12, the observation optical system 15, the imaging element 16 and the like necessary for the eye muscle function test are built in the apparatus main body 5 mounted on the head of the subject The head-mounted device configuration is adopted. This eliminates the need for a large screen or the like for displaying the hess screen. Therefore, the eye inspection apparatus can be miniaturized.

<4. Modified example etc>
The technical scope of the present invention is not limited to the above-described embodiments, and includes various modifications and improvements as long as specific effects obtained by the constituent elements of the invention and the combination thereof can be derived.

  For example, in the above-described embodiment, the image data of the eye 8 captured by the imaging device 16 is taken into the control unit 30 at the timing when the subject operation unit 31 is pressed. The present invention is not limited to this, and a configuration may be adopted in which the examiner instructs the control unit 30 using the terminal 45 to acquire the image data.

  In the above embodiment, although the configuration using the subject operation unit 31 is shown, the result of the eye movement of the subject is detected only by causing the target to follow, and the subject's An eye muscle function test may also be considered to determine and evaluate the end point of eye movement. In this case, since the subject only looks at the target, further burden reduction is possible.

DESCRIPTION OF SYMBOLS 1 ... Eye inspection apparatus 8 ... Eyeball 11 ... Display optical system 12 ... Display element 15 ... Observation optical system 16 ... Image pickup element 41 ... Inspection processing part 42 ... Inspection result output part

Claims (6)

Mark presenting means capable of presenting marks individually to the left eye and the right eye of the subject;
Imaging means for individually imaging the left eye and the right eye of the subject;
A subject operation unit operated by the subject for response;
The left eye and the right eye when the eyeball of the subject moves in the direction of the presentation position of the test visual target when the test target is presented to one eyeball of the subject by the visual target presenting means A detection unit that detects the difference in the amount of eye movement of the eye based on the image data of the left eye and the right eye captured by the imaging unit at a timing when the subject operation unit is operated by the subject ;
An eye inspection apparatus comprising: The target presenting means presents a central target at a central position of a field of view with respect to at least one of the left eye and the right eye of the subject, and the target presenting means of the left eye and the right eye of the subject Presenting the examination target at a position different from the presentation position of the central target with respect to any one of the eyeballs,
The detection unit is configured such that the subject operation unit is pressed by the subject when the subject sees the central target presented by the target presenting unit with one eye or both eyes. The subject's operation when the subject is looking with one eye with the image data of the left eye and the right eye captured by the imaging means at the timing and the examination visual target presented by the visual target presenting means A difference in eye movement between the left eye and the right eye is detected using the image data of the left eye and the right eye captured by the imaging unit at a timing when the subject is pressed by the subject. The eye inspection apparatus according to claim 1. The eye inspection apparatus according to claim 1, further comprising an output unit that outputs a detection result of the detection unit. The eye inspection apparatus according to claim 3, wherein the output means outputs the detection result in the form of a hess chart. The eye examination apparatus according to any one of claims 1 to 4, wherein the eye examination apparatus is an eye muscle examination apparatus for examining an eye muscle function. The eye inspection apparatus according to any one of claims 1 to 5, wherein the visual target presenting means and the imaging means are incorporated in an apparatus main body mounted on a head of the subject. .

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