JP3611680B2 - Optometry equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optometry apparatus suitable for refractive correction of an eye to be examined.
[0002]
[Prior art]
When there is a refractive error in the subject's eye and correct this, after examining the refractive state of the subject's eye accurately, taking into account the patient's complaints and the degree of the front glasses, the degree of wearing is not uncomfortable and tired It is important to prescribe.
When the prescription power is determined, a complete correction refracting power test is usually performed based on test data such as an objective test using a so-called refractometer and an anterior spectacle power measurement using a lens meter. The complete correction power test uses a subjective power measurement device that switches various optical characteristics to the test window, and obtains a response to the visual appearance of the displayed target from the subject. Find the frequency at which. When the complete correction power is obtained by the complete correction refractive power test, the prescription value is obtained by adjusting the power based on this power.
[0003]
[Problems to be solved by the invention]
However, the procedure for obtaining an appropriate prescription value after adjusting the frequency after obtaining the complete correction frequency largely depends on the knowledge and experience of the examiner and is not easy for an inexperienced person.
In addition, it takes a considerable amount of time to obtain the prescription value by adjusting the frequency, and there is a problem that the obtained prescription value varies depending on the examiner.
In view of the above problems, an object of the present invention is to provide an optometry apparatus that can easily obtain an appropriate prescription value even for a person who has little experience and is unfamiliar with optometry.
[0004]
[Means for Solving the Problems]
In order to solve the above problems, the present invention is characterized by having the following configuration.
(1)Of the measured eyeBased on refractive powerOf the eye to be examinedIn the optometry device for obtaining refractive power,Subject's obtained by binocular balance adjustmentBinocular perfect correction valueAdjustment factor information for predicting the optimal prescription frequency for the subject by making adjustments to the subject, including eyewear dataAn input means for inputting adjustment factor information;Prescription power prediction means for calculating the first prescription power by correcting the binocular perfect correction value based on the binocular complete correction value and the adjustment factor information, and an optical element having a refractive power corresponding to the calculated first prescription power Is arranged in the optometry window in front of the subject's eye, and the first prescription power is further adjusted based on the response result of the subject regarding the appearance, and the second prescription power with the appearance satisfying the subject is obtained. Means,It is characterized by providing.
[0005]
(2)The prescription power prediction means of (1) has at least two types of information relating to the adaptability to the correction power change of the eye to be examined as the adjustment factor information.Features.
[0006]
(3) (1)The prescription power predicting means has different correction procedures based on whether astigmatism, presence or absence of oblique astigmatism, hyperopia or myopia in the obtained perfect correction power.Features.
[0022]
【Example】
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an external view showing an overall configuration of an optometry apparatus according to an embodiment.
Reference numeral 1 denotes an optometry table arranged between the subject and the examiner, and 2 denotes a subjective refracting power measuring apparatus 2. The subjective refracting power measurement apparatus 2 includes a pair of left and right lens units 10 that electrically switch various optical elements to the optometry window 11 and a suspension unit 12 that suspends the left and right lens units 10. The hanging part 12 has a slide mechanism for correcting the distance between the left and right lens units 10 and a turning mechanism (described later) for making the optical axis of the optical system parallel to the visual axis for near vision of the subject. Reference numeral 13 denotes a near vision chart held by a near-point rod attached to the hanging portion 12 (removed from the front of the eye during a distance examination).
Reference numeral 3 denotes an objective eye refracting power measurement device that measures eye refractive power based on projecting a measurement index onto the fundus of the eye to be examined and detecting a projected index image of the fundus with a light receiving means. The objective eye refractive power measurement device 3 has a function of obtaining the interpupillary distance based on the movement amount when the measurement unit having the measurement optical system is moved from the alignment completion state of one eye to the alignment completion state of the other eye. It has. The objective eye refracting power measuring device 3 is mounted on a movable tray that can slide on the optometry table 1, and is slid to the center position of the optometry table 1 at the time of objective test. .
Reference numeral 4 denotes a projection-type target presentation device that presents an inspection target. Reference numeral 5 denotes a controller for operating the subjective refracting power measuring device 2 and the projected visual target presentation device 4, and 6 is a relay unit that relays communication between the devices. A lens meter is connected to the relay unit 6.
[0023]
FIG. 2 is a diagram for explaining the slide mechanism and the turning mechanism of the lens unit 10. A shaft 201 is fixed to a suspension plate 200 that suspends the lens unit 10, and the shaft 201 is inserted into a hole 202 a of a slide table 202, and is rotatable for tilting operation. The slide table 202 is slidable in the axial direction of the fixed guide 203, and the drive motor 204 for sliding is fixed to a fixed bracket (not shown) together with the fixed guide 203. Screws 205 and 206 having different directions are connected to the drive motor 204 and are engaged with the female screws of the slide table 202. Therefore, by rotating the drive motor 204, the two slide tables are rotated. 202 move in opposite directions. Thereby, the distance between the left and right lens units 10 can be adjusted, and the distance between the optical axes of the optical system arranged in the optometry window 11 can be adjusted to the distance between the pupils of the subject.
[0024]
Reference numeral 207 denotes a driving motor for turning, and worms 208 and 209 having different twisting directions are fixed to the rotating shaft. Wheels 210 and 211 that mesh with these worms are fixed with rotatable shafts 212 and 213, and eccentric shafts 214 and 215 and bearings 216 and 217 are arranged at the lower ends thereof. Are engaged with grooves 218, 219. For this reason, the left and right lens units 10 are turned in opposite directions through the suspension plate 200 by the rotation of the drive motor 207.
[0025]
FIG. 3 is a view of the controller 5 as seen from above.
A liquid crystal display 30 displays optometry information. A switch unit 31 has the following switches. Reference numeral 32 denotes a group of setting changeover switches, which have switches used when setting the parameters and the like by switching the display screen of the display 30 to the menu screen. 33 is a target switch group for switching the target to be presented to the target presentation apparatus 4, 34 is a mask switch group for applying a mask necessary for the presented target, 35 is a start switch for executing a program optometry, and 36 is a program optometry. Switch for advancing the next inspection to the next, 37 is a change mode designating switch group for designating the mode of the measurement data to be changed, etc. 38 is a mode or measurement for inputting the data An input data designating switch group 39 for designating a mode to be used, 39 is a data input switch used for inputting data from an objective eye refractive power measuring device or lens meter, 40 is a A print switch 41 is a measurement eye designation switch, and 42 is a dial switch used for changing a measurement value or inputting a numerical value.
[0026]
Reference numerals 43a and 43b are changeover switches for switching the cross cylinder, which are also used for adjusting the appearance at the prescription stage. Reference numeral 44 denotes a shift switch, and a switch function is added by pressing another switch while pressing this switch. Reference numeral 45 denotes a function switch group, which is used when selecting a switch corresponding to various switch displays displayed at a predetermined position below the screen of the display 30.
[0027]
FIG. 4 is a block diagram for explaining the control of the apparatus.
A switch signal from the switch unit 31 of the controller 5 is input to the microcomputer circuit 50 after being subjected to predetermined processing. A memory 51 storing a control program such as an optometry program and a memory 52 storing objective value data are connected to the microcomputer circuit 50. The microcomputer circuit 50 receives a switch signal from the memory 51. Is converted into various data based on the control program stored in the control program, and the screen of the display 30 is controlled via the display circuit 53. Further, the converted signal is input to the microcomputer circuit 55 of the relay unit 6. The microcomputer circuit 55 sends data relating to refractive power and movement of the lens unit 10 to the subjective refractive power inspection device 2 and data relating to the visual target to the visual target presenting device 4.
The microcomputer circuit 60 of the subjective refracting power test apparatus 2 that has received the data relating to the refractive power drives the motor 62 via the drive circuit 61, and the weak spherical disk 63, the strong spherical disk 64, and the auxiliary. The lens disk 65, the cross cylinder disk 66, and the like are rotated, and a predetermined optical system is disposed in the inspection window. The microcomputer circuit 60 drives the drive motors 204 and 207 when receiving a signal related to the slide of the lens unit 10.
[0028]
The microcomputer circuit 70 of the optotype presenting apparatus 4 that has received the data relating to the optotype lights up the lamp 72 via the drive circuit 71 and drives the motor 74 via the drive circuit 73, thereby The target disk 75 on which the target is drawn and the mask disk 76 are rotated to project a predetermined inspection target onto a screen (not shown) placed in front of the eye to be examined.
The objective circuit refractive power measuring device 3 and the lens meter 9 are connected to the microcomputer circuit 55, and the measurement data sent is stored in the memory 56. When a read command signal is input from the microcomputer circuit 50 on the controller 5 side, the microcomputer circuit 55 reads the specified measurement data from the memory 56 and transfers it to the controller 5 side. .
Reference numeral 57 denotes a printer that outputs measurement results, and reference numeral 58 denotes a drive circuit thereof.
[0029]
The operation of the apparatus configured as described above will be described. Here, an operation using an optometry program in which examination items and examination procedures are set in advance will be described (see FIG. 5).
At the time of examination, when the parameter setting or the inquiry information of the subject is inputted, the menu switch 32a of the setting changeover switch group 32 is pushed. A setting menu screen as shown in FIG. 6 is displayed on the display 30. The reverse display portion can be moved by the movement switches 32b and 32c of the switch group 32, and the reverse display item can be selected by the execution switch 32d.
When the “question” menu is selected, an inquiry screen is displayed on the display 30. In the inquiry items, items for inputting the purpose of making glasses, age, sex, occupation, hobby, glasses history, contact lens history, and the like are prepared. For each item, the reverse display portion is moved by the movement switches 32b and 32c and selected by the execution switch 32d. For example, when an item for inputting age is selected, the screen is further switched to an age input screen as shown in FIG. Enter the age by turning the dial switch.
<Execution of optometry program>
When necessary parameter settings and inquiry information are input, the start switch 35 is pressed to execute the optometry program. On the display 30, a message prompting the input of measurement data by the objective eye refractive power measurement device 3 is displayed.
[0030]
<Input of objective value data>
Each objective value data such as S (SPH: spherical power), C (CYL: astigmatic power), A (AXIS: astigmatic axis angle) obtained by the objective eye refractive power measuring device 3 is an objective. By pressing the print switch of the type eye refractive power measuring device 3, the data is stored in the memory 56 via the microcomputer circuit 55 of the relay unit 6. Thereafter, the data input switch 39 of the controller 5 is pushed, and then the objective switch of the input data designation switch group 38 is pushed, so that the objective value data stored in the memory 56 is controlled. Is transferred and stored in the objective value memory area of the memory 52 on the memory 5 side.
The objective value data may be input manually by operating the change mode designation switch group 37 and the dial switch 42 in addition to the data transfer by communication.
[0031]
When the input of the objective value data is completed, the apparatus determines whether or not it is a hyperopic system. Whether or not the system is a hyperopic system is, for example, a value (SE value) converted to an equivalent spherical surface is plus or −O. When the weakness is negative as in 50D, the hyperopic system is determined. In the objective measurement, when the equivalent sphere equivalent value is negative in weakness, it may be measured by adjusting force, and it must be suspected that it may actually be hyperopia. In the case of a hyperopic system, a message such as “Attention to accommodation intervention, especially young people” is displayed for several seconds. This is because a hyperopic eye may not be able to obtain an accurate test result when intervention is carried out, and it is necessary to pay more attention in the case of spectacle prescription. In particular, hyperopia of young people (about 15 years old or younger) is difficult to perform an accurate optometry because the ability to adjust is easy to work, and it may be desirable to have an ophthalmologist perform a treatment such as administering a paralytic agent. . Such a display can alert the inexperienced examiner to the attention, and the examiner should take measures necessary for future examinations (for example, set the amount of fog more than usual or increase the fog time). Or introduction of an ophthalmologist).
It should be noted that values for determining whether or not the system is a hyperopic system (SE values -0.25D, -O.50D, -O.75D, etc.) can be set in advance by parameter setting.
In addition, the display for prompting the attention of the adjustment intervention may be performed only when the age of the subject is input below the predetermined age. In this case, whether to display according to the input age is set in advance by parameter setting. Further, a predetermined age can be set in advance.
[0032]
<Naked eye vision test>
When the input of the objective value data is completed, the objective value data is automatically copied to the subjective value memory area, and is copied to the left and right display portion 81 of the screen example shown in FIG. Previous data (conscious value data = objective value data) is displayed. Thereafter, the inspection item shifts to the naked eye vision test. The display screen of the display 30 is automatically set to a mode in which the right eye naked eye vision value can be input, and the awareness value data moves to the left and right display unit 81. FIG. 8 shows a display example at this time. The current inspection item is displayed on the central display unit 80, and the measurement item to be displayed in reverse can be input.
This apparatus has a function of calculating an expected naked eye visual acuity value based on objective value data. At the start of the naked eye visual acuity test, an inspection target having the calculated expected visual acuity value is displayed on the visual target presenting apparatus 4. An operation signal is issued so as to be presented. The expected naked eye visual acuity value is displayed in the VA column of the central display unit 80, and the currently presented visual target symbol 83 is displayed in the operation explanation area 82 below the central display unit 80. The examiner obtains the response of the examinee, masks the visual target with the switches 34a and 34b of the mask switch group 34, obtains the naked eye visual acuity value of the measuring eye by changing the presentation visual target, and performs the input. . In this case, the subjective refractive power test apparatus 2 may not be arranged in front of the subject's eye, and the subject may be inspected with an eye shield, or the test eye-side examination window is opened, Other eyes may be blocked.
[0033]
When the right eye naked eye vision test is completed, the L eye of the measurement eye designation switch 41 is pressed to similarly perform the left eye naked eye vision test. At this time, if the objective value data of the left eye is a hyperopic system, that effect is displayed on the screen. Also, the test target presented at this time is automatically selected to be different from that for the right eye.
Subsequently, the binocular switch of the measurement eye designation switch 41 is designated, and the naked eye vision test with both eyes is performed. The high visual acuity values of the right eye and the left eye are automatically displayed in the VA column of the central display unit 80, and the examination can be started from these values.
[0034]
<Spectacle data input>
When the naked eye vision of both eyes can be input, the feed switch 36 is pushed to advance to the next inspection item. A message for confirming the presence or absence of glasses (including contact lenses) is displayed on the display 30, and a switch operation instruction based on the presence or absence of glasses is displayed at the bottom of the screen. When the function switch 45 with glasses is pressed in accordance with this instruction, the mode is switched to a mode in which glasses power data can be input. The input of the spectacle frequency data is transferred from the lens meter 9 to the memory 56 and stored in the same manner as the objective value data, and then the spectacles switch of the input switch 39 and the switch group 38 is pressed to store the memory 52. Stored in the front eyeglass memory area (may be manually input by operating the dial switch 42 or the like).
If the eyeglass power is input in advance before starting the examination, the step of inputting the eyeglass data is omitted.
[0035]
<Glass eyesight test>
When the spectacle frequency data can be input, the screen of the display 30 is switched to the spectacle visual acuity confirmation test mode for the right eye. Since an optical system corresponding to the spectacle power data is arranged in the inspection window of the subjective refractive power inspection device 2, the subjective refractive power inspection device 2 may be arranged in front of the eye of the subject. it can. In the VA column of the right eye of the central display unit 80, an expected visual acuity value based on the residual power based on the difference between the objective value data and the spectacle power data is displayed, and the visual acuity presenting device 4 has the visual acuity. A signal is issued to present a test index having a value. Based on the response of the subject, the visual acuity value is obtained by switching the presentation index by the switches 34a and 34b, and the value is inputted. When the left eye and both eyes are examined in the same manner, the visual acuity value is inputted as in the case of the naked eye visual acuity test.
[0036]
<Verification of visual acuity by objective value data>
Subsequently, when the feed switch 36 is pressed, the objective visual acuity confirmation test for confirming the suitability of the objective value data is made. An optical system corresponding to the objective value data is initially set in the inspection window of the lens unit 10 so that the right eye can be inspected. The examiner places the subjective refractive power test apparatus 2 in front of the subject's eyes. In addition, from the optotype presenting apparatus 4, a test mask having an optotype set having a visual acuity value of 0.5 to 0.7 is applied with a vertical mask. The objective visual acuity check test with glasses prescription is performed mainly for the purpose of confirming the reliability of the objective value data and visual function abnormalities such as amblyopia in the eye to be examined. An initial target having a minimum visual acuity value of 0.5 as a standard is presented. In the case of an eye to be examined whose visual acuity value of 0.5 cannot be read, take necessary measures such as re-performing objective measurement and close examination.
[0037]
<Single eye perfect correction decision inspection>
If the presented visual target can be read in the objective visual acuity confirmation test, the feed switch 36 is pressed to move to the next single-eye complete correction determination test. This test generally includes a first R / G (red green) test, an astigmatic axis adjustment test, an astigmatism power adjustment test, and a second R for preventing overcorrection and obtaining the highest visual acuity before the astigmatism test. / G test and visual acuity test are performed in this order, but this apparatus performs the test procedure based on the inputted C value of the objective value data (or the C value of the spectacle frequency data may be used). There is a program to be changed (see FIG. 9). First, the examination procedure proceeds as follows depending on whether or not the C value of the objective value data is equal to or less than the first predetermined reference value (CYL = 0).
[0038]
[A: When CYL = 0]
A message for confirming whether or not to perform astigmatism confirmation is displayed on the screen of the display 30, and “YES” and “NO” operation instructions are displayed at the bottom of the screen. The examiner presses and inputs one of the function switches 45 corresponding to the operation instruction.
[A-1] When the confirmation of astigmatism is not performed, pressing the “NO” switch omits the first R / G inspection, the astigmatism axis adjustment inspection, and the astigmatism power adjustment inspection, and the inspection step is the second R / G shift to inspection. When astigmatism does not appear in objective value data, astigmatism is often not detected even in subjective examinations, so unnecessary inspection items are omitted without many cumbersome switch operations, and examination efficiency is increased. be able to.
[0039]
[A-2] Astigmatism confirmation is performed when the existence of astigmatism is doubtful or accurate. When the “YES” switch is pressed, the process proceeds to the first R / G inspection step. The inspection window of the subjective refractive power inspection apparatus 2 is given a spherical power of +0.50 D with respect to the optical system of the initial value in order to remove the intervention of the adjustment of the measuring eye, and is clouded. The amount of fog is displayed on the display screen. A predetermined red-green target is presented from the target presentation device 4, and the controller 5 is in a mode in which the spherical power can be changed. The examiner operates the dial switch 42 based on the response of the subject's appearance to adjust the spherical power so that the red and green letters on the red green target are the same or the green side looks slightly better. By doing so, the minimum circle of confusion is positioned near the retina.
[0040]
When the spherical power adjustment in the first R / G inspection is completed and the feed switch 36 is pressed, the operation proceeds to a power confirmation inspection using a cross cylinder lens (hereinafter referred to as an XC lens) with the astigmatic axis = 0 degree. A point cloud target is presented as the inspection target, and the controller 5 is in a mode in which the astigmatism power can be changed. In the inspection window of the subjective refractive power inspection apparatus 2, an XC lens is set with a negative axis angle of 90 degrees. The examiner reverses the XC lens using the changeover switch 43a (this switch makes the negative axis 90 degrees), 43b (this switch makes the negative axis 180 degrees), and confirms the difference in appearance to the subject. When the answer is that it looks good, the dial switch 42 is turned to obtain a change in the C value. When it is better to press the switch 43a, turn the dial switch 42 to the left by one click and the C value = −O. 25D, A value = 90 degrees. On the contrary, when it is better to press the switch 43b, when the dial switch 42 is turned to the right by one click, the C value = −O. 25D, A value = 0 degree. Thereafter, the process proceeds to a step when CYL = 0 is not satisfied.
Here, when there is no change in the C value, due to the input of the feed switch 36, the operation proceeds to a frequency confirmation inspection with the astigmatic axis = 45 degrees. The XC lens is set with a negative axis angle of 135 degrees. This is performed to confirm whether there is astigmatism in an oblique direction. Similarly, the examiner reverses the XC lens and confirms the difference in appearance to the subject. If there is no change in the C value even in this inspection, it can be determined that there is no astigmatism, and the precise inspection of astigmatism is unnecessary, and the process shifts to the second R / G inspection. If there is a change, the process proceeds to the step when CYL = 0 is not satisfied.
[0041]
[B: When not CYL = 0]
The apparatus proceeds to the first R / G inspection step according to the determination of the apparatus. The examiner adjusts the spherical power in the same manner as described above so that the minimum circle of confusion is located near the retina.
When the feed switch 36 is pressed after the end of the first R / G test, the C value of the objective value data is equal to or greater than a second predetermined reference value (hereinafter, this value is set to -0.50D). The inspection procedure is changed as follows by the determination of the device. The C value “greater than or equal to” means the larger absolute value including negative reading and positive reading.
[B-1] When the C value is −0.50 D or more, the astigmatism axis adjustment inspection and the astigmatism power adjustment inspection are performed in this order.
In the astigmatism axis adjustment test, the controller 5 is in a mode in which the astigmatism axis can be changed, and the XC lens has an inversion axis in the inspection window of the subjective refractive power test apparatus 2 astigmatism of the objective value data. Set according to the axis. A point cloud target is presented as the inspection target. The examiner reverses the XC lens by the changeover switches 43a and 43b to confirm the difference in appearance to the examinee, and moves the reversal axis until it appears almost uniform before and after the reversal. The device of the embodiment can obtain the angle of the astigmatism axis by moving the inversion axis by a predetermined angle step by turning the dial switch 42 to the switch 43a or 43b side which is replied that it looks good.
[0042]
Regarding the movement of the reversal axis of the XC lens at this time, the apparatus determines whether the C value of the objective value data (or the C value of the spectacle power data) is equal to or greater than a third predetermined reference value. Has a program to change the adjustment angle step. For example, when the C value of the objective value data is −1.25D or more, the value is moved by 1 degree, and when it is less than −1.25D, it is moved by 5 degrees. When the C value is relatively small, it is meaningless because it is not stable even if the axis is detected with a fine angle step. On the other hand, when the C value is large, accurate axis detection is often possible with a fine angle of 1 degree step. Accordingly, the apparatus automatically sets this change based on the C value of the objective value data, so that the examiner does not change the setting for each C value during the examination and is not skilled. Even the examiner can easily and efficiently carry out the examination. Note that the reference value determined by the apparatus can be set in advance by the examiner. This is performed by operating the setting changeover switch group 32 in the parameter setting items in the menu screen. Further, depending on the examination policy of the examiner, the change based on the C value is not performed, and 5 degrees or 1 degree may be always fixed, or may be switched in the middle.
[0043]
When the astigmatic axis adjustment inspection is completed and the feed switch 36 is pressed, the astigmatism power adjustment inspection is started. The positive axis of the XC lens is set in the inspection window of the subjective refractive power inspection apparatus 2 in accordance with the obtained astigmatism axis. The examiner obtains astigmatism power by adjusting the C value to increase or decrease according to the difference in appearance before and after the inversion of the XC lens.
When the feed switch 36 is pressed after the astigmatism power adjustment test is completed, the apparatus compares the obtained astigmatism power with that of the objective value data. When both power fluctuations are 0.25D or less, the obtained values are determined as the astigmatic axis and the astigmatic power, but when the power fluctuation is 0.50D or more, the process shifts again to the astigmatic axis adjustment test. This is because a large power change that changes the astigmatism power by two or more stages increases the possibility of changing the axis. If there is no variation with respect to the previously obtained astigmatism axis value by the astigmatism axis adjustment test, the obtained value is determined as the astigmatism power and the axis, and the process proceeds to the second R / G test. Return to adjustment inspection.
[0044]
[B-2] When the C value is less than −0.50D (that is, −0.25D), the astigmatism power adjustment test is performed first before the astigmatism axis adjustment test. This is because there is a possibility that it becomes 0 at the detection inspection of the astigmatism, and when the astigmatism power is 0, the inspection of the astigmatism axis is unnecessary (the axis detection inspection is performed first, If the degree of astigmatism becomes 0, the axis inspection is wasted).
As a result of this inspection, if CYL = 0, the axis detection inspection is not necessary. Therefore, detection of the astigmatic axis is omitted (assuming AXIS = 0) by pressing the feed switch, and the process proceeds to the second R / G inspection. Is done. When the C value is −0.25D or more, the astigmatism axis is subsequently inspected to determine the astigmatism power and axis.
[0045]
As described above, the astigmatism power and the axis can be adjusted, and when the respective values can be determined, the process proceeds to the second R / G inspection. The inspection window of the subjective refractive power inspection apparatus 2 is given a spherical power of +0.50 D and is clouded. The amount of fog is displayed on the display screen. A predetermined red-green target is presented as the target of the target presentation device 4. Since the controller 5 is in a mode in which the spherical power can be changed, the examiner operates the dial switch 42 based on the response of the subject's appearance, and the letters in red and green are the same. Or make adjustments so that the red side looks a little better.
When the feed switch 36 is pressed after the second R / G inspection is completed, the visual acuity inspection is performed. The test target is presented in a state in which a target set having a visual acuity value of 1.0 is covered with a horizontal mask. When the maximum visual acuity is determined, the examiner adjusts the spherical power to determine the one-eye complete correction value by setting the power to the highest visual acuity from the most positive.
[0046]
When the complete correction value of one eye has been determined, the feed switch 36 is pressed to shift to an inspection for obtaining the other complete correction value. If the maximum visual acuity value of the measurement eye input at this time is less than 0.7, a message is displayed on the screen to confirm the visual acuity by a pinhole test and to prompt the S, C, A most adjustment. The Operation instructions “Yes” and “No” in response to this are displayed at the bottom of the screen. When a pinhole inspection is required, it is designated by the function switch 45 corresponding to the operation instruction (only a message for prompting the pinhole inspection is displayed for a few seconds, and then the judgment is made by the examiner. You may leave it). When “Yes” is designated, a pinhole plate is set in the inspection window of the subjective refractive power inspection apparatus 2. The eye to be examined is made to see the visual acuity test target through a pinhole, and it is confirmed whether or not the visual acuity has improved. In the lower part of the screen, “YES” and “NO” operation instructions for inquiring whether the eyesight has improved are displayed, and the function switch 45 is pressed in accordance with the operation instructions.
[0047]
When “NO” is entered, a message indicating that a close examination of the cornea, retina, etc. is required is displayed. If there is no change in visual acuity even after a pinhole test, not only correction abnormalities but also other abnormalities such as the cornea, retina, and optic nerve are considered, so the examiner takes necessary measures such as a close examination. be able to.
When “YES” is entered, the test item returns to the visual acuity confirmation test based on the objective value data, which is the first stage of the subjective test. If the visual acuity is improved by the pinhole test, the complete correction may be insufficient, so the complete correction test is repeated.
If the maximum visual acuity value for one eye is 0.7, the test is shifted to the test for obtaining the complete correction value for the other by pressing the feed switch 36. The examiner obtains the other complete correction value in the same manner.
[0048]
<Binocular balance test>
When the complete correction value for each eye is obtained, the feed switch 36 is pressed to shift to the binocular balance test. Both the inspection windows of the subjective refractive power inspection apparatus 2 are provided with polarizing plates, and are given a spherical power of a cloud amount so that the visual acuity value of each complete correction is about 0.8. It is done. The amount of fog is displayed on the display screen. Further, the central display unit 80 on the screen is a mode in which the values obtained by one-eye perfect correction are copied, and the spherical power of both eyes can be input. A value obtained by complete correction including a visual acuity value is transcribed on the left and right display unit 81. A test target is a binocular balance target.
The subject is made to confirm the difference between the left and right appearances by the binocular balance target. When there is a difference, the eye on the side that can be seen well is designated by the R switch or L switch of the measurement eye designation switch 41, and balance correction is performed by adding S + 0.25D. At this time, the naked eye visual acuity value and the visual acuity value by the front glasses are displayed below the central display unit 80. When the corrected eye becomes difficult to see due to balance correction, this information is used as a reference to give preference to the one with the better eyesight value from the previous glasses (if it is the first person, the one with better eyesight is preferred) To do). In addition, since the balance correction may be determined by a sight, it is convenient to input the sight information in advance and store it in a memory and display it on the screen.
In this way, a binocular perfect correction value (in this specification, a complete correction value after performing a binocular balance test is referred to as a binocular complete correction value) is obtained.
[0049]
<Stereoscopic confirmation inspection>
When the balance adjustment of both eyes is completed, the stereoscopic switch is inspected by pressing the feed switch 36. A message that informs the examiner that the cloud of spherical power applied during the binocular balance test is removed from both the inspection windows of the subjective refractive power inspection apparatus 2 and that the fog has been released below the central display unit 80. -The message is displayed. In this way, the apparatus automatically cancels the cloud according to the input signal of the feed switch 36 and displays the fact so that the examiner performs the next inspection with an appropriate optical system without forgetting to cancel the cloud. be able to.
In the stereoscopic vision check inspection, a stereoscopic visual target is presented. Operation instructions (1 ′, 2 ′, 4 ′, 10 ′, NG) for inputting stereoscopic parallax are displayed at the bottom of the screen. The examiner presses the function switch corresponding to the operation instruction and inputs it depending on how far the subject can confirm the stereoscopic parallax. This result is printed at the time of printout.
[0050]
<Distance correction for distance use-(1) Automatic adjustment>
When the stereoscopic vision inspection is completed, the process proceeds to distance correction power adjustment for determining a prescription value standard for distance use. This device is an automatic adjustment program that automatically calculates the standard frequency of the prescription value that is expected to be optimal for the subject based on the binocular perfect correction value and the spectacle value obtained as described above. The automatic adjustment program is executed by an input signal of the feed switch 36 while the optometry program is in progress, and the calculated prescription frequency of the prescription value is displayed on the central display unit 80.
The automatic adjustment program will be described below using the flowcharts shown in FIGS. The “strength eye” used in the following description means that the absolute value of the frequency is larger in each of the S and C values of binocular perfect correction, and “weak eye” means the opposite. And Astigmatism (C value) is negatively read.
[0051]
First, the apparatus determines whether or not there is astigmatism based on the binocular perfect correction value (STEP 1-1). When there is astigmatism, it is further determined whether or not oblique astigmatism (AXIS: 15 ° to 75 ° or 105 ° to 165 °) (STEP 1-2). Thereafter, it is determined by the S value of both eyes whether it is hyperopia (both eyes plus or one eye plus one eye is 0) or myopia (both eyes minus or one eye minus and one eye is 0) (STEP 1- 3 to 1-5), any one of the following power adjustments A to F is performed to calculate the adjustment power. When it is not possible to distinguish between hyperopia and myopia (when the S value of one eye is positive and the S value of the other eye is negative), the frequency adjustment is not performed, and an indication that the examiner adjusts is displayed.
[0052]
[Automatic adjustment A: No astigmatism, far-sightedness]
The apparatus determines whether or not the subject is first dressed based on the presence / absence of spectacle power data (presence / absence of spectacle history) (STEP A-1).
[A-1]] In the case of the first time wearing, next, the right and left difference of S value is compared (STEP A-2). If the left-right difference of the S value is within a predetermined frequency difference (hereinafter, the left-right difference of the S value or C value will be described as being adjusted within 0.75D), the adjustment power remains the binocular perfect correction value. And When the left-right difference of the S value exceeds 0.75D, the S value of the strong eye is set to a value obtained by adding + 0.75D to the S value of the weak eye (STEP A-3).
[A-2] When it is not first-appearance, the left-right difference of S values is compared (STEP A-4), and when the left-right difference exceeds 0.75D, the S value on the strength eye side is the S value of the weak eye The value obtained by adding + 0.75D to the value obtained by adding + 0.75D to the value on the same side of the front glasses and the value obtained by adding a predetermined frequency (hereinafter referred to as + 0.75D for hyperopia) is obtained. Does not exceed the binocular perfect correction value (STEP A-5).
[Automatic adjustment B: Myopia without astigmatism]
[0053]
It is determined whether or not the subject is first-wearing (STEP B-1).
[B-1] In the case of initial wear, first of all, the correction amount ΔS1 is obtained by calculating the table A in FIG. A correction process for subtracting the correction amount ΔS1 from the S value (hereinafter referred to as a correction process A1) is performed (STEP B-2). Next, the left and right differences after the correction processing are compared (STEP B-3), and if the difference exceeds 0.75D, the S value for the high intensity eye is set to -0.75D for the S value for the weak eye. The subscribed value is set (STEP B-4).
[B-2] When it is not the first apparel, the correction amount ΔS2 is obtained by calculating the table B in FIG. 16 based on the smaller difference between the front spectacles and the binocular perfect correction value in the left and right S values. A correction process for subtracting the correction amount ΔS2 from the S value for binocular perfect correction (hereinafter referred to as correction process B1) is performed for both eyes (STEP B-5). Next, the left and right differences of the S values after the correction process are compared (STEP B-6). If the difference exceeds 0.75D, the S value on the strength eye side is the S value of the weak eye that has been corrected. Obtain the larger absolute value of the value obtained by adding -0.75D and the value obtained by adding the predetermined frequency (hereinafter referred to as -0.75D for myopia) to the S value of the front glasses, and that value is completely Do not exceed the correction value (STEP B-7).
[0054]
[Automatic adjustment C: Hyperopia with astigmatism without oblique astigmatism]
It is determined whether or not the subject is first-wearing (STEP C-1).
[C-1] In the first case, first, the correction amount ΔC1 is obtained by calculating the table C in FIG. 16 based on the value of the C value weak eye, and the C value for binocular perfect correction is obtained for both eyes. Then, a correction process for subtracting the correction amount ΔC1 (hereinafter referred to as a correction process C1) is performed (STEP C-2). Subsequently, the S value of both eyes is set to a value obtained by adding half of the correction amount ΔC1 to the binocular perfect correction value to obtain an equivalent spherical surface (STEP C-3). Thereafter, the left and right differences of the obtained S values are compared (STEP C-4), and if it exceeds 0.75D, the S value on the strength eye side is a value obtained by adding + 0.75D to the S value of the weak eye. (STEP C-5). Next, the left-right difference of the C value after the correction process C1 is compared (STEP C-6). If it exceeds 0.75D, the C value of the strong eye adds -0.75D to the C value of the weak eye. Value (STEP C-7).
[0055]
[C-2] When it is not first clothing, first, based on the determination of the presence or absence of astigmatism in the front spectacle value (STEP C-8), if there is no astigmatism, the same frequency adjustment as in the first clothing is performed (STEP C-2). -C-7).
When there is astigmatism in the front spectacle value, the correction amount ΔC2 is obtained by calculating the table D in FIG. 16 based on the smaller difference between the front spectacle value and the binocular perfect correction value in the left and right C values. A correction process for subtracting the correction amount ΔC2 from the C value for binocular perfect correction (hereinafter referred to as correction process D1) is performed for both eyes (STEP C-9). Subsequently, the S value of both eyes is set to a value obtained by adding half of the correction amount ΔC2 to the binocular perfect correction value to obtain an equivalent spherical surface (STEP C-10). Thereafter, the left and right differences of the obtained S values are compared (STEP C-11), and if the difference exceeds 0.75D, the S value on the strength eye side is +0 to the S value of the weak eye having an equivalent spherical surface. The larger absolute value of the value obtained by adding .75D and the value obtained by adding + 0.75D to the S value on the same side of the front glasses is obtained so that the value does not exceed the complete correction value (STEP C- 12). Next, when the left-right difference of the C value after the correction process D1 exceeds 0.75D (STEP C-13), the C value on the strength eye side is a value obtained by adding -0.75D to the C value of the weak eye. The larger absolute value of the value obtained by adding −0.75D to the C value on the same side of the front glasses is obtained so that the value does not exceed the complete correction value (STEP C-14).
[0056]
[Automatic adjustment D: Myopia with astigmatism without oblique astigmatism]
It is determined whether or not the subject is first-wearing (STEP D-1).
[D-1] At the time of initial wearing, correction processing C1 is performed (STEP D-2), and correction processing A1 is performed (STEP D-3). Thereafter, the left and right differences of the obtained S values are compared (STEP D-4). (STEP D-5). Next, the left-right difference of the C value after the correction process C1 is compared (STEP D-6). When it exceeds 0.75D, the C value of the strong eye adds -0.75D to the C value of the weak eye. Value (STEP D-7).
[0057]
[D-2] When it is not the first wear, first, it is determined whether or not there is astigmatism of the front spectacle power (STEP D-8). When there is astigmatism, correction processing D1 is performed (STEP D-9). Subsequently, a correction process B1 is performed (STEP D-10). Thereafter, the left-right difference of the obtained S values is compared (STEP D-11), and if it exceeds 0.75D, the S value on the strength eye side is a value obtained by adding -0.75D to the S value of the weak eye. The larger absolute value of the S value on the same side of the front glasses and the value obtained by adding -0.75D is obtained so that the value does not exceed the complete correction value (STEP D-12). Next, the left-right difference of the C value after the correction process D1 is compared (STEP D-13). If it exceeds 0.75D, the C value for the high intensity eye is set to -0.75D for the weak eye. Obtain the larger absolute value of the value obtained by adding -0.75D to the C value of the front eyeglass on the same side as the added value, so that the value does not exceed the complete correction value (STEP D-14) .
[0058]
When there is no astigmatism in the determination of the presence or absence of astigmatism at the front spectacle power, correction processing C1 and correction processing B1 are performed (STEP D-15, D-16). Thereafter, the left and right differences of the obtained S values are compared (STEP D-17), and if it exceeds 0.75D, the S value on the strength eye side is the value obtained by adding -0.75D to the S value of the weak eye. The larger absolute value of the S value on the same side of the front glasses plus -0.75D is obtained, and the value does not exceed the complete correction value (STEP D-18). Next, when the left-right difference of the C value after the correction process C1 exceeds 0.75D, the C value on the strength eye side is set to a value obtained by adding −0.75D to the C value of the weak eye (STEP D-19). , D-20).
[0059]
[Automatic adjustment E: Hyperopia with oblique astigmatism]
The apparatus determines whether or not the subject is first dressed (STEP E-1).
[E-1] At the time of the initial wearing, both the left and right C values are -0.50D or less (hereinafter, in this specification, the C value is -0.50D or less, that is, the smaller one, that is, -0. 25D or -0.50D) (STEP E-2). In oblique astigmatism, when the C value is small, it is often better for the subject not to perform astigmatism correction. Therefore, when both C values are −0.5 D or less, astigmatism is ignored and C value = 0 is set. The left and right S values are set to equivalent spherical surfaces by adding half of the respective C values (STEP E-3). Thereafter, the left and right differences of the obtained S values are compared (STEP E-4), and if it exceeds 0.75D, the S value on the strength eye side is a value obtained by adding + 0.75D to the S value of the weak eye. (STEP E-5).
In the determination of whether or not the C value is −0.5 D or less (STEP E-2), when at least one of the left and right C values exceeds −0.5 D, correction processing C1 is performed (STEP E− 6) The S values of both eyes are both made equal to the binocular perfect correction value by adding half of the correction amount ΔC1 to obtain an equivalent spherical surface (STEP E-7). Subsequently, when the left-right difference of the obtained S value exceeds 0.75D, the S value on the strength eye side is set to a value obtained by adding + 0.75D to the S value of the weak eye (STEP E-8, E-). 9). Next, when the left-right difference of the C value after the correction process C1 exceeds 0.75D, the C value of the strong eye is set to a value obtained by adding −0.75D to the C value of the weak eye (STEP E-10, E-11).
[0060]
[E-2] When the subject is not first-dressed, it is first determined whether or not the left and right C values are both equal to or less than -0.5 D (STEP E-12), and then the front glasses each have astigmatism. (STEP E-13, E-14).
When the C values for binocular perfect correction are both within -0.5 D and the anterior glasses do not have astigmatism, the C value is set to 0, and the left and right S values are added to half of each C value to make an equivalent spherical surface. Value (STEP E-15). Thereafter, the left and right differences of the obtained S values are compared (STEP E-16), and if it exceeds 0.75D, the S value on the strength eye side is + 0.75D to the S value of the weak eye with an equivalent spherical surface. The larger value of the added value and the value obtained by adding + 0.75D to the S value on the same side of the front glasses is obtained, and the value is prevented from exceeding the complete correction value (STEP E-17).
When the front glasses have astigmatism regardless of the C-value of binocular perfect correction, the same processing as STEP C-9 to C-14 is performed (STEP E-18 to 23).
When at least one of the left and right C values exceeds −0.5 D and the front glasses do not have astigmatism, correction processing C1 is performed (STEP E-24), and both S values of both eyes are completely corrected values for both eyes. Is added to half the correction amount ΔC1 to obtain an equivalent spherical surface (STEP E-25). Subsequently, the left and right differences of the obtained S values are compared (STEP E-26). If the difference exceeds 0.75D, the same processing as STEP C-12 is performed (STEP E-27). Next, the left-right difference of the C value after the correction process C1 is compared (STEP E-28). If the left-right difference exceeds 0.75D, the C value of the strong eye is set to −0. It is set as the value which added 75D (STEP E-29).
[0061]
[Automatic adjustment F: Myopia with oblique astigmatism]
The apparatus determines whether or not the subject is initially dressed (STEP F-1).
[F-1] In the case of the initial wearing, it is next determined whether or not both left and right C values are equal to or less than -0.5 D (STEP F-2). When both C values are within −0.5 D, both C values = 0 (STEP F-3). Subsequently, the S value is subjected to correction processing A1 (STEP F-4). Then, the left and right differences of the obtained S values are compared (STEP F-5). If the left and right difference exceeds 0.75D, the S value on the strength eye side adds -0.75D to the S value of the weak eye. (STEP F-6).
In the determination of whether or not the C value is −0.5 D or less (STEP F-2), when at least one of the left and right C values exceeds −0.5 D, correction processing C1 is performed (STEP F−). 7). Subsequently, the correction process A1 is performed on the S value (STEP F-8). Thereafter, the left and right differences of the obtained S values are compared (STEP F-9). If the left and right difference exceeds 0.75D, the S value on the strength eye side adds -0.75D to the S value of the weak eye. (STEP F-10). Next, the left-right difference of the C value after the correction process C1 is compared (STEP F-11). If the left-right difference exceeds 0.75D, the C value of the strong eye is set to −0. It is set as the value which added 75D (STEP F-12).
[0062]
[F-2] When the subject is not first-dressed, first, it is determined whether or not the left and right binocular perfect correction C values are both −0.5 D or less (STEP F-13). It is determined whether or not the glasses have astigmatism (C value) (STEP F-14, F-15).
When the C value for binocular perfect correction is within −0.5 D and the front glasses do not have astigmatism, C value = 0 is set (STEP F-16). Subsequently, a correction process B1 is performed (STEP F-17). Thereafter, the left-right difference of the obtained S values is compared (STEP F-18). If the left-right difference exceeds 0.75D, the intensity eye side S value is processed in the same manner as STEP B-7 (STEP F -19).
When the front glasses have astigmatism regardless of the C-value for binocular perfect correction, the same processing as STEP D-9 to D-14 is performed (STEP F-20 to F-25).
When at least one of the left and right C values exceeds −0.5 D and the front glasses do not have astigmatism, the C value is subjected to correction processing C1 (STEP F-26), and the S value is subjected to correction processing B1. (STEP F-27). Thereafter, the left and right differences of the obtained S values are compared (STEP F-28). If the left and right difference exceeds 0.75D, the S value on the strength eye side is processed in the same manner as STEP B-7 (STEP F -29). Next, the left-right difference of the C value after the correction process C1 is compared (STEP F-30). If the left-right difference exceeds 0.75D, the C value of the strong eye is set to −0. It is set as the value which added 75D (STEP F-31).
[0063]
As described above, when the apparatus can distinguish between hyperopia and myopia, the apparatus automatically calculates the prescription value standard frequency by performing any of the automatic adjustments A to F.
In the above automatic adjustment program, the amount of adjustment for adjusting the S value or C value on the strength eye side is ± 0 with respect to the S value or C value when the amount of change from the front eyeglass on the same side is adopted. .75D (3 steps) adjustment (STEP A-5, B-7, C-14, etc.), but ± 0.50D (2 steps) adjustment amount is changed according to the age of the subject. You may do it. This is because there is a difference in adaptability with respect to changes in the power of the front glasses depending on the age. If you are a young person, you can adapt even if there are three steps (0.75D) of changes in the frequency of the front glasses, but generally the change in two steps (0.50D) will be limited as the age increases. Therefore, if the adjustment amount of the prescription power is changed according to the adaptability of the eye to be examined, a prescription more suitable for the wearer can be obtained. To change the frequency adjustment amount according to age, do as follows. In the automatic adjustment program, for example, two kinds of frequency adjustment amounts of three levels (0.75D) and two levels (0.50D) are prepared depending on whether or not a certain age (38 years old) or more (more types are available) May be provided). While the optometry program is in progress, when the feed switch 36 is pressed after the stereoscopic vision check is completed, an operation instruction for inputting the age of the subject “under 38 years” or “above 38 years” is displayed at the bottom of the screen. The When the examiner presses the function switch corresponding to one of the operation instructions, the apparatus calculates the reference frequency using the adjustment amount set in advance corresponding to the input signal.
[0064]
In the embodiment, the input signal of the feed switch 36 is obtained and the automatic adjustment program is executed. However, this automatic adjustment program is executed if necessary data is input even in manual optometry. be able to. In manual optometry, when the “prescription” switch of the input data designation switch group 38 is pressed while pressing the shift switch 44, the automatic adjustment program is executed. Also in this case, the frequency adjustment amount may be changed depending on the age of the subject.
Furthermore, in the above embodiment, the correction amounts ΔS1, ΔS2, ΔC1, and ΔC2 of the correction processes A1 to D1 are obtained by calculation. However, table tables are prepared in advance and obtained based on these. It can also be done.
[0065]
<Distance adjustment for distance correction-(2) Adjustment by examiner>
When the standard frequency of the prescription value is calculated by the automatic adjustment program, the result is displayed on the display 30. FIG. 17 is a diagram showing a screen example of the display 30 after automatic adjustment. The central display unit 80 changes to the prescription mode, and the S value and C value of the display are displayed as the standard frequency automatically adjusted by the apparatus, and the distance display frequency is adjusted below the central display unit 80. A message is displayed. An optical system corresponding to the automatically adjusted power is set in both inspection windows of the subjective refractive power inspection device 2, and the visual acuity having a visual acuity set of 0.9 to 1.2 from the visual target presenting device. A value target is presented. The examiner confirms the appearance of the adjusted power, and finely adjusts the distance correction power by operating the switch.
[0066]
The device is for manual adjustment that changes the frequency of the item to be adjusted when switch input is made based on the distance of myopia, myopia, astigmatism, astigmatism, or the presence of oblique astigmatism in the prescription value standard frequency calculated by the automatic adjustment program Have a control program. When the automatic adjustment program is executed, the frequency of the item to be adjusted is changed by obtaining the response of the appearance of the subject and inputting the changeover switch 43a or 43b.
Hereinafter, manual adjustment based on the control program of the apparatus will be described (see FIGS. 18 and 19).
[0067]
[Manual adjustment A: When adjusting the power of hyperopia without astigmatism]
The subject visually recognizes the presented target through the optical systems set in both inspection windows of the subjective refractive power inspection apparatus 2 and confirms the appearance in the automatically adjusted frequency. If the subject is satisfied with the appearance, the adjustment is terminated. If it is difficult to see, the “strong” switch 43b is pressed. Based on this input signal, it is determined whether or not the binocular S value of the adjustment power is greater than 0. This is repeated until the subject is satisfied with the appearance or the S value is 0 for both eyes. One eye S value is0After becoming D, the other eye0Adjust until D. In the hyperopia correction, the adjustment on the myopia side where the S value becomes negative is not good, so when the S value becomes 0, a warning sound is emitted by the buzzer 54 to notify that the input is impossible. In this flow, the input of the “weak” switch 43a is not accepted, and a buzzer sound is similarly generated when this switch is pressed.
[0068]
[Manual adjustment B: Myopia power adjustment without astigmatism]
The examiner confirms the appearance at the automatically adjusted frequency. If it is difficult to see, the “strong” switch 43b is pressed. Based on this input signal, it is determined whether or not the S value of the adjustment power is larger than the S value for binocular perfect correction (is smaller in absolute value), and when it is larger, -0.25D is added to the S value for both eyes. The input of the “strongly” switch 43b is accepted until both the adjusted binocular S values reach the limit of the binocular perfect correction value, and a buzzer sounds when the limit is reached. A buzzer will sound when you hit it).
If there is a sense of incongruity (high degree) by checking the appearance, the “weak” switch 43a is pressed. It is determined whether the S value of both eyes does not fall below -0.25D (is not 0). If not, -0.25D is added to the S value of both eyes. After one eye reaches −0.25D, adjustments are made until the other eye reaches −0.25D.
[0069]
[Manual adjustment C: When astigmatism and hyperopia power adjustment is not oblique astigmatism]
The examiner confirms the appearance at the automatically adjusted frequency. If it is difficult to see, the frequency is adjusted in the same manner as the manual adjustment A by pressing the “strong” switch 43b.
When the subject complains of discomfort, the “weak” switch 43a is pressed. It is determined whether the C value of both eyes does not fall below -0.25D (is not 0). If not, + 0.25D is added to the C value of both eyes, and if it falls below, a buzzer sounds. Be emitted.
[Manual adjustment D: When the power of astigmatism and myopia is not oblique astigmatism]
The examiner confirms the appearance at the automatically adjusted frequency. If it is difficult to see, the frequency is adjusted in the same manner as the manual adjustment B by pressing the “strong” switch 43b.
[0070]
When the subject complains of discomfort, the “weak” switch 43a is pressed. It is determined whether the S and C values of both eyes do not fall below -0.25D, and when both the S and C values of both eyes do not fall below -0.25D, the C value or S value of the switch 43a The frequency is sequentially adjusted by the combination of the S value and the C value according to the number of inputs as follows. In the first input signal, + 0.25D is added to the C value of both eyes. In the second input signal, + 0.25D added to the C value in the first time is returned, and + 0.25D is added to the S value. In the third input signal, + 0.25D is added to the C value for the second adjustment frequency. Thereafter, the process is repeated until both the S value and the C value reach the limit depending on the number of inputs of the switch 43a (if either one reaches the limit first, the frequency of the other is reduced).
[0071]
[Manual adjustment E: When adjusting the power of oblique astigmatism and hyperopia]
The examiner confirms the appearance at the automatically adjusted frequency. If it is difficult to see, the frequency is adjusted in the same manner as the manual adjustment A by pressing the “strong” switch 43b.
When the subject complains of discomfort, the “weak” switch 43a is pressed. It is determined whether the C value of both eyes does not fall below -0.25D (is not 0). If not, the relationship between the C value or A value of both eyes depends on the number of inputs of the switch 43a. Adjusted based on
The frequency adjustment of the combination of the C value and the A value in oblique astigmatism will be described. In order to reduce the discomfort of spatial vision in oblique astigmatism, adjustments are made so that the axis approaches horizontal or vertical. At this time, if the axis obtained by complete correction is rotated, new astigmatism occurs. C value of complete correction is C₁, A value is θ₁And the C value of the prescription is C₂, A value is θ₂Then the newly generated astigmatism power C₀And its axial angle θ₀Is expressed as:
(B) tan 2θ₀= (C₁sin 2θ₁-C₂sin 2θ₂) / (C₁cos 2θ₁-C₂cos 2θ₂).
(B) C₀= (C₁sin 2θ₁-C₂sin 2θ₂) / Sin 2θ₀
[0072]
When there is a sense of incongruity, the astigmatism power is reduced by the input of the “weak” switch 43a, so that newly generated astigmatism, that is, residual astigmatism is increased. Since the change step of the astigmatism power in the embodiment is 0.25D, the apparatus is based on the above formula so that the residual astigmatism power due to shaft rotation is in the middle of the change step 0.25D (approximately 0.12D), The frequency is adjusted so as to change by approximately 0.12D in terms of C value according to the number of times of input of the switch 43a. In the first input of the switch 43a, first, the axial angle of both eyes is adjusted so as to change by approximately 0.12D in terms of C value. In the second input, the axis angle is returned to further change by approximately 0.12D, and the C value of both eyes is decreased by 0.25D. In the third input, the shaft angle is adjusted to change by approximately 0.12D with respect to the second input. As described above, astigmatism is adjusted based on the relationship between the number of inputs of the switch 43a and the combination of the C value and the A value (see the specific example shown in FIG. 20). After the C value of one eye becomes −0.25D, the adjustment can be performed until the C value of the other eye becomes −0.25D.
Note that astigmatism adjustment may be performed based on a table prepared in advance, instead of the above calculation.
[0073]
[Manual adjustment F: When adjusting the power of oblique astigmatism and myopia]
The examiner confirms the appearance at the automatically adjusted frequency. If it is difficult to see, the frequency is adjusted in the same manner as the manual adjustment B by pressing the “strong” switch 43b.
When the subject complains of discomfort, the “weak” switch 43a is pressed. It is determined whether both eyes 'S value and C value are less than -0.25D, and when both eyes' S value and C value are not less than -0.25D, both eyes S, C, and A are adjusted based on the combination of these. This adjustment is also performed by the same process as in the above-described manual adjustment E. In the first input, first, the shaft angle is reduced by approximately 0.12 D in terms of C value by adjusting the shaft angle. In the second input, the shaft angle is returned and the C value is decreased by 0.25D. In the third input, the change in the previous C value is returned and the S value is decreased by 0.25D. In the fourth input, the previous S value is kept as it is, and is reduced by approximately 0.12D in terms of C value by adjusting the shaft angle. Thereafter, these are repeated in order. After the C value of one eye becomes −0.25D, the adjustment can be performed until the C value of the other eye becomes −0.25D. In addition, after the S value of one eye becomes −0.25D, the adjustment can be performed until the S value of the other eye becomes −0.25D.
[0074]
As in the above manual adjustments A to F, the appearance of the subject is confirmed, the response is obtained, and either the switch 43a or 43b is input to automatically adjust the frequency of the appropriate item. The For this reason, even an inexperienced examiner can easily adjust the distance power without hesitation in the items to be adjusted, the directionality thereof, and the switch operation.
[0075]
In the manual adjustment prescription mode, each time the switch 43a or 43b is pressed, the previous prescription frequency data is sequentially stored in the memory of the apparatus, and an operation explanation area on the screen as shown in FIG. Below the prescription value 1 of the automatic adjustment frequency calculated by the apparatus, a display 90 indicating that the adjustment frequency is sequentially stored as a prescription value 2, a prescription value 3,. When the function switch 45 corresponding to each prescription value on the display 90 is pushed, the display of the optical system arranged in the inspection window of the subjective refractive power inspection apparatus 2 and the central display unit 80 is immediately switched, and the adjustment power is compared. Can be done instantly. Of course, the item to be adjusted and its frequency can be manually changed by specifying each of the switches S, C, and A of the change measurement data specifying switch group 37 and turning the dial switch 42 right or left. By pressing the function switch 45 corresponding to the “copy” display 91 of the operation instruction display, the data can be copied, manually changed, and stored in the memory.
[0076]
In the prescription mode, a plurality of reference data of results in the previous inspection modes are displayed on the left and right sides of the central display unit 80. In the screen example of FIG. 17, a first left and right display 81 a that displays a spectacle value as a result of the second previous examination mode and a confirmation visual acuity value, and one eye as a result of the previous examination mode A second left / right display 81b that displays the awareness value of the complete correction and the confirmation visual acuity value is displayed (when there is no front spectacle data, the naked eye visual acuity value is displayed). Thereby, the examiner can easily confirm the data obtained in advance for the current measurement mode. In particular, at the stage of adjusting the prescription power, it is convenient because it is possible to make adjustments while simultaneously comparing eyeglass values and awareness values of one-eye perfect correction. In addition, the visual acuity value of the front glasses and the visual acuity value in the subjective examination of the one-eye perfect correction are displayed. Can be used to adjust the prescription.
[0077]
In the screen example of FIG. 17, the reference data is displayed as two types of data of the first and second left and right displays, but three or more types of data may be displayed. The number of types of data to be displayed is designated by parameter setting in the menu screen before inspection.
In the embodiment, an optometry program is used. Of course, a plurality of reference data can be displayed in a manual examination. The stage to be displayed may be set in advance, or may be displayed when a plurality of inspection data are input.
When the display of the reference data is changed to other data, the following is performed. For example, when it is desired to view the objective value data in the screen example of FIG. 17, the objective switch of the switch group 38 is pressed while the shift switch 44 is being pressed. The subjective value data for the one-eye perfect correction shifts to the first left / right display 81a, and the objective value data called from the memory is displayed on the second left / right display 81b. In this way, it is possible to freely call and display only the data to be viewed without changing the current measurement mode.
[0078]
<Near-term inspection>
When the distance correction power is adjusted, the feed switch 36 is pushed to proceed to the next inspection. Since a message asking whether a near-field inspection is necessary is displayed on the screen of the display 30, the function switch 45 is pushed in accordance with an operation instruction when performing a near-field inspection. Subsequently, an operation instruction for inputting the age of the subject is displayed on the screen (may be omitted when the age is input at the time of the inquiry). When the function switch 45 corresponding to the operation instruction is pressed, the apparatus issues an operation signal to the subjective refractive power inspection apparatus 2. The optical system of the binocular perfect correction value is set in the inspection window of the subjective refractive power inspection device 2, and the addition power expected based on the input age (this addition power is half of the expected value or three stages). (0.75D) weaker setting can be made), and a near-field XC lens is set. When a signal for near-field inspection is input, the turning mechanism of the subjective refractive power inspection apparatus 2 is driven, and the lens unit 10 is converged at a convergence angle corresponding to the near-distance 35 cm. The controller 5 is in the ADD addition mode, and the spherical power can be added by the dial switch 42 or the like. The examiner presents a cross-grid near target at a distance of 35 cm in front of the subject's eyes. Measure the addition with both eyes and enter the addition.
[0079]
When the addition power can be input, the feed switch 36 is pushed. When the apparatus receives the input signal, the screen is displayed for confirming whether or not the subject wears the near eyeglasses for the first time. If it is the first time, adjustment is performed by adding -0.25D to the addition power by the function switch 45, and if it is not the first time, the function switch 45 is left as it is. The device converts the difference between the S value adjusted by the distance adjustment from the binocular perfect correction value and the difference between the C-value equivalent spherical surfaces into the addition power, and calculates the addition power by subtracting this from the measured addition power. However, when this becomes negative, the addition power is zero. The adjusted value is displayed on the screen of the display 30, and a message indicating that the addition power is adjusted is displayed.
Thereafter, the examiner sets a near vision chart for visual acuity confirmation and confirms that the visual acuity value does not fall below 0.7. If so, check your vision. Add + 0.25D to the ADD value of both eyes and see if the eyesight improves. If the visual acuity increases, add + 0.25D to the ADD value of both eyes. If it does not change or falls, add -0.25D to the ADD value of both eyes and bring it back down. In this way, the addition power is determined.
[0080]
[Confirmation of the degree of distant power in a congested state]
After determining the addition power, it is as follows when confirming how far it is difficult to see the near vision target with the distance adjustment power to the subject. The examiner presses the ADD switch of the switch group 37. When this switch signal is input, the apparatus leaves the subjective refractive power inspection apparatus 2 in a congested state, cancels the addition power, and finally arranges the optical system of the adjusted distance power in the inspection window. To do. The subject is shown a near vision target in this state. Next, when the ADD switch is pressed again, the device returns the released addition power. The subject is again shown the near vision target with the prescribed addition power. In this way, the state of the near vision power and the distance vision power can be switched immediately while the subjective refractive power test apparatus 2 is in a congested state, so that the subject can clearly realize the difference in appearance. Can be made.
[0081]
[Frequency conversion to different near work distance]
Further, in the near inspection, the addition at a predetermined distance (35 cm in the embodiment) is obtained, but depending on the subject, the necessary near work distance may be different from the distance in the near inspection. In this case, it is necessary to adjust the addition power at the near working distance required by the subject. By inputting the necessary near work distance, this device can convert the measured near power to the near power of the input distance.
A method of converting near-use power into different near-work distances performed by the apparatus will be described.
If the addition power measured at the near examination distance f (m) is ADD (f), the adjustment force required for the near examination distance f can be considered as 1 / f. 1 / f-ADD (f). On the other hand, if the adjustment force required at different near working distances f ′ (m) is 1 / f ′, the addition power ADD (f ′) required for this is:
ADD (f ′) = {1 / f ′ − (1 / f−ADD (f))}
It can be. However, when calculating the frequency, the frequency is rounded to the nearest in a predetermined measurement step (O.25D step in the embodiment).
[0082]
The conversion operation to different near work distances is performed as follows. When the feed switch 36 is pressed after the near-field inspection is completed, an operation instruction 92 indicating the necessary near work distance is displayed on the display screen as shown in FIG. The examiner presses the function switch 45 corresponding to the required distance. Based on the calculation as described above, the apparatus converts the addition obtained by the measurement into the addition of the input distance and calculates the addition. The calculated conversion addition power is displayed in the ADD column of the central display unit 80. Thus, the examiner can easily know the addition power at the near work distance required by the examinee.
Different near work distances may be input multiple times. Each time the function switch 45 corresponding to the required near work distance is pressed, the converted addition is displayed. When the frequency conversion to a different near work distance is completed or unnecessary, the feed switch 36 is pushed.
Further, the optical system arranged in the inspection window of the subjective refractive power inspection apparatus 2 is provided with the converted addition power so that the appearance at the addition power at different near working distances can be confirmed. Also good. Furthermore, the state of convergence of the subjective refractive power test apparatus 2 may be converged in accordance with the input near work distance, and a near visual acuity table for the necessary near work distance may be presented to check the appearance.
[0083]
As described above, when all the inspections are completed and the prescription value is determined, the print switch 40 is pressed to print out the measurement result. FIG. 23 shows an example of the printing. The distance prescription values S, C, and A are printed on the printing unit 101 of the FINAL column 100 indicating the prescription value. The addition power at the near-inspection distance of 35 cm is printed on the printing unit 102 below. When a different near work distance is input, the addition power converted together with the input distance is printed on the printing unit 103 of the printing unit 102. When multiple near work distances are entered, they are further printed below.
In the FAR + ADDITION column 104, processing for adding the addition power to the S value of the distance prescription is performed by the apparatus, and the near-use prescription values of the S value, C value, and A value after the processing are printed. In this way, when printing out, the near-term prescription value is printed separately from the distance prescription value. You can know it easily and accurately.
[0084]
In the above embodiment, the warning display for alerting the examiner of the possibility of intervention is not based on the objective value data, but is measured at the stage when the complete correction value for one eye is obtained. When the value is positive and the value is positive (similar to the above, it may be positive or weak), a message prompting attention such as “Is the adjustment sufficiently removed” is displayed. You can also. Further, in comparison with the inputted objective value data and anterior spectacle data, when the plus power of the complete correction value is reduced from the plus power of the inputted data (+ 1.50D → + 0) .50D, etc.), or if the negative data has changed to the positive side, a warning message may be displayed when the influence of the adjustment seems to be non-negligible. good. As a result, it is possible to trigger the examiner to determine whether or not a detailed inspection is necessary before the adjustment stage. These may be performed only when the age of a young person (for example, 15 years old or less) is input.
In addition, regardless of the input frequency data and measurement frequency, the age (below the age)LaIf you have entered your age (which can be set freely in the meter settings), you may display a notice that you should be careful about the intervention of the adjustment when you start the test (when you close the menu screen, etc.) You may display that it calls attention after calculating | requiring a correction value.
[0085]
【The invention's effect】
According to the present invention, even a person who is inexperienced and unfamiliar with optometry can easily obtain an appropriate prescription value.
[Brief description of the drawings]
FIG. 1 is an external view showing an overall configuration of an optometry apparatus according to an embodiment.
FIG. 2 is a diagram illustrating a slide mechanism and a turning mechanism of a lens unit.
FIG. 3 is a view of the controller 5 as viewed from above.
FIG. 4 is a block diagram illustrating control of the apparatus according to the embodiment.
FIG. 5 is a diagram illustrating a flowchart of an optometry program according to an embodiment.
FIG. 6 is a diagram showing an example of a setting menu screen displayed on the display.
FIG. 7 is a diagram showing an example of an age input screen.
FIG. 8 is a diagram showing an example of a screen at the start of a naked eye vision test.
FIG. 9 is a diagram showing an inspection flow of astigmatism inspection;
FIG. 10 is a flowchart illustrating an automatic adjustment program for distance correction power.
FIG. 11 is a flowchart illustrating an automatic adjustment program for distance correction power.
FIG. 12 is a flowchart illustrating an automatic adjustment program for distance correction power.
FIG. 13 is a flowchart illustrating an automatic adjustment program for distance correction power.
FIG. 14 is a flowchart illustrating an automatic adjustment program for distance correction power.
FIG. 15 is a flowchart illustrating an automatic adjustment program for distance correction power.
FIG. 16 is a diagram illustrating calculation of table A to table D for obtaining a correction amount for adjusting the correction power.
FIG. 17 is a diagram illustrating an example of a display screen after automatic adjustment;
FIG. 18 is a flowchart for explaining an adjustment program for manual adjustment.
FIG. 19 is a flowchart illustrating an adjustment program for manual adjustment.
FIG. 20 is a diagram illustrating a specific example of astigmatism adjustment for switch input when there is a sense of incongruity in manual adjustment E;
FIG. 21 is a diagram illustrating a display example when manual adjustment is performed with respect to the automatic adjustment frequency.
FIG. 22 is a diagram for explaining an operation instruction display when a necessary near work distance is input.
FIG. 23 is a diagram illustrating a print example.
[Explanation of symbols]
2 Awareness measuring device
5 Controller
31 Switch part
30 display
36 Feed switch
50 Microcomputer circuit
51, 52 memory

Claims (3)

The eye examination apparatus for obtaining refractive power of the eye based on the refractive power of the measured subject's eye, the adjustment of binocular perfect correction values of a subject obtained by binocular balance added to the subject Adjustment factor information for predicting the optimum prescription frequency, input means for inputting adjustment factor information including wearing spectacle data, binocular complete correction value and binocular complete correction value based on the adjustment factor information A prescription power predicting means that corrects the first prescription power and an optical element having a refractive power corresponding to the calculated first prescription power is placed in the optometry window in front of the eye to be examined, and the subject regarding the appearance And an adjusting means for further adjusting the first prescription power based on the response result to obtain a second prescription power with an appearance satisfying the subject . The prescription power predicting means according to claim 1 has at least two types of information relating to adaptability to the correction power change of the eye to be examined as the adjustment factor information . 2. The optometry apparatus according to claim 1, wherein the prescription power predicting means has different correction procedures based on whether or not there is astigmatism, oblique astigmatism, hyperopia or myopia in the obtained perfect correction power .

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