JP3639951B2 - Short distance vision test tool - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a short-distance vision test tool suitable for examining the visual acuity of various subjects such as myopia, hyperopia, presbyopia, amblyopia, and cataract patients.
[0002]
[Prior art]
As a short-distance visual acuity test, the subject himself / herself has a short-distance visual acuity table, positions the short-distance visual acuity table at a distance of 30 cm or 50 cm from the subject's eye, and the Landolt with different sizes printed on the visual acuity table A visual acuity test is performed to determine visual acuity based on whether or not a subject can visually recognize a target such as a ring.
[0003]
The visual acuity table used for this type of short-distance visual acuity has conventionally been printed with a Landolt ring with a diameter of 0.75 mm (in the case of an inspection distance of 50 cm) as a standard visual acuity of 1.0. A target with a visual acuity of 1.2, 1.5,..., Which gradually decreases in diameter, is printed, and a visual acuity of 0.9, 0.8,. The target is printed.
[0004]
[Problems to be solved by the invention]
The short-distance vision test is an examination in which the subject himself / herself holds the short-distance vision table in his / her hand while looking at the target. The distance from the subject to the target is 30 cm or 50 cm. Maintaining a predetermined distance is important for performing an accurate visual examination. However, since the subject himself examines while holding the short-distance vision chart in his hand and looking at the chart on the chart of vision, the subject gradually loses his or her visual acuity when the target becomes difficult to see during the examination. There is a problem in that it becomes difficult to perform an accurate visual acuity test by moving the table closer to or away from the eye and the inspection distance deviating from the set value.
[0005]
The present invention has been made in view of the above points, and a short-distance vision test that can perform an accurate visual acuity test while maintaining a predetermined distance between the eye of the subject and the visual acuity table. Aim to provide ingredients.
[0006]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, the short-distance vision test tool of the present invention holds the test tool in the hand and keeps the short-distance vision table away from the subject's eyes by a predetermined short distance. This is a short-distance vision tester that presents and examines the visual acuity of the subject based on whether or not the subject can visually recognize the visual target of the short-distance visual acuity table, and can be opened and closed left and right via a central vertical folding line A short distance vision chart is affixed to the inside of the door cover, and an inspection distance confirmation string for confirming the examination distance from the short distance vision chart to the subject's eyes is attached to the inside of the door cover . A holding loop is attached to the tip of the inspection distance confirmation string-like body, and a second loop is attached at a predetermined distance from the tip of the inspection distance confirmation string-like body .
A solid visual target is attached to the surface. [0007]
Here, in the above test distance confirmation string-like body may be formed as a tape measure denoted by the scale indicating the distance to the surface of the cord. Furthermore, the short-distance optotypes can be formed by exposure and development a plurality of optotypes on a positive film for photographic. The visual target can be formed by exposure and development with different optical densities.
[0008]
[Action]
Such a short-distance visual acuity test tool is used when a visual acuity test is performed on a subject such as myopia, hyperopia, presbyopia, amblyopia, and cataract at a short distance such as 30 cm or 50 cm. The near distance vision chart is attached to the inside of the door cover that can be opened and closed to the left and right via the center vertical folding line. When inspecting, the subject opens the door cover with his / her own inspection tool. Hold the tip of the test distance confirmation string attached to the inside of the subject and pull the test distance confirmation string to match the position of the subject's eyes. Is set to a predetermined short distance.
[0009]
Thereafter, the examiner asks the subject about the opening direction of, for example, the Landolt ring target on the visual acuity table, and measures the short distance visual acuity based on the answer. If the distance between the subject's eyes and the short-distance vision table changes due to the subject approaching or moving away from the examination tool during the examination, the examination distance confirmation string is extended and the subject is examined. The position of the inspection tool is adjusted so that the distance between the person's eye and the short-distance vision table is the correct distance.
[0010]
In this way, the near distance vision chart is attached to the inside of the door cover, and an inspection distance confirmation string for indicating the examination distance from the near distance vision chart to the subject is attached to the inside of the door cover. Therefore, the distance to the short-distance vision chart can be easily set correctly, and the inspection distance can be easily confirmed and adjusted correctly during the inspection.
[0011]
By the way, in such a short-distance visual acuity test tool, since the visual acuity value is determined based on the contrast of the visual target, it is important that the visual target attached to the visual acuity table has a predetermined optical density. . For example, when a visual target is formed by normal printing, a visual target having a contrast of 1 with respect to the background can be printed relatively easily using a thick black ink, but a visual image with a low contrast (optical density) is displayed. When a mark is formed by printing, it is necessary to finely prepare printing ink in order to obtain a predetermined optical density, and it is difficult to accurately create a target with a predetermined optical density and contrast. It is difficult to stably print such a target.
[0012]
Furthermore, there is a method of printing a target as a set of dots and adjusting the optical density of the target based on the number of dots per unit area, as in a printer using a computer. When printing is performed, jaggedness and blurring occur at the edge portion, and it becomes impossible to form a precise target.
[0013]
On the other hand, the short-distance visual acuity test tool of the present invention uses a positive film for photography as a visual acuity table, and forms a plurality of targets having different optical densities on the positive film by exposing and developing a target image. Thus, the optical density of the visual target can be easily adjusted by the exposure time of the visual target image. Further, for example, a positive film of photographic material has a diffusion RMS granularity of 8 and its resolution is 63 lines / mm when the resolution is low, and 125 lines / mm when the resolution is high. be able to. Therefore, it is possible to satisfactorily form an accurate visual target having a precise edge without jaggedness and blur.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a perspective view of a short-distance vision test tool, and FIG. 2 shows an exploded view thereof.
[0015]
This short-distance visual acuity test tool is configured by sticking a short-distance visual acuity table 1 inside a door cover 7 that can be opened and closed left and right through a central vertical folding line. A visual target 4 is formed on the film 2 by exposure and development, and a back sheet 3 is attached to the back surface of the positive film 2.
[0016]
Using this positive film, the short distance vision table 1 is manufactured as follows. First, in the target data creation step, target data is created. This target data creation process is performed by a device having a computer having a program for creating an image, for example, a digital image recorder. On the computer screen of the digital image recorder, the Landolt data having a predetermined shape and different sizes in order. Each index 4 of the ring is created. The background of the screen is created in white and the target 4 is created in black. Since the visual target is created on the computer screen, its optical density (contrast) can be arbitrarily and easily adjusted. Each target 4 is composed of Landolt ring targets having different sizes, and the positions of the cuts are different.
[0017]
Next, in the exposure process, the image of the target created on the computer screen of the digital image recorder, that is, the image of the target displayed on a display such as a CRT is optically exposed on the negative film. . This exposure process can be performed with a digital image recorder. For example, for a target image created on a computer screen, the CRT electron beam forming the screen is optically expanded and exposed on a negative film. Do. Alternatively, a target image created on a computer screen is exposed on a negative film in dot units. When the target image is exposed on the negative film in such dot units, the target image can be exposed on the negative film with a very high resolution of, for example, 1500 dpi to 3000 dpi.
[0018]
The optical density (contrast) of the target formed on the negative film can be set to any optical density at the stage of creating the target image on the computer screen. When the exposure is performed, the optical density of the visual target can be adjusted by adjusting the exposure time. In addition, as the negative film used here, a black and white negative film having a panchromatic color sensitivity in which a red photosensitive area is extended to the long wavelength side can be used.
[0019]
Next, the negative film development process is entered, and the negative film exposed with the target image as described above is immersed in a predetermined developer for a predetermined time and developed. Note that the optical density (contrast with the background) of the visual target can also be adjusted by adjusting the development processing time.
[0020]
Next, the positive film is created from the negative film which has been developed in the development process. This positive film production process involves, for example, irradiating light through the negative film, which has been exposed and developed as described above, and transmitted through the negative film. An image of the visual target on the film can be formed on the positive film, and the positive film can be exposed. As the positive film, a polyester acetate base can be used, and a black and white film coated and formed on an extremely fine grain emulsion can be used.
[0021]
Then, the positive film is developed, and the positive film exposed with the image of the target 4 as described above is immersed in a predetermined developer for a predetermined time to be developed. Similarly to the above, the optical density (contrast with respect to the background) of the visual target can also be adjusted by adjusting the development processing time.
[0022]
A white back sheet 3 is attached to the back surface of the positive film 2 on which the visual target 4 as described above is formed, and the short distance vision table 1 is formed. White paper or white plastic sheet can be used for the back sheet 3. Then, as shown in FIG. 2, the short distance vision table 1 is attached to the inside of the door cover 7. The door cover 7 is formed as a cover that cuts cardboard or the like into a rectangle, puts a vertical folding line at the center thereof, and can be opened and closed to the left and right via the vertical folding line. The short distance visual acuity table 1 is attached to the inside of the door cover 7, and a rectangular and frame-like cover frame 9 is attached from above, and the peripheral portion of the short distance visual acuity table 1 is covered.
[0023]
At this time, a hole is formed in the upper portion of the cover frame 9, and the inspection distance confirmation string-like body 8 is inserted into the hole, and the base portion of the inspection distance confirmation string-like body 8 is the door cover 7 and the cover frame 9. Glued between. The inspection distance confirmation string-like body 8 is set so that the length to the tip thereof is a predetermined distance of, for example, 30 cm or 50 cm in a pulled state. Further, a loop 8a is provided at the tip so that it can be easily hooked and held by the tip of an examiner's finger or a support rod.
[0024]
Such a short-distance visual acuity test tool is used when performing visual acuity tests at short distances of 30 to 50 cm on subjects such as myopia, hyperopia, presbyopia, amblyopia, and cataract patients.
[0025]
As shown in FIG. 4, this short distance visual acuity test tool has the short distance visual acuity table 1 attached to the inside of a door cover 7 that can be opened and closed to the left and right via a central vertical folding line. The subject opens the door cover 7 and the examiner holds the tip of the inspection distance confirmation string-like body 8 attached to the inside of the door cover 7 and pulls the string-like body 8. The distance between the eye of the subject and the visual acuity table 1 is set to a predetermined (30 cm or 50 cm) short distance in accordance with the position of the eye.
[0026]
At this time, since the loop 8a is provided at the tip of the inspection distance confirmation string-like body 8, the inspector hangs the loop 8a on the tip of a holding rod, a writing instrument or the like to place the string-like body 8 on the subject's eye. The distance between the eye chart 1 and the eyes can be set to a predetermined distance without touching the periphery of the subject's eyes.
[0027]
In this state, the examiner asks the subject about the opening direction of the Landolt ring target on the visual acuity table 1 and measures short-distance visual acuity based on the answer. In such a short-distance visual acuity test, the subject himself / herself holds the short-distance visual acuity table in his / her hand and inspects while looking at the visual target in the visual acuity table. The inspection distance may gradually deviate from the set value by gradually moving the visual acuity table closer to or away from the eye. In this case, the inspector again checks the string 8 for checking the inspection distance. While holding the tip and pulling the string-like body 8, the eye distance can be returned to an accurate position from the visual acuity table according to the eye position of the subject, and an accurate visual acuity test can be performed.
[0028]
5 to 7 show a short-distance vision test device according to another embodiment. This short-distance visual acuity test tool is configured by sticking a short-distance visual acuity table 11 on the inner side of a door cover 7 that can be opened and closed to the left and right via a central vertical folding line. As shown in FIG. 7, three types of targets 14, 15, 16 having different contrasts are formed on a photographic positive film 12 by exposure and development, and a back sheet 3 is attached to the back surface of the positive film 12. Is done.
[0029]
The three types of visual targets 14, 15, and 16 are each composed of a plurality of sizes of Landolt's circular visual targets, and are formed with different positions (opening directions) of the cuts. Further, the three types of visual targets 14, 15, and 16 are created with different optical densities, and the contrast of each visual target with respect to the background is 1 (100%) for the visual target 14 and 1/4 for the visual target 15. The target 16 is set to 1/16 (about 6%) at (25%).
[0030]
The contrast C with respect to the background of the target is accurately determined by measuring the brightness of the target and the background, where the target brightness is L and the background brightness L ₀ is C = (L ₀ −L) / (L ₀ + L). Contrast 1 (100%) is a case where the luminance L of the target is zero and the luminance L ₀ of the background is a predetermined value, but it is practically difficult to make the luminance L of the target zero. Therefore, the numerical value is given a certain range, and the contrast of 1 to 0.9 (100% to 90%) of the actually measured value is regarded as the contrast 1 (100%).
[0031]
Using this positive film, the short distance vision table 1 is manufactured as follows. First, in the target data creation step, target data is created. This target data creation process is performed by a device having a computer having a program for creating an image, for example, a digital image recorder. On the computer screen of the digital image recorder, the Landolt data having a predetermined shape and different sizes in order. Each index 14, 15, 16 of the ring is created. The background of the screen is created in white, the target 14 is black, the target 15 is dark gray, and the target 16 is light gray. Since the visual target is created on the computer screen, its optical density (contrast) can be arbitrarily and easily adjusted.
[0032]
For example, the black visual target 14 is adjusted to a contrast of 1 to 0.9 (100% to 90%), and the dark gray visual target 15 is adjusted to a contrast of 1/4 (25%) to obtain a bright gray visual target. The standard 16 is adjusted to a contrast of 1/16 (about 6%). As described above, the contrast C is the contrast between the target and the background. When the brightness of the target and the background is measured and the target brightness is L and the background brightness L ₀ , C = (L ₀ − L) / (L ₀ + L). Each of the visual targets 14 to 6 is a Landolt visual target having different sizes, and the positions of the cuts are different.
[0033]
Next, in the exposure process, the image of the target created on the computer screen of the digital image recorder, that is, the image of the target displayed on a display such as a CRT is optically exposed on the negative film. . This exposure process can be performed with a digital image recorder. For example, for a target image created on a computer screen, the CRT electron beam forming the screen is optically expanded and exposed on a negative film. Do. Alternatively, a target image created on a computer screen is exposed on a negative film in dot units. When the target image is exposed on the negative film in such dot units, the target image can be exposed on the negative film with a very high resolution of, for example, 1500 dpi to 3000 dpi.
[0034]
The optical density (contrast) of the target formed on the negative film can be set to any optical density at the stage of creating the target image on the computer screen. When the exposure is performed, the optical density of the visual target can be adjusted by adjusting the exposure time. In addition, as the negative film used here, a black and white negative film having a panchromatic color sensitivity in which a red photosensitive area is extended to the long wavelength side can be used.
[0035]
Next, the negative film development process is entered, and the negative film exposed with the target image as described above is immersed in a predetermined developer for a predetermined time and developed. Note that the optical density (contrast with the background) of the visual target can also be adjusted by adjusting the development processing time.
[0036]
Next, the positive film is created from the negative film which has been developed in the development process. This positive film production process involves, for example, irradiating light through the negative film, which has been exposed and developed as described above, and transmitted through the negative film. An image of the visual target on the film can be formed on the positive film, and the positive film can be exposed. As the positive film, a polyester acetate base can be used, and a black and white film coated and formed on an extremely fine grain emulsion can be used. When the image is exposed on the positive film, the optical density (contrast) of the target can be adjusted by adjusting the exposure amount or the exposure time.
[0037]
Then, the positive film development process is started, and the positive film exposed with the images of the targets 14 to 16 as described above is immersed in a predetermined developer for a predetermined time and developed. Similarly to the above, the optical density (contrast with respect to the background) of the visual target can also be adjusted by adjusting the development processing time.
[0038]
On the positive film 12 developed in this way, as shown in FIG. 7, three types of visual targets having different optical sizes (contrast with the background), that is, contrast 1 to 0. 9 (100% to 90%) visual target 14, contrast 1/4 (25%) visual target 15 and contrast 1/16 (about 6%) visual target 16 are formed. Actually, the visual target 14 having a contrast of 1 to 0.9 (100% to 90%) can be formed relatively easily if an image having the highest optical density is formed.
[0039]
On the other hand, for the target 15 having a contrast of 1/4 (25%) and the target 16 having a contrast of 1/16 (about 6%), the prototype of the prototype is measured, the contrast is measured, and the density of the target image based on the prototype is measured. By adjusting this, it can be formed relatively easily.
[0040]
That is, first, on the computer screen of the digital image recorder, a plurality of prototype targets having different optical densities (contrasts) are created in stages, and these prototype targets are exposed for 20 seconds at 10 Lux, for example. Then, the contrast of the prototype target of the positive film created by developing it is measured using a luminance meter. Then, based on the measurement results, a prototype target that is close to the contrast to be obtained is selected on the computer screen of the digital image recorder, and the optical density (contrast) of the image of the prototype target is further finely adjusted. Thus, the target 15 with a contrast of 1/4 (25%) and the target 16 with a contrast of 1/16 (about 6%) can be set relatively easily and accurately. In addition, the target numbers 1-13 are attached to the side of each size target 14, 15, 16 so that it is convenient when the target is specified at the time of inspection.
[0041]
The white back sheet 3 is affixed to the back surface of the positive film 12 with the visual targets 14 to 16 as described above to form the short distance vision table 11. White paper or white plastic sheet can be used for the back sheet 3. Then, as shown in FIG. 6, the short distance vision table 11 is attached to the inside of the door cover 7. Similarly to the above, the door cover 7 is formed as a cover that cuts thick paper or the like into a rectangle, puts a vertical folding line at the center thereof, and can be opened and closed left and right through the vertical folding line. The near distance vision table 11 is attached to the inside of the door cover 7, and a rectangular frame-like cover frame 9 is attached from above, and the peripheral portion of the near distance vision table 11 is covered.
[0042]
At this time, in the same manner as described above, a hole is formed in the upper portion of the cover frame 9 and the inspection distance confirmation string-like body 8 is inserted into the hole, and the base portion of the inspection distance confirmation string-like body 8 is the door cover. 7 and the cover frame 9. The inspection distance confirmation string-like body 8 is set so that the length to the tip thereof is a predetermined distance of, for example, 30 cm or 50 cm in a pulled state. Further, a loop 8a is provided at the tip so that it can be easily hooked and held by the tip of an examiner's finger or a support rod.
[0043]
Such a short-distance visual acuity test tool is used when a visual acuity test is performed at a short distance of 30 cm or 50 cm on subjects such as patients with amblyopia and cataract. Since the near distance vision table 11 is attached to the inside of the door cover that can be opened and closed to the left and right via the center vertical folding line, when inspecting, open the door cover 7 of the inspection tool on a desk or the like, While holding the tip of the test distance confirmation string 8 attached to the inside and pulling the test distance confirmation string 8, the eye of the patient and the visual acuity table are aligned with the position of the subject's eyes. 11 is set to a predetermined short distance (30 cm or 50 cm).
[0044]
At this time, since the loop 8a is provided at the tip of the inspection distance confirmation string-like body 8, the inspector hangs the loop 8a on the tip of a holding rod, a writing instrument or the like to place the string-like body 8 on the subject's eye. The distance between the eye chart 1 and the eyes can be set to a predetermined distance without touching the periphery of the subject's eyes. In this state, the examiner asks the subject about the opening direction of the Landolt ring target on the visual acuity table 11 and measures the short distance visual acuity based on the answer.
[0045]
As described above, the near distance vision table 11 is attached to the inside of the door cover 7, and an inspection distance confirmation string for indicating the examination distance from the near distance vision table 11 to the subject is disposed on the inside of the door cover 7. Since the object 8 is attached, the inspector can easily set the distance to the short distance vision table 11 correctly and inspect.
[0046]
In addition to the target having a high optical density and high contrast, the target on the short distance vision table 11 is a target having a medium optical density and a medium contrast, and a target having a low optical density and a low contrast. Presenting a low target and performing a visual acuity test based on whether or not the target is visible, and determining the visual acuity value based on the size of the target and the contrast with the background as a reference. The visual acuity test can be accurately performed.
[0047]
In the above embodiment, the Landolt ring target is used as the target, but other character targets and the like can also be used. In addition, as a method of displaying the target, a decimal system, a fraction system, or a LogMAR system can be used.
[0048]
Further, as shown in FIG. 8, the second loop 18b can be provided at a position a predetermined distance from the tip of the inspection distance confirmation string-like member 18 provided with the loop 18a at the tip. In this case, if the length to the loop 18a is 50 cm, the second loop 18b is provided at a location of 30 cm, for example, from the visual acuity table 1, so that it can be used even at an inspection distance of 30 cm.
[0049]
【The invention's effect】
As explained above, according to the near distance visual acuity test tool of the present invention, the near distance vision table is attached to the inside of the door cover that can be opened and closed to the left and right via the central vertical folding line, Since a string for checking the inspection distance is attached to indicate the inspection distance from the short distance vision table to the subject, the examiner or the subject can easily set the distance to the short distance vision table correctly. Can be inspected. In addition, since a loop is provided at the tip of the string for checking the inspection distance, the inspector extends the string to the position of the eye of the subject by hanging the loop on the tip of a holding rod or writing instrument, The distance between the eye chart and the eyes can be set to a predetermined distance without directly touching the periphery of the subject's eyes.
[Brief description of the drawings]
FIG. 1 is a front perspective view of a short-distance visual acuity test tool showing an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the short-distance vision test tool.
FIG. 3 is a front view of a short-distance visual acuity table 1;
FIG. 4 is an explanatory diagram showing a usage state of the short-distance vision test tool.
FIG. 5 is a front perspective view of a short-distance visual acuity test tool showing another embodiment.
FIG. 6 is an exploded perspective view of the short-distance vision test tool.
FIG. 7 is a front view of a short-distance vision table 11 of the inspection tool.
FIG. 8 is a front perspective view of a short-distance vision test device of another embodiment.
[Explanation of symbols]
1-short distance vision table 2-positive film 3-back sheets 4, 5, 6-target 7-door cover 8-inspection distance confirmation string 8a-loop

Claims (4)

The subject holds the examination tool in his / her hand and presents a short-distance vision table away from the subject's eyes by a predetermined short distance, and the subject visually recognizes the target in the short-distance vision table A short-distance visual acuity test tool that examines the visual acuity of the subject based on whether or not it is possible,
The near distance visual acuity table is affixed to the inside of the door cover that can be opened and closed to the left and right via a central vertical folding line, and the inspection distance from the near distance visual acuity table to the subject's eyes is confirmed inside the door cover And a holding loop is attached to the tip of the inspection distance confirmation string, and a position at a predetermined distance from the tip of the inspection distance confirmation string. A short-distance visual acuity test tool characterized by having a second loop attached thereto.   The near distance visual acuity inspection tool according to claim 1, wherein a scale for indicating a distance from the short distance visual acuity table is attached to the string for checking the inspection distance.   2. The short-distance visual acuity test tool according to claim 1, wherein the short-distance visual acuity table is formed by exposing and developing a plurality of visual targets on a photographic positive film.   2. The short-distance visual acuity test tool according to claim 1, wherein the short-distance visual acuity table is formed by exposing and developing a plurality of visual targets having different optical densities on a photographic positive film.

Images