JP4272002B2 - Sight meter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a visual acuity meter that can be commonly used for measurement of various visual acuities such as normal visual acuity, night vision, moving visual acuity, and static visual acuity.
[0002]
[Prior art]
Conventionally, a visual acuity meter measures the moving visual acuity to measure at which point an approaching target can be discriminated, and changes the optical distance and apparent size of the target step by step, and at which position the target is located. Static visual acuity measurement for measuring whether or not recognition is possible has been performed (see, for example, Patent Document 1).
[0003]
The visual acuity meter described in the above-mentioned Patent Document 1 is displayed with a target display means capable of displaying a plurality of types of targets or a specific target, an eyepiece for observing the displayed target, An optical system for setting a predetermined optical distance between the visual target and the eyepiece and setting the visual target to a predetermined apparent size, and an optical distance and an apparent size between the eyepiece and the visual target. Means for changing the speed at a predetermined speed. The sight meter measures the static visual acuity based on the visual target observed at the eyepiece when the optical distance and the apparent size are changed stepwise, and the optical distance is continuously at a predetermined speed. When changing, the moving visual acuity is measured on the basis of a visual target observed according to a magnification that changes in the eyepiece.
[0004]
[Patent Document 1]
JP-A-11-137519 (FIGS. 1 and 2)
[0005]
[Problems to be solved by the invention]
According to the sight meter described in the above-mentioned Patent Document 1, it is possible to measure the moving object visual acuity and the static visual acuity in a space-saving manner with a relatively simple configuration. However, for example, in addition to these dynamic visual acuity and static visual acuity, normal visual acuity that is measured by changing the size of the target 5 m ahead from the subject, or low-luminance visual acuity after dark adaptation after light adaptation If an attempt is made to make it possible to measure night vision or the like that measures how many seconds the target can be visually recognized, the number of parts may increase, leading to an increase in the size of the apparatus.
[0006]
In view of the circumstances described above, the present invention can be used in common with other types of visual acuity measurement in addition to moving visual acuity and static visual acuity, and has a simple configuration with a minimal increase in the number of parts. An object of the present invention is to provide a visual acuity meter that does not increase the size of the apparatus.
[0007]
[Means for Solving the Problems]
    That is, according to the first aspect of the present invention, the first and second targets (50a, 50b) are arranged on the measurement optical path (P) to the eyepiece opening (3a, 3b) corresponding to the eye to be examined (4a, 4b). , 12A to 12C..., 12a to 12c..., 27a to 27d) are provided along the measurement optical path so that the first and second target plates (12, 27) can be selectively presented from a plurality of types. A bypass unit (51a, 51b) that is sequentially disposed from the eyepiece opening side and opens the measurement optical path between the eyepiece opening and the second eyeplate on the first target plate. Provided,
    Provide input means (35-38) that can select the first and second measurement modes;
    There is provided first measurement visual acuity presentation means (17) capable of moving and driving the first visual target plate (12) to present a predetermined visual target on the measurement optical path (P),
    There is provided second measurement visual acuity presentation means (28) that can move and drive the second visual target plate (27) to present a predetermined visual target on the measurement optical path (P),
    When the first measurement mode is selected by the input means (for example, 37, 38), the first visual target plate (12) is moved and driven by the first measurement visual acuity presentation means (17). First control means (30) is provided for controlling the predetermined first target (50a, 50b, 12A to 12C..., 12a to 12c...) To be presented on the measurement optical path (P). ,
    When the second measurement mode is selected by the input means (for example, 36, 35), the first target plate (12) is moved and driven to measure the bypass portions (51a, 51b). While positioning on the optical path (P), the second target visual plate (27) is moved and driven by the second measurement visual acuity presenting means (28), and the predetermined second visual target (27a to 27d). Is provided with second control means (30) for controlling to be presented on the measurement optical path (P)And
    By moving along the measurement optical path on the measurement optical path (P) between the first visual target plate (12) and the second visual target plate (27), the eyepiece openings (3a, 3b) ) And the second optotype plate (27) and the apparent size of the second optotype (27a to 27d) observed on the eyepiece opening (3a, 3b) side. The optical distance and size variable means (26) that can be changed are arranged.
[0009]
    In the present invention,2The present invention is arranged on the measurement optical path (P) between the first target plate (12) and the optical distance and size variable means (26), and the optical distance and size variable means ( 26) includes light splitting means (18, 19) that can split the light passing through the left and right eye (4a, 4b).
[0010]
    In the present invention,3According to the present invention, the first visual target illumination means (53) capable of illuminating the first visual target (12A-12C ..., 12a-12c ...) presented on the measurement optical path (P) from the back, A half mirror (20A) disposed at a predetermined angle on the measurement optical path (P) between the light splitting means (18, 19) and the optical distance and size variable means (26);
    The first target illumination means includes a single light source (53) disposed on the back surface of the half mirror (20A).
[0011]
    In the present invention,4The present invention provides a peripheral illumination means (10a) capable of illuminating the periphery of the first visual target (12A-12C ..., 12a-12c ...) presented on the measurement optical path (P),
    A brightness adjusting means (39) of the ambient illumination means is provided.
[0012]
    In the present invention,5According to the present invention, the first visual target (12A to 12C) arranged on the eyepiece opening (3a, 3b) side of the first visual target plate (12) and presented on the measurement optical path (P), 12a to 12c...) Can be illuminated from the back side of the second visual target illumination means (59, 61) that can illuminate the eyepiece opening side and the first visual target presented on the measurement optical path (P). A first target illumination means (22, 24 or 53) is provided.
[0013]
    In the present invention,6According to the present invention, brightness adjustment means (39) capable of variably adjusting the brightness of the first target illumination means (22, 24 or 53) or the second target illumination means (59, 61). 64).
[0014]
【The invention's effect】
As described above, according to the first invention of the present invention, when the first measurement mode is selected by the input means (for example, 37), the first control means (30) is used as the first target. For example, when control is performed so that a predetermined one of the targets (12A to 12C..., 12a to 12c...) For normal visual acuity measurement is presented on the measurement optical path (P), the normal visual acuity of the eye to be examined (4a, 4b) It becomes possible to measure. Further, when the first measurement mode is selected by the input means (for example, 38), the first control means (30) uses, for example, the bright order applied visual targets (50a, 50b) as the first optical targets as the measurement optical path. (P) When controlled to be presented above, for example, after giving light adaptation for a predetermined time, other first targets (for example, 12A to 12C..., 12a to 12c. By changing, it becomes possible to measure the night vision of the eye to be examined.
[0015]
In addition, when the second measurement mode is selected by the input means (for example, 36, 35), the second control means (30) positions the bypass portions (51a, 51b) on the measurement optical path (P). At the same time, since control is performed so that a predetermined one of the second visual targets (27a to 27d) is presented on the measurement optical path (P), for example, the eyepiece opening (3a, 3b) and the second visual target are moved by the movement. By providing optical means capable of changing the optical distance between the marking plates (27) and the apparent size of the second visual targets (27a to 27d) observed on the eyepiece openings (3a, 3b) side, For example, it is possible to measure, for example, moving visual acuity and static visual acuity of the optometry (4a, 4b). As described above, the first visual target plate (12), the second visual target plate (27), and the like can be used to measure other types of visual acuity such as normal visual acuity as well as the moving visual acuity and the static visual acuity. By appropriately using the combinations, it is possible to reduce the number of parts as much as possible, to simplify the device configuration, and to realize a visual acuity meter that does not increase the size of the device.
[0016]
    furtherSince the optical distance and size variable means (26) is disposed on the measurement optical path (P) between the first target plate (12) and the second target plate (27), for example, input When the second measurement mode is selected by the means (for example, 36, 35), the first target plate (12) is moved and driven to position the bypass portions (51a, 51b) on the measurement optical path (P). In this state, the optical distance and size variable means (26) is selectively moved and driven to optical distance between the eyepiece opening (3a, 3b) and the second visual target (27a-27d) and the eyepiece opening (3a, It is possible to measure moving visual acuity and static visual acuity by changing the apparent size of the visual target observed on the 3b) side continuously or stepwise.
[0017]
    In the present invention,2According to the invention, since the light splitting means (18, 19) is provided on the measurement optical path (P) between the first target plate (12) and the optical distance and size variable means (26), the optical distance is provided. And the light passing through the size varying means (26) is divided before the first target plate (12) so as to correspond to the left and right eyes (4a, 4b), and then the first target plate ( 12) can enter the entrance apertures (13a, 13b).
[0018]
    In the present invention,3According to the invention, the illumination light of the first target illumination means that is one light source (53) is transmitted through the half mirror (20A), and the left and right eyes (4a) are divided by the light dividing means (18, 19). 4b), it is possible to efficiently illuminate the first visual targets (12A to 12C..., 12a to 12c...) Toward the left and right eyes. As described above, when the target illumination light source is composed of one light source, the number of the light source and the parts associated therewith can be reduced, which contributes to further simplification of the apparatus configuration.
[0019]
    In the present invention,4According to the invention, since the peripheral illumination means (10a) and the brightness adjustment means (39) of the peripheral illumination means are provided, the periphery of the first visual target (12A to 12C..., 12a to 12c. By illuminating with the peripheral illumination light source (10a), it is possible to prevent the subject from feeling uncomfortable due to the first visual target and its peripheral appearance, and to make the visual acuity measurement more accurate.
[0020]
    In the present invention,5According to the invention, the second visual target illumination means (59, 61) capable of illuminating the presented first visual targets (12A to 12C..., 12a to 12c...) From the eyepiece opening side and the back surface illumination. Since the 1st target illumination means (22, 24 or 53) which can be provided was provided, the 1st target (12A- 12A-) is set by setting the brightness of the 1st and 2nd target illumination means suitably. 12C ..., 12a-12c ...) The contrast visual acuity can be measured when the surrounding contrast is reduced. At this time, when the contrast around the observed first target is reduced, the subject observes the first target in a dim state (low contrast state) such as a dusk state in the evening. Become.
[0021]
    In the present invention,6According to the invention, the brightness adjusting means (39) corresponding to the first target illumination means (22, 24 or 53) or the second target illumination means (59, 61) is provided. When measuring the contrast visual acuity, the brightness of the first visual target illumination means or the second visual target illumination means can be easily adjusted by the brightness adjustment means (39). The optimum state can be easily obtained.
[0022]
Note that the numbers in parentheses are for the sake of convenience indicating the corresponding elements in the drawings, and therefore the present description is not limited to the descriptions on the drawings.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a diagram showing an example of a sight meter to which the present invention is applied, in which (a) is a front view, (b) is a side view, and FIG. 2 is a first embodiment of a sight meter according to the present invention. (A) is a block diagram schematically showing the configuration of the acuity meter, (b) is a schematic plan view showing the state viewed in the direction of arrow AA in FIG. 2 (a), FIG. 3 is a front view showing a first target plate, and FIG. 4 is a front view showing a second target plate. FIG. 5 is a diagram showing the configuration of the sight meter according to the second embodiment of the present invention, wherein (a) is a block diagram schematically showing the configuration of the sight meter, and (b) is FIG. 5 (a). FIG. 6 is a schematic plan view showing the state viewed in the direction of arrows B-B in FIG. 6, FIG. 6 is a diagram showing the configuration of the third embodiment of the visual acuity according to the present invention, and FIG. The block diagram shown roughly, (b) is a schematic plan view shown in the state seen in CC arrow direction in Fig.6 (a).
[0024]
Hereinafter, the sight meter 1 according to the present invention will be described in order along the first to third embodiments.
[0025]
<First Embodiment>
A visual acuity meter 1 to which the present invention is applied has a main body 2 formed in a box shape as shown in FIG. 1 (a), an eyepiece 3 is provided on the front of the main body 2, and An operation panel 5 having a predetermined switch is provided on the side surface of the main body 2 as shown in FIG. The sight meter 1 includes a visual target (described in detail later) provided on a measurement optical path P between the eyepiece 3 and the visual illumination light source 63 (see FIG. 2B). The visual acuity is measured based on whether or not the subject's response to the target is correct.
[0026]
The visual acuity meter 1 is a normal visual acuity measurement and light adaptation adapted to measure by changing the size of the target located at a predetermined distance (for example, 5 m) from the subject's eyes 4a and 4b (see FIG. 2 (b)). Night vision measurement that measures how many seconds a low-luminance target can be viewed in dark adaptation later, and moving visual acuity measurement that measures when a target that approaches continuously at a constant speed can be distinguished In addition, the optical distance to the visual target and the apparent size are changed in stages, and the static visual acuity measurement for measuring the size of the visual target can be performed.
[0027]
Lenses 15a and 15b are inserted into and removed from the eyepiece 3 in a timely manner so that the subject can observe a target (a first target and a second target described later) provided inside the main body 2. The binocular eyepiece openings 3a and 3b (see FIG. 1) are provided. The lenses 15a and 15b have eyepiece openings when measuring normal visual acuity using the first visual targets 12A, 12B, 12C..., 12a, 12b, 12c... On the first visual target plate 12 shown in FIG. Inserted in 3a and 3b. Further, in order to improve the observation state by the subject, a dark screen 7 is provided above the eyepiece 3 in FIG. Furthermore, response switches 8A and 8B for responding when the subject recognizes the visual target are provided below the eyepiece 3 in the figure. These response switches 8A and 8B constitute the response switch device 8 shown in FIG. 2 and the like. The response switch 8A is pressed when the subject recognizes the target, and the response switch 8B The so-called joystick type tilting operation is performed according to the cut direction of the Landolt ring of the recognized target. The response switch 8B includes a main body portion 9a and a stick portion 9b that is tilted with respect to the main body portion 9a. On the surface of the main body 9a, a display corresponding to the Landolt ring of the visual target presented to the subject is made on the top, bottom, left and right with the stick portion 9b standing at the center of the main body 9a. ing. As the response switch device 8, it is also possible to use a configuration in which the response switches 8A and 8B are integrated.
[0028]
In the main body 2, an optical device 2a shown in the lower part of FIG. 2A and a control device 2b shown in the upper part of FIG.
[0029]
As shown in FIGS. 2A and 2B, the optical device 2 a includes a reflection case 13 having the eyepiece 3 on the measurement optical path P between the eyepiece 3 and the target illumination light source 63. The first target plate 12, the first target plate rotation motor 17 made of, for example, a stepping motor for rotating the target plate 12, the half mirrors 18 and 19, the total reflection mirror 20, and the correction A lens 25, a prism 26 that is moved in the directions of arrows D and E in FIG. 2B based on the operation of a prism moving motor (not shown), a second target plate 27, and the target plate 27 A second target plate rotation motor 28, for example, a stepping motor to be rotated, and a target illumination light source 63 disposed on the back surface of the target plate 27 via a diffusion plate 29 (that is, a test target side (that is, a target plate) The eyepiece opening side is provided in order. Visual illumination light sources (first visual illumination means) 22 and 24 are arranged on the back surfaces of the half mirrors 18 and 19 via diffusion plates 21 and 23, respectively. The target illumination light sources 22, 24, and 63 can all be constituted by light emitting diodes (LEDs).
[0030]
Further, as described above, the first target plate rotation motor 17 and the second target plate rotation motor 28 can each be composed of a stepping motor, but in that case, they are generated with a required duty ratio. By supplying a pulse signal to the motors 17 and 28 at a predetermined timing, it is easy to control the first visual target plate 12 and the second visual target plate 27 by rotating them at predetermined angles in predetermined directions. Can be executed.
[0031]
The reflection case 13 has a pair of hollow members 13A and 13B having a box shape or a cylindrical shape, for example, disposed at positions facing the subject's left and right eyes 4a and 4b, respectively. The hollow member 13 </ b> A has an eyepiece opening 3 a on one end side in the axial direction, and the other end side from the target illumination light source 22 and the target illumination light source 63 via the first target plate 12. An incident opening 13a for taking in illumination light is provided. Further, the hollow member 13B has an eyepiece opening 3b on one end side in the axial direction, and on the other end side, from the target illumination light source 22 and the target illumination light source 63 via the first target plate 12. Is provided with an incident opening 13b.
[0032]
The hollow members 13A and 13B are located above the eyepiece openings 3a and 3b on one end side,NormalA peripheral illumination light source 10a (see FIG. 2 (a)) capable of illuminating the periphery of the target in the reflection case 13 at the time of visual acuity measurement is provided, and illumination received from the peripheral illumination light source 10a on each inner wall A diffusive member for diffusing light is provided. Also, a halogen lamp 49, which is a light source for light adaptation at the time of night vision measurement, is disposed inside the hollow members 13A and 13B so as to be positioned below the eyepiece openings 3a and 3b on one end side. . In FIG. 2A, the ambient illumination light source 10a is illustrated only on the hollow member 13B side for convenience.
[0033]
The peripheral illumination light source 10a can illuminate the periphery of the observed target (within the viewing angle centered on the target), that is, the outer periphery of the incident apertures 13a and 13b that can be observed through the lenses 15a to 15d. In order to illuminate the inner wall 13c, it is provided at a position substantially opposite to the incident openings 13a and 13b. Further, for example, white LEDs can be used for the target illumination light sources 22 and 24, the target illumination light source 63, and the ambient illumination light source 10a. In that case, since the luminance can be finely and easily adjusted according to the forward current, the luminance unevenness can be easily prevented.
[0034]
In the eyepiece 3 of the hollow member 13A, a shutter 11a is arranged so as to be able to advance and retreat with respect to the lens 15a located in the eyepiece opening 3a, and a lens so as to advance and retreat to a position adjacent to the lens 15a. 15c is arranged. In the eyepiece 3 of the hollow member 13B, the shutter 11b is arranged so as to be able to advance and retract with respect to the lens 15b located in the eyepiece opening 3b, and can advance and retract to a position adjacent to the lens 15b. A lens 15d is disposed on the front side.
[0035]
The shutters 11a and 11b are disposed at positions close to the eyepiece 3, and are inserted into and removed from the measurement optical path P depending on whether the measurement target is the right eye, the left eye, or both eyes. And is made of a suitable material having a light shielding property capable of shielding the illumination by the target illumination light sources 22, 24 and the like.
[0036]
The lenses 15a to 15d and the shutters 11a and 11b are interlocked and connected to an actuator 40 (see FIG. 2A) made of a solenoid or the like so that each can be inserted / removed independently from / from the measurement optical path P. .
[0037]
As shown in FIG. 3, the first visual target plate 12 is made of, for example, a transparent glass material formed in a disc shape, and presents a visual target when measuring normal visual acuity and night vision. It is configured. On the first target plate 12, a large number of targets are provided along two circumferences having a common rotation center 16 and having different diameters.
[0038]
That is, on the circumference on the inner diameter side with the rotation center 16 as the center, the light order applied visual target 50a, the measurement optical path P between the eyepiece 3 and the second visual target plate 27 is opened. An opening (bypass) 51a and first targets 12A, 12B, 12C... Which are Landolt's rings having cuts in any of the four directions, up, down, left and right, are sequentially arranged. Further, in order to open the measurement optical path P between the bright order applied visual target 50 b and the eyepiece 3 and the second visual target plate 27 on the circumference on the outer diameter side centering on the rotation center 16. And first visual targets 12a, 12b, 12c... Which are Landolt's rings having cuts in any of the four directions, up, down, left and right. A transparent member may be fitted into each of the openings 51a and 51b.
[0039]
As described above, the first target plate 12 is formed on the two concentric circumferences, the bright order applied targets 50a and 50b, the openings 51a and 51b, and the first target 12A, which are paired with each other. 12B, 12C ..., 12a, 12b, 12c, etc., so that when measuring normal visual acuity and night vision, the corresponding ones can be simultaneously presented to both eyes 4a, 4b. Has been. And as shown in FIG.2 (b), the said rotation center 16 is so that each part on the said 2 circumference can be correctly made to oppose each entrance opening 13a, 13b of hollow member 13A, 13B. The hollow members 13A and 13B are provided so as to deviate by a predetermined distance from the center position of the whole.
[0040]
The bright order applied optotypes 50a and 50b are referred to as “light order applied optotypes” in the present embodiment because of their function of giving bright adaptation to the eyes 4a and 4b in advance during night vision measurement. In the present invention, the visual targets 12A, 12B, 12C,..., 12a, 12b, and 12c are used as the visual targets presented to the eyepiece openings 3a and 3b by the rotational positioning (moving drive) of the visual target plate 12. ... and a 1st optotype shall be comprised.
[0041]
The rotation center 16 is configured so that the first visual target plate 12 rotates in the directions of arrows E and F shown in FIG. (See b)). Then, by turning the motor 17 by a predetermined angle in a predetermined direction, the bright order applied visual target 50a, the opening 51a and the visual targets 12A to 12C, or the bright order applied visual target 50b, the opening 51b and the visual target. The selected one of 12a to 12c is arranged at a position facing the entrance openings 13a and 13b of the reflection case 13 so that the subject can observe the selected one. Note that the bright order applied visual targets 50a and 50b and the first visual targets 12A to 12C..., 12a to 12c.
[0042]
Based on the operation of the first target plate rotation motor 17, the first target plate 12 is moved to a first rotation position, a second rotation position, and a third rotation position. It is configured to be able to rotate. Here, the first rotation position is a position for opening the incident openings 13a and 13b of the reflection case 13 so that the second visual targets 27a to 27d are visible from the eyepiece openings 3a and 3b. There are positions where the openings 51 a and 51 b in FIG. 3 are opposed to the incident openings 13 a and 13 b of the reflection case 13, respectively. The second rotation position is a position for shielding the incident openings 13a and 13b, and the bright order applied visual targets (first visual targets) 50a and 50b in FIG. It is a position where the illumination light from the first target plate 12 side to the eyepiece openings 3a and 3b can be substantially shielded so as to face 13a and 13b.
[0043]
Further, the third rotation position refers to the first visual targets 12A to 12C that are illuminated by the visual target illumination light sources 22 and 24 (the visual target illumination light source 53 in the second embodiment to be described later). ˜12c is a rotational position for enabling visual recognition of the eyepiece openings 3a and 3b, and is a view in front of the light-applied applied visual target (first visual target) 50a from the first visual target 12A in the downward arrow direction. The entire range up to the target, that is, an angular range corresponding to approximately one rotation of the target plate 12, symbols R1 to R in FIG._NIt means the movable range up to. At this time, the position at the time of rotation on the first visual target 12a to the bright order applied visual target (first visual target) 50b side is the movable range R1 to R._NAre automatically determined at the time when the first visual targets 12A to 12C. As described above, when the first visual target plate 12 reaches the third rotation position, the movable ranges R1 to R1._NIs rotated and stopped in a timely manner.
[0044]
The half mirrors 18 and 19 are arranged in the measurement optical path P so as to maintain an incident angle of 45 ° and a reflection angle of 45 °, and the path of the illumination light from the target illumination light source 63 is 90 to the subject side. ° Has a function to convert. The half mirror 19 receives the illumination light reflected by the total reflection mirror 20, reflects a part of the illumination light to the incident opening 13b side, and transmits the remaining light component to the half mirror 18 side. The half mirror 18 reflects a part of the illumination light received from the half mirror 19 side to the incident opening 13a side.
[0045]
Further, the half mirrors 18 and 19 transmit illumination light received from the target illumination light sources 22 and 24 that are turned on when necessary via the diffusers 21 and 23 to the rear surface of the first target plate 12. Let go. The half mirrors 18 and 19 transmit the illumination light from the target illumination light source 63 via the prism 26 on the measurement optical path P between the first target plate 12 and the prism 26 to the left and right eyepiece openings 3a and 3a. The light splitting means that can split in accordance with 3b is configured. Due to the presence of such a light splitting means, the illumination light passing through the prism 26 is split into left and right before the first target plate 12 and then is efficiently passed through the first target plate 12 to the incident openings 13a and 13b. You can enter well.
[0046]
The total reflection mirror 20 directs the path of illumination light that passes through the second target plate 27 from the target illumination light source 63 and enters via the prism 26 and the correction lens 25 toward the half mirrors 18 and 19. Convert 90 °.
[0047]
The prism 26 is disposed on the measurement optical path P between the first target plate 12 and the second target plate 27, and the first target plate 12 is positioned at the first rotation position. When moving, the optical distance moved between the eyepiece openings 3a and 3b and the second visual targets 27a to 27d is moved in the directions of arrows D and E by driving a prism moving motor (not shown). The distance and size variable means are configured.
[0048]
As shown in FIG. 4, the second visual target plate 27 is made of, for example, a transparent glass material formed in a disk shape, and presents a visual target when measuring moving visual acuity and static visual acuity. . On the second target plate 27, there is a Landolt ring having a rotation center 37 and a plurality of targets along one circumference, that is, a cut in any of the four directions of up, down, left and right. The second visual targets 27a, 27b, 27c, and 27d are sequentially arranged at equiangular intervals. The second visual targets 27a to 27d can be formed of a coating material, for example.
[0049]
The rotation center 37 is a rotation axis of the target plate rotation motor 28 (see FIG. 2B) so that the second target plate 27 can rotate in the directions of arrows G and H shown in FIG. ) Is engaged. Then, the first visual target plate 12 is selected so that the selected one of the second visual targets 27a to 27d can be observed by the subject by the rotation of the motor 28 by a predetermined angle in the predetermined direction. Are disposed at positions facing the incident openings 13a and 13b of the reflection case 13 through the openings 51a and 51b, respectively.
[0050]
Therefore, when the first target plate 12 is rotated to the first rotation position where the first target plate 12 opposes the openings 51a and 51b to the incident openings 13a and 13b, the second target plate 27 is illuminated with the target. While being illuminated by the light source 63, any one of the second visual targets 27a to 27d is rotated so as to be positioned on the measurement optical path P to the eyepiece openings 3a and 3b.
[0051]
Next, the control device 2b will be described. The control device 2b has a CPU (Central Processing Unit) 30 as shown in the upper part of FIG. 2A. The CPU 30 includes a display 31, a memory 32, a clock 33, an actuator 40, and peripheral components. An illumination light source 10a and a lamp 42 for monitoring the state of the eyelid of the eye to be examined during the bright adaptation of the night vision measurement are connected.
[0052]
Further, a normal visual acuity measurement switch 37, a night visual acuity measurement switch 38, a moving object visual acuity measurement switch 36, and a stationary visual acuity measurement switch 35, which can each select a visual acuity measurement, are connected to the CPU 30 via an interface 34. Furthermore, the CPU 30 receives, via the interface 34, the brightness adjustment switches 39 and 64, the response switch device 8 including the response switches 8A and 8B (see FIG. 1), the voice guidance device 41 that outputs the voice for promoting the progress of automatic measurement, A visual acuity change switch 43, a selection eye switch 44, a visual target switch 45 that can switch the direction of the cut of the Landolt ring, a sensitivity adjustment switch 46 that adjusts the lighting sensitivity of the lamp 42, and the like are connected.
[0053]
The brightness adjustment switch 39 turns on and off the peripheral illumination light source 10a, the target illumination light sources 22 and 24, and the target illumination light source 63, and adjusts the brightness of illumination by each of these light sources. I can do it. The brightness adjustment switch 64 can turn on and off the halogen lamp 49, which is an illumination light source for night vision measurement, and can adjust the brightness of illumination by the halogen lamp 49. Further, the visual acuity change switch 43 can select the first visual targets 12A to 12C..., 12a to 12c..., Or the second visual targets 27a to 27d corresponding to a predetermined visual acuity value. 44 can select visual acuity measurement corresponding to any of the left eye, right eye, or both eyes.
[0054]
The display 31, the normal visual acuity measurement switch 37, the night visual acuity measurement switch 38, the moving visual acuity measurement switch 36, the static visual acuity measurement switch 35, the brightness adjustment switches 39 and 64, the voice guidance device 41, the visual acuity change switch 43, and the selection eye switch 44. The target switch 45 and the sensitivity adjustment switch 46 are disposed at appropriate positions on the operation panel 5 shown in FIG.
[0055]
The CPU 30 receives a target illumination light source 22, 24, a target illumination light source 63, a peripheral illumination light source 10a, and a first target plate provided in the optical device 2a via a power source (not shown) having a predetermined output. A rotation motor 17, a second target plate rotation motor 28, an actuator 40, and the like are connected. Shutters 11a and 11b and lenses 15a to 15d are individually connected to the actuator 40, and by selectively operating the actuator 40, these shutters and lenses can be appropriately inserted into and removed from the eyepiece openings 3a and 3b. I can do it.
[0056]
The normal visual acuity measurement switch 37, the night visual acuity measurement switch 38, the moving object visual acuity measurement switch 36, and the stationary visual acuity measurement switch 35 constitute an input unit that can select the first and second measurement modes.
[0057]
Further, the first target plate 12 is rotated (moved and driven) by the first target plate rotation motor 17 to the second rotational position and the third rotational position, so that a predetermined target target is obtained. Is provided on the measurement optical path P. First measurement visual acuity presenting means is configured. When the CPU 30 operates the normal visual acuity measurement switch 37 or the night visual acuity measurement switch 38 as the input means and selects the first measurement mode (normal visual acuity measurement mode, night visual acuity measurement mode), The first visual target plate 12 is rotated (moved and driven) by the visual target plate rotating motor 17 to the third rotational position and the second rotational position in time, so that the first visual targets 12A to 12C. , 12a to 12c..., And first order control means for controlling so that a predetermined one of the bright order applied visual targets (first visual targets) 50a and 50b is presented on the measurement optical path P. Further, the first control means is accompanied by the luminance adjustment means 39 and 64, so that when the night vision measurement switch 38 is operated as an input means and the night vision measurement mode is selected as the first measurement mode, The first visual target plate 12 is rotated to the second rotational position in order to position the bright order applied visual targets 50a and 50b corresponding to the selection among the plurality of types of first visual targets on the measurement optical path P. In addition, after the halogen lamp 49 is turned on and turned off at a predetermined timing, the target illumination light sources 22 and 24 and the ambient illumination light source 10a are also turned on with a relatively low luminance.
[0058]
On the other hand, a second target visual acuity presenting means capable of presenting a predetermined target on the measurement optical path P by rotating the second visual target plate 27 by the second target plate rotation motor 28 is configured. . When the CPU 30 operates the moving visual acuity measurement switch 36 or the static visual acuity measurement switch 35 as the input means and selects the second measurement mode (moving visual acuity measurement mode, static visual acuity measurement mode), The target plate 12 is rotated (moved) to position the openings (bypass portions) 51 a and 51 b on the measurement optical path P, and the second target plate 27 is moved by the second target plate rotation motor 28. A second control unit is configured to control the movement so that a predetermined one of the second visual targets 27a, 27b, 27c, and 27d is presented on the measurement optical path P. Further, the second control means is configured such that the moving visual acuity measurement switch 36 or the static visual acuity measurement switch 35 is operated as an input means, and the moving visual acuity measurement mode or the static visual acuity measurement mode is selected as the second measurement mode. After the first target plate 12 is rotated and the openings 51a and 51b are positioned on the measurement optical path P, the prism 26 is moved and positioned in conjunction with the rotation of the second target plate 27. It also has a function to control.
[0059]
Since the sight meter 1 has the above-described configuration, for example, at the time of normal visual acuity measurement, the first target plate 12 is rotated to the third rotation position, and the movable ranges R1 to R thereof._N, The first target 12A to 12C..., 12a to 12c... Are illuminated from the back by the target illumination light sources 22 and 24, and the first target 12 is rotated to rotate the first target. It is possible to perform normal visual acuity measurement on the subject's eyes 4a and 4b while changing 12A to 12C.
[0060]
That is, when the normal visual acuity measurement switch 37 as the input means is pressed at the start of the normal visual acuity measurement and the normal visual acuity measurement mode is selected as the first measurement mode, the CPU 30 as the first control means By transmitting a predetermined signal (not shown), the actuator 40 is actuated to appropriately disengage the shutters 11a and 11b from the measurement optical path P. When the left eye visual acuity is measured, the selection eye switch 44 is pressed in advance, so that the left eye-side shutter 11a is detached from the measurement optical path P when the normal visual acuity measurement switch 37 is pressed, and the right eye The eye-side shutter 11b is set so as to be inserted on the measurement optical path P. On the other hand, when measuring the right eye vision, the selection switch 44 is pressed in advance, so that the right-eye shutter 11b is detached from the measurement optical path P, and the left-eye shutter 11a is measured. Set to be inserted above. Then, electric power is supplied to the first target plate rotating motor 17, and the first target plate 12 is rotated to the third rotation position by the operation of the motor 17, so that the first target plate 12. Among the upper first visual targets 12A to 12C, 12a to 12c, for example, the visual targets 12A and 12a corresponding to the same visual acuity value are moved to positions facing the incident openings 13a and 13b of the reflection case 13. .
[0061]
Subsequently, when the visual acuity change switch 43 is pressed and a signal corresponding to a predetermined visual acuity value is input, the CPU 30 as the first control means transmits the predetermined signal to a power source (not shown), thereby The first target plate rotating motor 17 serving as the measurement visual acuity presenting means operates to rotate the first target plate 12 by a predetermined angle in a predetermined direction. Thereby, movable range R1-R in the 3rd rotation position_N, Of the first visual targets 12A to 12C..., 12a to 12c according to the input visual acuity values, a pair of visual targets corresponding to the same visual acuity values are located at positions facing the entrance openings 13a and 13b. Moved. At this time, the first target selected in the eyepiece opening 3a or 3b on the required side opened from the shutter 11a or 11b is presented, and the first illumination source 22 or 24 is turned on to display the first target. The target is illuminated from the back side.
[0062]
In addition, the peripheral illumination light source 10a is turned on in a form in which the luminance is appropriately adjusted by the luminance adjustment switch 39, and illuminates the viewing angle centered on the first target to be observed. In this state, the subject tilts the response switch 8B (stick part 9b) according to the direction of the cut when the cut of the Landolt's ring of the first target can be identified by the eye 4a or 4b. To do. Thereby, since the signal according to the direction recognized by the subject is transmitted to the CPU 30, the CPU 30 measures the normal visual acuity based on the correctness of the subject's response to the presented first visual target. In the normal visual acuity measurement, for example, when the subject cannot identify the cut of the Landolt ring, the examination is advanced by pressing the response switch 8A, and during a certain time after the target is presented. It is also a preferred aspect that the test is advanced by assuming that the target cannot be identified when the response switch 8B is not operated. As described above, the peripheral illumination light source 10a illuminates the periphery of the first target in the reflection case 13, thereby preventing the subject from feeling uncomfortable due to the first target and the way the periphery is viewed. It is possible to measure the visual acuity more accurately.
[0063]
On the other hand, when the night vision is measured, the first target plate 12 is positioned at the second rotation position and the incident openings 13a and 13b are shielded, and the halogen lamp 49 is turned on to reflect the reflection case 13. The interior is illuminated, and the subject's eyes 4a and 4b looking through the eyepiece openings 3a and 3b are subjected to light adaptation for a predetermined time. Further, after the predetermined time has elapsed, the halogen lamp 49 is turned off, the first target plate 12 is rotated to the third rotation position, and the movable ranges R1 to R at the third rotation position are set._N, The first visual target plate 12 is rotated to change the first visual targets 12A to 12C..., 12a to 12c. Thus, the night vision of the eyes 4a and 4b to be examined is measured.
[0064]
That is, at the start of night vision measurement, when the night vision measurement switch 38 which is an input means is pressed and the night vision measurement mode is selected as the first measurement mode, the CPU 30 as the first control means By transmitting a predetermined signal (not shown), the actuator 40 is actuated to appropriately disengage the shutters 11a and 11b from the measurement optical path P. In synchronization with this, the first target plate rotation motor 17 rotates by a predetermined angle in a predetermined direction, whereby the first target plate 12 is rotated to the second rotation position to be bright. The forward applied visual targets (first visual targets) 50a and 50b are moved so as to face the entrance openings 13a and 13b, respectively, and the hollow members 13A and 13B are shielded. Then, in a state where the subject looks into the eyepiece opening 3a or 3b opened from the shutter 11a or 11b, the halogen lamp 49 which is illumination for light adaptation at the time of night vision measurement is turned on, and the hollow member 13A or The inside of 13B is illuminated for a predetermined time, and bright adaptation is given to the subject's eye 4a or 4b.
[0065]
After the elapse of the predetermined time, the halogen lamp 49 is turned off based on the signal from the CPU 30 as the first control means, and the target plate rotation motor 17 is operated to move the first target plate 12. It is rotated to a predetermined target at the third rotation position. The target may be either a preset target or a target set at the start of examination or during light adaptation.
[0066]
The subject presses the response switch 8A at the time when the subject eye 4a or 4b can identify the cut of the Landolt's ring of the first target in the dark state where the halogen lamp 49 after the light adaptation is turned off. At the same time, the response switch 8B is tilted according to the direction of the cut. That is, since the subject's eyes 4a and 4b after the light adaptation are gradually dark-adapted in a substantially dark state, the subject can view the first target illuminated by the target illumination light sources 22 and 24 at low illuminance. Observing and operating the response switches 8A and 8B at the point when the break of the Landolt ring can be identified. Thereby, the CPU 30 measures the elapsed time from the extinction of the halogen lamp 49 by the clock 33, displays the elapsed time on the display 31 of the operation panel 5, and calculates the night vision based on the predetermined characteristic curve from the elapsed time. taking measurement.
[0067]
Further, when measuring the moving body visual acuity, the first target plate 12 is positioned at the first rotation position, and the openings 51a and 51b are made into the incident openings 13a and 13b (that is, the eyepiece openings 3a and 3b). The eyepiece opening 3a is moved by moving the prism 26 as an optical distance and size variable means while illuminating the second targets 27a to 27d on the second target plate 27 with the target illumination light source 63. 3b and the second visual targets 27a to 27d and the apparent size of the visual targets are changed. As a result, it is possible to perform moving body visual acuity measurement for the eyes 4a and 4b to be examined looking into the eyepiece openings 3a and 3b.
[0068]
That is, when moving object visual acuity measurement is started, when the moving object visual acuity measurement switch 36 as an input unit is pressed and the moving object visual acuity measurement mode is selected as the second measurement mode, the CPU 30 as the second control unit By transmitting a predetermined signal (not shown), the actuator 40 is actuated to appropriately disengage the shutters 11a and 11b from the measurement optical path P. In synchronization with this, the first target plate rotation motor 17 is rotated by a predetermined angle in a predetermined direction, and the operation of the motor 17 causes the first target plate 12 to rotate to the first rotation position. Be moved. Thereby, the opening parts (bypass parts) 51a and 51b on the first target plate 12 are moved to positions facing the incident openings 13a and 13b of the reflection case 13, and from the eyepiece opening 3a or 3b side, The second visual targets 27 a to 27 d on the second visual target plate 27 are visible through the half mirror 18 or 19, the total reflection mirror 20, the correction lens 25, and the prism 26.
[0069]
In this state, when the visual acuity change switch 43 is pressed and a signal corresponding to a predetermined visual target is input, the CPU 30 transmits a predetermined signal to a power source (not shown), whereby the second measurement visual acuity presenting means. A certain second target plate rotation motor 28 operates to rotate the second target plate 27 by a predetermined angle in a predetermined direction (the direction of arrow G or H in FIG. 4). Thereby, the second visual targets 27a to 27d corresponding to the input visual targets appear in the eyepiece openings 3a and 3b, and are illuminated by the visual target illumination light source 63 that is turned on at a predetermined timing.
[0070]
That is, the illumination light from the target illumination light source 63 that illuminates the second targets 27a to 27d is reflected by the total reflection mirror 20 through the prism 26 and the correction lens 25, and then the half mirrors 18 and 19 are reflected. Then, the light enters the hollow members 13A and 13B through the incident openings 13a and 13b, and reaches the eyes 4a and 4b to be examined from the eyepiece openings 3a and 3b.
[0071]
When the CPU 30 transmits a predetermined signal, a prism moving motor (not shown) operates in response to this, and moves the prism 26 at a predetermined speed, for example, in the direction of the arrow D → E. At this time, the subject presses the response switch 8A at the point of time when the cut of the Landolt ring of the second target that appears to be approaching can be identified, and the response switch 8B is pressed according to the direction of the cut. Tilt operation. Thereby, a signal corresponding to the direction recognized by the subject is transmitted to the CPU 30. The CPU 30 determines whether the response is correct or not based on the signal, measures the elapsed time from the start of movement of the prism 26 by the clock 33, and calculates the position of the prism 26 from the elapsed time, thereby obtaining an apparent size. A moving object visual acuity value is calculated and used as a measurement result.
[0072]
Further, when measuring the static visual acuity, the first target plate 12 is rotated to the first rotation position to position the openings 51a and 51b on the measurement optical path P, and then the prism 26 is moved. Positioning control is performed, and the second target plate 27 is positioned in a predetermined direction (the arrow G in FIG. 4 or the arrow G in FIG. 4) in order to position the target corresponding to the input operation among the plural types of second targets 27a to 27d. In the state where the second visual targets 27a to 27d are illuminated by the visual target illumination light source 63, the static visual acuity measurement is performed on the eyes 4a and 4b to be examined.
[0073]
That is, when the static visual acuity measurement switch 35 as an input means is pressed at the start of the static visual acuity measurement and the static visual acuity measurement mode is selected as the second measurement mode, the CPU 30 as the second control means By transmitting a predetermined signal (not shown), the actuator 40 is actuated to appropriately disengage the shutters 11a and 11b from the measurement optical path P. In synchronization with this, the first target plate rotation motor 17 is rotated by a predetermined angle in a predetermined direction, and the operation of the motor 17 causes the first target plate 12 to rotate to the first rotation position. Be moved. As a result, as in the above-described moving object visual acuity measurement, the openings 51a and 51b move to positions facing the incident openings 13a and 13b, and the second targets 27a to 27d are visually recognized from the eyepiece opening 3a or 3b side. It will be ready.
[0074]
In the static visual acuity measurement, the visual acuity for the second visual targets 27a, 27b, 27c, and 27d on the second visual target plate 27 located at a specific optical distance is not measured, but an instruction from the operator is given. In response, the prism 26 is moved stepwise by a predetermined distance and stopped, thereby changing the optical distance and the apparent size of the second visual target stepwise to measure visual acuity.
[0075]
When the target switch 45 is pressed in a state where the second targets 27a to 27d are visible, and a signal corresponding to a predetermined target direction is input, the second target 27a to 27d is input in response to a predetermined signal from the CPU 30. The second target plate rotation motor 28 operates to rotate the second target plate 27 by a predetermined angle in a predetermined direction. Thereby, the second target corresponding to the target direction appears in the eyepiece openings 3a and 3b and is illuminated by the target illumination light source 63 that is lit at a predetermined timing.
[0076]
The subject observes the illuminated second targets 27a to 27d, presses the response switch 8A when the direction of the cut of the Landolt ring can be recognized, and responds according to the direction of the cut. The switch 8B is tilted. Thereby, when the signal according to the direction recognized by the subject is transmitted to the CPU 30 and the CPU 30 displays the correct answer on the display 31, for example, the visual acuity value is one step higher than the current target. The prism 26 is moved as described above, the optical distance and the apparent size are changed, the second visual target is presented to the subject, and the above-described measurement is repeated. On the other hand, when there is no response for a predetermined time or when the subject tilts the response switch 8B in the wrong direction, the CPU 30 displays a display indicating that the answer is incorrect, for example, from the current target. The prism 26 is moved so that the visual acuity value is lowered by one step, the optical distance and the apparent size are changed, the second visual target is presented to the subject, and the above-described measurement is repeated. Then, the CPU 30 displays the highest visual acuity value among the correct visual acuity values as the visual acuity of the subject on the display 31 and ends the static visual acuity measurement.
[0077]
As described above, according to the present embodiment, in addition to the dynamic visual acuity and the static visual acuity, other visual acuity such as normal visual acuity and night vision can be measured, but the first visual target plate 12 can be measured. The second target plate 27, the illumination light sources 22, 24, 63, the halogen lamp 49, the prism 26, and the like are used in appropriate combinations to reduce the number of parts as much as possible, simplify the device configuration, and increase the size of the device. It is possible to realize a visual acuity meter 1 that does not lead to an increase in size. In addition, the brightness adjusting means 39 can appropriately adjust the light amounts of the peripheral illumination light source 10a and the target illumination light sources 22, 24, 63, that is, the brightness, so that the first targets 12A to 12C,. It is possible to easily obtain an optimum state that prevents the subject from feeling uncomfortable due to the appearance of ˜12c.
[0078]
<Second Embodiment>
Next, a second embodiment according to the present invention will be described. As shown in FIG. 5, the present embodiment reduces the number of target illumination light sources 22 and 24 arranged behind the half mirrors 18 and 19 as compared to the first embodiment described above. However, since the other parts are the same, the same reference numerals are given to the main parts and the description thereof is omitted.
[0079]
That is, in the present embodiment, instead of the half mirror 18 in the first embodiment, the total reflection mirror 18A is arranged at the same position at the same angle, and the target illumination light sources 22, 24 in the first embodiment. Further, the diffusion plates 21 and 23 are eliminated, and the half mirror 20A is disposed at the same position and at the same angle in place of the total reflection mirror 20. Then, only one target illumination light source 53 is disposed on the back surface of the half mirror 20 </ b> A via the diffusion plate 52. The target illumination light source 53 is turned on based on the operation of the brightness adjustment switch 39, similarly to the peripheral illumination light source 10a, the target illumination light sources 22 and 24, and the target illumination light source 63 in the first embodiment. , And the brightness (brightness) of the illumination is adjusted.
[0080]
In the present embodiment having such a configuration, the illumination light of one target illumination light source 53 passes through the diffusion plate 52 and the half mirror 20A, passes through the half mirror 19, and further passes through the half mirror 19. Are respectively guided to the total reflection mirror 18A. Then, the illumination light guided to the total reflection mirror 18A and the half mirror 19 is reflected by 90 ° by the mirrors 18A and 19 respectively, enters the hollow members 13A and 13B, proceeds along the measurement optical path P, and proceeds to the eye to be examined. 4a, 4b will be reached.
[0081]
Therefore, according to the sight meter 1 of the present embodiment, it is unnecessary to mount at least the target illumination light sources 22 and 24 and the diffusion plates 21 and 23 in the first embodiment, and the back surface of the first target plate 12 is used. Can be realized by one target illumination light source 53 and a diffusion plate 52. Therefore, by turning on one target illumination light source 53, the illumination light transmitted through the half mirror 20A is directed along the measurement optical path P to the mirrors 18A and 19 and corresponds to the left and right sides of the eyes 4a and 4b to be examined. Since the first target can be efficiently illuminated with respect to the subject's eyes 4a and 4b after the light splitting as described above, the number of target illumination light sources 53 and the number of diffusion plates 52 corresponding thereto is one each, The number of parts can be further reduced, contributing to simplification of the device configuration. In this case, if a high-luminance LED is used for the target illumination light source 53, the illumination efficiency can be improved. Further, since the light intensity (that is, brightness) of the peripheral illumination light source 10a and the target illumination light source 53 can be appropriately adjusted by the brightness adjusting means 39, the first targets 12A to 12C..., 12a to 12c. It is possible to easily obtain an optimal state that prevents the subject from feeling uncomfortable due to the appearance of.
[0082]
<Third Embodiment>
Next, a third embodiment according to the present invention will be described. As shown in FIG. 6, this embodiment can measure contrast visual acuity (visual acuity when the contrast between the target and the background illumination is reduced) as compared to the first embodiment described above. However, since the other parts are the same, the same reference numerals are given to the main parts and the description thereof is omitted.
[0083]
    That is, in the present embodiment, in addition to the configuration of the first embodiment, the contrast visual acuity measuring unit 2d is provided between the reflecting case 13 and the first target plate 12 in a widened form. Intervene. The contrast visual acuity measurement unit 2d includes half mirrors 56 and 57 disposed at predetermined angles on the measurement optical path P between the hollow members 13A and 13B and the first target plate 12, respectively.Half mirror 56A contrast illumination light source 59 made of, for example, an LED disposed via a diffusion plate 58 so that light can be irradiated at a predetermined angle;Half mirror 57It is composed of a contrast illumination light source 61 made of, for example, an LED disposed via a diffusion plate 60 so that light can be irradiated at a predetermined angle. Therefore, the illumination by the contrast visual acuity measuring unit 2d is reflected by the half mirrors 56 and 57 via the diffusion plates 58 and 60, and the first visual target on the first visual target plate 12 is reflected from the incident apertures 13a and 13b side. Will be illuminated.
[0084]
Further, a contrast visual acuity switch 62 is connected to the CPU 30 via the interface 34. In the present embodiment, the brightness adjustment switch 39 has a function of adjusting the brightness (illumination light amount) of each of the peripheral illumination light source 10a and the target illumination light sources 22 and 24, and a contrast illumination light source (second viewing light source). It also has a function of adjusting the luminance of the mark illumination means) 59, 61.
[0085]
Therefore, in the sight meter 1 in the present embodiment, when the contrast visual acuity measurement is started, the contrast visual acuity switch 62 is first pressed. Then, when the CPU 30 transmits a predetermined signal, the target illumination light sources 22 and 24 and the peripheral illumination light source 10a are turned on, and the luminance within the viewing angle centered on the target to be observed is substantially uniform. Illuminated.
[0086]
When the contrast illumination light sources 59 and 61 are turned on in response to a predetermined signal from the CPU 30, the illumination by the illumination light sources 59 and 61 is measured by reflection of the half mirrors 56 and 57 via the diffusion plates 58 and 60. Overlapping with illumination by the target illumination light sources 22 and 24 on the optical path P, any of the first targets 12A to 12C, 12a to 12c... The contrast between the mark and the background illumination is reduced.
[0087]
In this way, the contrast illumination light sources 59 and 61 illuminate the first targets 12A to 12C..., 12a to 12c from the front side with variable brightness, so that when the contrast visual acuity is measured, A better measurement result can be obtained by appropriately changing the contrast with the background illumination. Since the target illumination light sources 22 and 24 (target illumination light source 53 in the second embodiment) and the target illumination light sources 59 and 61 are provided with the brightness adjusting means 39 that can variably adjust the brightness. When measuring contrast visual acuity, the brightness adjusting means 39 can appropriately adjust the brightness of each of the target illumination light sources 22 and 24 and the contrast illumination light sources 59 and 61. Therefore, the optimum state at the time of contrast visual acuity measurement can be easily achieved. Can be obtained.
[0088]
In the present embodiment, the half mirrors 56 and 57 are configured to be always positioned in the measurement optical path P. However, the present invention is not limited to this. For example, the half mirrors 56 and 57 disposed in the measurement optical path P are not used. It can be configured to be bounced up and retracted from the measurement optical path P, or can be arranged outside the measurement optical path P at all times and inserted into the measurement optical path P only during use.
[0089]
In the first to third embodiments described above, manual visual acuity measurement has been described. However, the present invention is not limited to this, and the present invention can be applied to, for example, automatic measurement and semi-automatic measurement. It is. Further, in each of the above-described embodiments, the visual acuity measurement in which the optical distance is 5 [m] is described as an example of the normal visual acuity. However, the present invention is not limited to this, and a combination of the lenses 15a and 15c and the lenses 15b and 15d is appropriately selected. The visual acuity can be measured in a state where the optical distance is shorter than 5 [m] by selecting and adjusting.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of a sight meter to which the present invention is applied, in which (a) is a front view and (b) is a side view.
2 is a diagram showing the configuration of the first embodiment of the sight meter according to the present invention, (a) is a block diagram schematically showing the configuration of the sight meter, and (b) is FIG. It is a schematic plan view shown in the state seen in the AA arrow direction in (a).
FIG. 3 is a front view showing a first target plate.
FIG. 4 is a front view showing a second target plate.
FIGS. 5A and 5B are diagrams showing a configuration of a visual acuity meter according to a second embodiment of the present invention, in which FIG. 5A is a block diagram schematically showing the configuration of the visual acuity meter, and FIG. It is a schematic plan view shown in the state seen in the BB arrow direction in (a).
6 is a diagram showing a configuration of a third embodiment of a visual acuity meter according to the present invention, (a) is a block diagram schematically showing the configuration of the visual acuity meter, and (b) is a block diagram of FIG. It is a schematic plan view shown in the state seen in CC arrow direction in (a).
[Explanation of symbols]
1 …… Sight meter
3 ... Eyepiece
3a, 3b ... Eyepiece opening
4a, 4b ... Eye to be examined
10a ...... Ambient illumination means (ambient illumination light source)
12 …… First target plate
12A to 12C, 12a to 12c ....... first target
13 …… Reflection case
13a, 13b: Entrance aperture
17 …… First measurement visual acuity presenting means (first target plate rotation motor)
18, 19 ... Light splitting means (half mirror)
20 ... Total reflection mirror
20A …… Half mirror
22, 24, 53... First target illumination means (target illumination light source)
26 …… Optical distance and size variable means (prism)
27 …… Second target plate
27a-27d ... second target
28 …… Second measurement visual acuity presenting means (second target plate rotation motor)
30... First control means, second control means (CPU)
35 …… Input means (stationary visual acuity measurement switch)
36 …… Input means (moving visual acuity measurement switch)
37 …… Input means (normal vision measurement switch)
38 …… Input means (night vision measurement switch)
39: Brightness adjusting means, adjusting means (luminance adjusting means)
49 …… Halogen lamp
50a, 50b ...... First target (light order applied target)
51a, 51b ...... Bypass part (opening part)
52 …… Diffusion plate
59, 61 ... Second illumination means for target (contrast illumination light source)
63 …… Light source for target
64 …… Brightness adjustment means
P …… Measurement optical path
R1-R_N……Range of movement

Claims (6)

The first and second optotype plates are arranged on the measurement optical path to the eyepiece opening corresponding to the eye to be examined so that the first and second optotypes can be selectively presented from a plurality of types. Are arranged sequentially from the eyepiece opening side, and the first target plate is provided with a bypass part that opens the measurement optical path between the eyepiece opening and the second target plate,
An input means is provided for selecting the first and second measurement modes,
Providing a first measurement visual acuity presenting means capable of moving and driving the first visual target plate to present a predetermined visual target on the measurement optical path;
Providing a second measurement visual acuity presenting means capable of moving and driving the second visual target plate to present a predetermined visual target on the measurement optical path;
When the first measurement mode is selected by the input unit, the first target plate is moved and driven by the first measurement visual acuity presentation unit to measure the predetermined first target. Providing a first control means for controlling to be presented on the optical path;
When the second measurement mode is selected by the input means, the first target plate is moved to position the bypass portion on the measurement optical path, and the second measurement visual acuity presentation means The second target plate is moved and driven so as to control the second target to be presented on the measurement optical path .
Optical between the eyepiece opening and the second target plate by moving along the measurement optical path on the measurement optical path between the first target plate and the second target plate A visual acuity meter comprising: an optical distance and size variable means capable of changing a distance and an apparent size of the second visual target observed on the eyepiece opening side . It is arranged on the measurement optical path between the first target plate and the optical distance and size variable means, and the light passing through the optical distance and size variable means corresponds to the left and right eye to be examined. The sight meter according to claim 1 , further comprising a light splitting unit capable of splitting. On the measurement optical path between the first target illumination means that can illuminate the first target presented on the measurement optical path from the back, and the light splitting means and the optical distance and size variable means. A half mirror disposed at a predetermined angle to
3. The sight meter according to claim 2 , wherein the first visual target illumination unit includes a single light source disposed on a back surface of the half mirror. Providing a peripheral illumination means capable of illuminating the periphery of the first visual target presented on the measurement optical path;
The sight meter according to claim 1, further comprising brightness adjusting means for the ambient lighting means.     Second target illumination means that is disposed on the eyepiece opening side of the first target plate and that can illuminate the first target presented on the measurement optical path from the eyepiece opening side and the measurement light The sight meter according to claim 1, wherein the sight meter is configured by providing a first target illumination unit capable of illuminating the first target presented on the road from the back. 6. A visual acuity meter according to claim 5 , further comprising brightness adjusting means capable of variably adjusting the brightness of the first visual target illumination means or the second visual target illumination means.

Images