JP7369001B2 - ophthalmology equipment - Google Patents

Description

TECHNICAL FIELD The present invention relates to an ophthalmological device.

Conventionally, a face support part that supports the face of a subject, and a face position detection device that detects the position of the face with respect to the face support part are provided, and based on the position of the face detected by the face position detection device, Ophthalmological apparatuses that stop alignment operations are known (for example, see Patent Document 1).

JP 2018-38517 Publication

By the way, in conventional ophthalmological apparatuses, when alignment is completed and measurement is started, the face position is not detected because the measurement time is relatively short. However, measuring eye characteristics when the face is not properly supported may reduce measurement accuracy. That is, if the state in which the face is supported by the face support unit cannot be recognized during the measurement of eye characteristics, the examiner cannot grasp whether the measurement accuracy is ensured.

The present invention has been made in view of the above problem, and an object of the present invention is to provide an ophthalmologic apparatus that allows an examiner to measure ocular characteristics while grasping the support state of a subject's face.

In order to achieve the above object, the ophthalmological apparatus of the present invention includes an ophthalmological examination machine main body that measures the ocular characteristics of an eye to be examined, a face support section that is provided in the ophthalmological examination machine main body and supports the face of a subject, and the ophthalmological examination apparatus that a detection unit that continuously detects whether or not the face is supported by the face support unit while the eye characteristics are being measured by the optometry machine body; a notification unit that reports whether or not the face is supported by the face support unit based on the detection result; a display unit that displays the measurement result by the optometry machine body and the detection result by the detection unit in association with each other; It is characterized by having the following.

With the ophthalmological apparatus configured in this manner, the examiner can measure eye characteristics while grasping the support state of the subject's face.

1 is a perspective view showing the overall configuration of an ophthalmologic apparatus according to Example 1. FIG. It is an explanatory view showing a detection result by a detection part. (a) is an explanatory diagram showing a pressure detection position with the pressure sensor of Example 1, and (b) is an explanatory diagram showing the pressure detection direction with the pressure sensor of Example 1. FIG. 2 is an explanatory diagram showing the configuration of an operation controller. FIG. 2 is an explanatory diagram schematically showing a display screen of the operation controller of the ophthalmological apparatus of Example 1. FIG. 2 is an explanatory diagram schematically showing a screen showing measurement results of eye characteristics of an eye to be examined in the ophthalmological apparatus of Example 1. FIG.

EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing the ophthalmologic apparatus of this invention is demonstrated based on Example 1 shown in drawing.

(Example 1)
The configuration of the ophthalmologic apparatus 1 of Example 1 will be described below based on FIGS. 1 to 6.

The ophthalmologic apparatus 1 of Example 1 is a binocular open type ophthalmologic apparatus that can simultaneously measure ocular characteristics of both eyes with the subject's left and right eyes open. In addition, in the ophthalmological apparatus 1 of Example 1, it is also possible to measure the ocular characteristics of each eye by shielding one eye or turning off the fixation target. That is, the ophthalmologic apparatus of the present invention is not limited to a binocular open type, but can also be applied to an ophthalmologic apparatus that measures ocular characteristics for each eye.

As shown in FIG. 1, the ophthalmologic apparatus 1 of Example 1 includes a support base 10, a measurement unit 20 (optometry machine main body), and an operation controller 30 (operation section). In addition, as shown in FIG. 1 throughout this specification, the X-axis, Y-axis, and Z-axis are taken, and when viewed from the subject undergoing eye examination, the left and right direction is the X direction, and the up and down direction (vertical direction) is the Y direction. , the direction perpendicular to the X direction and the Y direction (the depth direction of the measurement unit 20) is defined as the Z direction.

The support base 10 has a column 11 that stands up from the floor, and an optometry table 12 that is supported by the column 11. The optometry table 12 is a stand on which devices and tools used for optometry, such as the operation controller 30, are placed, and for supporting the posture of the subject. The optometry table 12 may be supported by the support 11 so that its position in the Y direction (height position) can be adjusted.

The measurement unit 20 includes an arm 21, a measurement head 22, a forehead rest part 23 (face support part), and a measurement side control part 24. The arm 21 has one end supported by the tip of the column 11, the other end extending from the column 11 toward the front side (toward the subject) along the Z direction, and the measurement head 22 is attached to the tip. Thereby, the measurement head 22 is suspended from the support 11 via the arm 21 above the optometry table 12. Furthermore, the arm 21 is movable in the Y direction relative to the support column 11. Note that the arm 21 may also be movable in the X direction and the Z direction with respect to the support column 11.

The measurement head 22 includes a drive section 22a and a pair of left and right measurement sections 22R and 22L provided below the drive section 22a, and measures the ocular characteristics of the subject's eye. The right measuring section 22R and the left measuring section 22L form a pair to individually correspond to the left and right eyes of the subject. Here, the right measurement unit 22R has a built-in right measurement optical system 25R that measures the ocular characteristics of the right eye of the subject. The left measurement unit 22L has a built-in left measurement optical system 25L that measures the ocular characteristics of the left eye of the subject. The measurement results obtained by the measurement head 22 are input to the measurement-side control section 24 .

The drive unit 22a is a mechanism that individually drives the right measuring unit 22R and the left measuring unit 22L to move horizontally (in the X direction), drive to move vertically (in the Y direction), rotationally drive in the X direction, and rotationally drive in the Y direction.

The right measurement optical system 25R and the left measurement optical system 25L are an observation system for observing the anterior segment of the eye to be examined, a fixation target projection system for presenting a fixation target to the eye to be examined, and a measurement light irradiated to the fundus of the eye to be examined. It also has an objective measurement system that receives the reflected measurement light reflected by the fundus of the eye to be examined, a subjective measurement system that presents a subjective visual target to the eye to be examined, and the like.

Here, in the objective measurement system, in addition to objectively measuring the eye characteristics of the eye to be examined based on the result of reception of reflected light, photography is performed to obtain an image of the eye to be examined. In other words, the objective measurement system performs objective refraction measurement (reflex measurement), corneal topography measurement (keratometry), intraocular pressure measurement, fundus photography, and optical coherence tomography (hereinafter referred to as "OCT"). Perform tomographic imaging (OCT imaging) and measurements using OCT. Note that the objective measurement is performed not only during the objective measurement but also during the subjective measurement.

Furthermore, in the subjective measurement system, the ocular characteristics of the subject's eye are subjectively measured based on the subject's response to the presented optotype. That is, the subjective measurement system performs subjective refraction measurements such as distance vision tests, near vision tests, contrast tests, and glare tests, and visual field tests.

The forehead rest part 23 is arranged between the right measurement part 22R and the left measurement part 22L, and is provided in the measurement unit 20. The forehead rest part 23 supports the subject's face by bringing a part of the subject's face (forehead) into contact during measurement of eye characteristics. That is, the subject directly facing the optometry table 12 presses his or her forehead against the forehead rest 23 to stabilize the direction and position of the face so that it does not move. The position of the forehead rest 23 is adjusted by moving the arm 21 in the Y direction relative to the support 11. A pressure sensor 26 (detection section) is provided on the surface of the forehead rest section 23 that contacts the forehead of the subject.

As shown in FIG. 2, the pressure sensor 26 detects the pressure P exerted on the forehead rest part 23 by the forehead of the subject, and the face of the subject is adjusted to the forehead rest part 23 based on the value of the detected pressure P. This is a sensor that detects whether or not it is supported by. The detection result by the pressure sensor 26 is input to the measurement side control section 24.

The pressure sensor 26 continuously detects the pressure P acting on the forehead rest 23 while measuring the eye characteristics of the eye to be examined. That is, the pressure sensor 26 continues to detect whether the subject's forehead is in contact with the forehead rest 23, that is, whether the subject's face is supported by the forehead rest 23. Here, "while measuring the ocular characteristics of the eye to be examined" includes, for example, not only while performing objective refraction measurement and subjective refraction measurement, but also while taking images of the eye to be examined, and when performing alignment. This includes while you are there.

The pressure sensor 26 detects that the subject's face is supported by the forehead rest 23 when the pressure P detected by the pressure sensor 26 is higher than a preset threshold value P ^* . That is, in the example shown in FIG. 2, it is detected that "the subject's face is supported by the forehead rest 23" from time t ₀ to t ₁ and after time t ₂ . Further, from time t ₁ to time t ₂ , it is detected that "the subject's face is not supported by the forehead rest 23".

Further, as shown in FIG. 3(a), this pressure sensor 26 has a sheet shape that covers almost the entire surface of the forehead rest 23, and is placed at a plurality of different positions on the forehead rest 23 (position A, The pressure P acting on the forehead rest 23 at the position B etc.) can be detected. In this case, the pressure sensor 26 determines whether the subject's face is supported by the forehead rest 23 based on the pressure P detected at a plurality of different positions (position A, position B, etc.) on the forehead rest 23. It is possible to detect whether this is the case.

Furthermore, as shown in FIG. 3(b), the pressure sensor 26 can detect the pressure P acting on the forehead rest 23 in a plurality of different directions (arrow α, arrow β, etc.) from an arbitrary position C. I can do it. In this case, the pressure sensor 26 detects whether the subject's face is supported by the forehead rest 23 based on the pressure P acting on the forehead rest 23 in a plurality of different directions (arrow α, arrow β, etc.). It is possible to detect whether or not the

The measurement side control section 24 is an information processing device provided below the optometry table 12, and centrally controls each section of the measurement unit 20 based on a control signal transmitted from the operation controller 30. The measurement-side control unit 24 also receives the measurement results of the eye characteristics of the subject's eye measured by the measurement head 22 and the detection results of the state of support of the subject's face by the forehead rest 23 detected by the pressure sensor 26. It is transmitted to the operation controller 30.

The “detection result regarding the support state of the subject's face” is the detection result by the pressure sensor 26 as to whether or not the subject's face is supported by the forehead rest part 23 . Note that when the pressure sensor 26 detects whether or not the subject's face is supported based on the pressure P detected at a plurality of different positions (position A, position B, etc.) on the forehead rest part 23, The measurement-side control unit 24 analyzes the difference in detection position and the difference in pressure P to estimate the inclination of the subject's face. Information generated based on the estimated facial inclination is then transmitted to the operation controller 30 as "detection results regarding the support state of the subject's face." Further, when the pressure sensor 26 detects whether or not the subject's face is supported based on the pressure P acting on the forehead rest 23 in a plurality of different directions (arrow α, arrow β, etc.), In this case, the measurement-side control unit 24 analyzes the difference in detection direction and the difference in pressure P to estimate the inclination of the subject's face. Information generated based on the estimated facial inclination is then transmitted to the operation controller 30 as "detection results regarding the support state of the subject's face."

Furthermore, the measurement-side control unit 24 includes a storage unit 24a that stores the measurement results by the measurement head 22 and the detection results by the pressure sensor 26 in a time-series manner in association with each other. Here, "measurement results" include the measurement type of objective measurement or subjective measurement, the objective measurement value (spherical power, cylinder power, cylinder axis), the type of visual target presented at the time of subjective measurement, and the subjective measurement. It includes measurement conditions (spherical power, cylindrical power, cylindrical axis). Based on the control signal from the operation controller 30, the measurement side control section 24 reads out the measurement results and detection results for a predetermined period stored in the storage section 24a, and transmits them to the operation controller 30.

The operation controller 30 is an information processing device that accepts operations by the examiner and outputs control signals to the measurement-side control section 24 of the measurement unit 20. This operation controller 30 is, for example, a tablet terminal or a smartphone, and is separated from the measurement unit 20 and can be carried by the examiner. Note that the operation controller 30 may be a notebook personal computer, a desktop personal computer, or the like, or may be a controller dedicated to the ophthalmologic apparatus 1. The operation controller 30 exchanges information with the measurement-side control unit 24 via wireless communication or network communication. That is, the operation controller 30 can communicate with the measurement unit 20 and the pressure sensor 26 via the measurement-side control section 24.

As shown in FIG. 4, the operation controller 30 includes a display section 31 and an operation-side control section 32. The display unit 31 consists of a touch panel display provided on the surface of the operation controller 30. The display unit 31 includes a display surface 31a on which images and the like are displayed, and a plurality of touch panel type input buttons 31b arranged in an overlapping manner on the display surface 31a. The operation side control unit 32 is composed of a microcomputer built into the operation controller 30. The operation side control section 32 includes an image control section 32a that controls an image to be displayed on the display surface 31a based on the measurement results and detection results sent from the measurement side control section 24, and a control signal corresponding to the operation on the input button 31b. and a signal control section 32b that outputs the signal to the measurement-side control section 24.

In the operation controller 30, when the examiner taps a predetermined input button 31b, a predetermined control signal is transmitted from the signal control section 32b to the measurement-side control section 24. The measurement side control unit 24 controls the measurement unit 20 and the pressure sensor 26 based on the received control signal, and measures eye characteristics such as arbitrary objective measurement and subjective measurement, alignment, and support state of the subject. Detection, etc. are performed. Further, when the measurement of the eye characteristics is performed by the measurement head 22, the measurement-side control section 24 transmits the measurement results and the detection results by the pressure sensor 26 to the operation-side control section 32 of the operation controller 30. The image control unit 32a displays, for example, a predetermined screen as shown in FIG. 5 on the display surface 31a based on the received measurement results. In addition, the display surface 31a shown in FIG. 5 shows schematic diagrams 40R and 40L of the fixation target presented to the eye to be examined, a horizontal cross-sectional view of the eye to be examined, and a visual axis and an optical axis of the measurement optical system. Schematic diagrams 41R and 41L, anterior segment images ER and EL, schematic diagrams 42R and 42L showing the light guide center and the position of corneal reflection, objective refractive power 43, and the like are displayed.

Furthermore, the image control section 32a controls the luminescent color of the icon 44 (notification section) displayed on the display surface 31a based on the detection result of the pressure sensor 26 detected during the eye measurement. That is, the icon 44 reports information as to whether or not the forehead of the subject is supported by the forehead support section 23 based on the detection result of the pressure sensor 26. When the pressure sensor 26 detects that "the subject's face is supported by the forehead rest 23", the image control unit 32a causes the icon 44 to emit light in green. Furthermore, when the pressure sensor 26 detects that "the subject's face is not supported by the forehead rest 23", the image control unit 32a causes the icon 44 to emit red light.

Further, the image control unit 32a continues to cause the icon 44 to emit light while the measurement unit 20 is measuring the eye characteristics of the subject's eye, and continuously notifies the detection results of the pressure sensor 26 while the eye characteristics are being measured. Note that if the detection result changes due to a change in the posture of the subject during the measurement of the eye characteristics, the image control unit 32a changes the luminescent color of the icon 44 at the timing when the detection result changes. Further, the image control section 32a only controls the light emission of the icon 44 based on the detection result of the pressure sensor 26, and does not affect the measurement operation of the measurement unit 20 in any way.

Further, for example, when the examiner taps the log button 31c, which is one of the input buttons 31b arranged on the display surface 31a of the operation controller 30, a predetermined control signal is sent from the operation controller 30 to the measurement side control unit 24. sent to. The measurement-side control unit 24 reads the measurement results and detection results for a predetermined period stored in the storage unit 24a, and transmits them to the operation controller 30. The image control unit 32a displays a log display screen 100 shown in FIG. 6 on the display surface 31a based on the measurement results and detection results for a predetermined period transmitted from the measurement-side control unit 24.

The log display screen 100 is a screen that displays measurement results and detection results read out from the storage unit 24a in parallel over a predetermined period of time. In the example shown in FIG. 6, the horizontal axis is the time axis of a predetermined period, and the measurement results and detection results are displayed side by side along the vertical axis. This log display screen 100 includes a support state display section 101, a measurement type display section 102, an optotype display section 103, a measurement condition display section 104, a spherical power display section 105, a cylindrical power display section 106, and a cylindrical power display section 106. It has an axis display section 107.

The support state display section 101 displays a time period in which the subject's face is supported by the forehead rest part 23 and a time period in which the subject's face is not supported by the forehead rest part 23. That is, when the log display screen 100 is displayed, the support state display section 101 reports information as to whether or not the forehead of the subject is supported by the forehead support section 23 based on the detection result of the pressure sensor 26. Became the information department. In FIG. 6, a time period in which the subject's face is supported by the forehead rest part 23 is shown by a white band, and a time period in which the subject's face is not supported by the forehead rest part 23 is shown by a diagonal line.

The measurement type display section 102 displays the time period in which the objective measurement was performed and the time period in which the subjective measurement was performed. The optotype display unit 103 displays the type of optotype presented to the subject during the subjective measurement for each time period. The measurement condition display section 104 displays the values of the spherical power (S), cylindrical power (C), and cylindrical axis (A) of the lens placed in front of the subject's eye during subjective measurement for each time period. The spherical power display section 105 displays the value of the spherical power (S) of the subject's eye measured during objective measurement and subjective measurement within a predetermined period. The cylindrical power display section 106 displays the value of the cylindrical power (C) of the subject's eye measured during the objective measurement and subjective measurement within a predetermined period. The value of the cylindrical axis (A) of the subject's eye measured during the subjective measurement is displayed.

Furthermore, a cursor 108 that can be moved to any position along the time axis (horizontal axis) is displayed on the log display screen 100. The examiner can move the cursor 108 by pressing his or her finger against it and moving it. The examiner sets the cursor 108 to an arbitrary position on the time axis and taps the execution button 109. As a result, a control signal linking various measurement conditions and the operation of the measurement head 22 at the timing when the cursor 108 is set is transmitted from the operation controller 30 to the measurement-side control unit 24. The measurement side control section 24 controls each section of the measurement head 22 based on the received control signal. Thereby, the measurement head 22 reproduces the measurement operation at the timing when the cursor 108 was set.

Hereinafter, the effects of the ophthalmologic apparatus 1 of Example 1 will be explained.

To measure eye characteristics using the ophthalmological apparatus 1 of Example 1, first, at the start of measuring eye characteristics, the examinee presses his or her forehead against the forehead rest part 23 according to the examiner's instructions, and then presses his/her face against the forehead rest 23. stabilize. At this time, the pressure sensor 26 provided in the forehead rest 23 detects the pressure P acting on the forehead rest 23, and based on the value of the detected pressure P, the subject's face is supported by the forehead rest 23. detect whether or not the When the support state of the subject's face is detected by the pressure sensor 26, the detection result is transmitted from the measurement-side control unit 24 to the operation controller 30.

The operation controller 30 receives the detection result of the pressure sensor 26 transmitted from the measurement-side control unit 24. The image control unit 32a controls the luminescent color of the icon 44 displayed on the display surface 31a of the operation controller 30 based on the received detection result. Thereby, whether or not the forehead of the subject is supported by the forehead rest part 23 is notified by the luminescent color of the icon 44. The image control unit 32a continues to control the emitted light color of the icon 44 after starting the measurement of the eye characteristics, and continuously reports the detection information of the pressure sensor 26.

Then, the examiner performs alignment to align the measurement optical axes of the right measurement section 22R and the left measurement section 22L with the pupil centers and corneal vertices of the left and right eyes to be examined, respectively. At this time, the examiner visually recognizes the icon 44 and confirms the luminescent color of the icon 44 to perform alignment while checking whether or not the subject's forehead is in contact with the forehead rest part 23. I can do it. Therefore, if the examinee releases his or her forehead from the forehead rest part 23 during alignment, the examiner can quickly understand that the examinee's face is not supported appropriately. Then, it is possible to determine whether to continue the alignment as it is, or to interrupt the alignment and encourage the subject to make forehead contact. Note that alignment may be performed automatically, or the alignment amount may be set manually. After completing the alignment, the examiner measures the ocular characteristics of the eye to be examined.

In the measurement of eye characteristics, first, the objective eye refractive power is measured using an objective measurement system, and based on this result, the subjective eye refractive power is measured using a subjective measurement system. conduct. A known method is used to measure the refractive power of each eye. During all of these measurement periods, the pressure sensor 26 detects the pressure P acting on the forehead rest 23 and determines whether the subject's face is supported by the forehead rest 23 based on the detected pressure P value. The detection result is sent to the operation controller 30. The image control unit 32a changes the luminescent color of the icon 44 displayed on the display surface 31a of the operation controller 30 based on the received detection result, and determines whether the forehead of the subject is supported by the forehead support unit 23. is notified by the color of the icon 44.

As a result, the examiner can grasp whether or not the subject's face is supported by the forehead rest part 23 by visually recognizing the luminescent color of the icon 44 even during the measurement of eye characteristics. It is possible to perform measurements while recognizing the support state of the face in real time. Further, the image control section 32a only controls the light emission of the icon 44 based on the detection result of the pressure sensor 26, and does not affect the measurement operation of the measurement unit 20 in any way. Therefore, even if it is detected that the subject's face is not supported by the forehead rest 23, the examiner can decide whether to continue or interrupt the measurement, and the examiner is not required. It is possible to avoid interruptions in measurement and reduce troublesomeness during measurement.

Furthermore, the icon 44 is provided on the display surface 31a of the operation controller 30. Here, the operation controller 30 is separated from the measurement unit 20 and is capable of communicating with the measurement unit 20 and the pressure sensor 26 via the measurement-side control section 24, and receives an operation by the examiner and controls the measurement-side control section 24. It outputs a control signal to the Therefore, the examiner who performs the measurement of the eye characteristics of the eye to be examined can easily recognize the icon 44 and can quickly make a decision to continue or interrupt the measurement.

Further, during the measurement of the eye characteristics, the operation controller 30 displays the icon 44 on the display surface 31a and at the same time displays the measurement results (schematic diagrams 40R, 40L, etc.) by the measurement unit 20, as shown in FIG. That is, the display unit 31 of the operation controller 30 displays the measurement result by the measurement unit 20 and the detection result by the pressure sensor 26 in association with each other. Thereby, the examiner can recognize the luminescent color of the icon 44 while checking the measurement results. Therefore, the examiner must consider whether the measurement accuracy of the measurement result is guaranteed, taking into account the timing of the measurement when the forehead leaves the forehead rest part 23, the time the forehead is away from the forehead rest part 23, etc. It is possible to accurately estimate whether or not this is the case. Therefore, it is possible to more appropriately determine whether to continue or interrupt measurement.

Furthermore, in the first embodiment, the measurement-side control section 24 includes a storage section 24a that stores the measurement results by the measurement unit 20 and the detection results by the pressure sensor 26 in association with each other. Then, when the examiner taps the log button 31c, the measurement results and detection results associated with each other are read out from the storage unit 24a, and the log display screen 100 shown in FIG. 6 is displayed on the display surface 31a of the display unit 31. . As a result, the examiner can check the measurement result by the measurement unit 20 and the state of support of the subject's head at the time the measurement result was obtained, after the eye measurement is completed or at any time during the measurement. can be checked retrospectively. Then, it becomes possible to reproduce the measurement conditions and perform re-measurement if necessary.

In particular, in the first embodiment, a cursor 108 is displayed on the log display screen 100. Then, the user moves the cursor 108 to an arbitrary position along the time axis (horizontal axis), sets it at an arbitrary position on the time axis, and taps the execution button 109. As a result, a control signal linking various measurement conditions at the timing when the cursor 108 is set and the operation of the measurement head 22 is transmitted from the operation controller 30 to the measurement-side control unit 24. Then, in the measurement head 22, the measurement operation at the timing when the cursor 108 was set is reproduced. Therefore, it is possible to easily reproduce the measurement conditions and perform re-measurement, and it is possible to improve the efficiency of eye measurement. Furthermore, since the measurement conditions are automatically reproduced, no setting errors occur and re-measurement can be performed appropriately.

In the ophthalmological apparatus 1 of Example 1, the measurement unit 20 presents a subjective optotype to the eye to be examined, and subjectively measures the optical characteristics of the eye to be examined based on the response of the examinee. It has a system. In contrast, the ophthalmologic apparatus 1 can continuously notify the patient's head support state even during subjective measurement. Therefore, even in subjective measurements where the state of support of the subject's face tends to affect the content of the response and the measurement accuracy tends to fluctuate depending on the state of support of the subject's face, it is difficult to estimate the measurement accuracy appropriately. , accurate measurements can be made.

In the first embodiment, whether or not the subject's face is supported by the forehead rest 23 is determined based on the pressure P detected at a plurality of different positions (position A, position B, etc.) on the forehead rest 23. When the detection is based on the detection position, the measurement-side control unit 24 analyzes the difference in detection position and the pressure difference to estimate the inclination of the subject's face. Information generated based on the estimated facial inclination is then transmitted to the operation controller 30 as "detection results regarding the support state of the subject's face." Therefore, the emitted light color of the icon 44 can be controlled according to the detection result based on the inclination of the face estimated by analyzing the difference in detection position and the pressure difference, and it becomes possible to perform more appropriate notification.

Furthermore, in the first embodiment, whether or not the subject's face is supported by the forehead rest 23 is determined by the pressure P acting on the forehead rest 23 in a plurality of different directions (arrow α, arrow β, etc.). In the case of detection based on , the measurement-side control unit 24 analyzes the difference in detection direction and the pressure difference to estimate the inclination of the subject's face. Information generated based on the estimated facial inclination is then transmitted to the operation controller 30 as "detection results regarding the support state of the subject's face." Therefore, the emitted light color of the icon 44 can be controlled according to the detection result based on the inclination of the face estimated by analyzing the difference in detection direction and the pressure difference, and it becomes possible to perform more appropriate notification.

In the ophthalmological apparatus 1 of the first embodiment, an icon 44 is displayed on the display surface 31a of the operation controller 30, and whether or not the subject's face is supported by the forehead rest 23 is determined based on the emitted light color of the icon 44. The structure was designed to notify the public. Thereby, the examiner can easily understand whether or not the subject's face is supported by recognizing the difference in the emitted light color of the icon 44.

Although the ophthalmological apparatus 1 of the present invention has been described above based on Example 1, the specific configuration is not limited to this example, and the invention according to each claim Changes and additions to the design are permitted as long as they do not deviate from the gist.

In the ophthalmological apparatus 1 according to the first embodiment, an example is shown in which it is notified whether or not the subject's face is supported by the luminescent color of the icon 44 displayed on the display surface 31a of the operation controller 30. However, it is not limited to this. For example, the operating controller 30 may be provided with a speaker, and the state of support of the face by the forehead rest 23 may be notified by the sound output from the speaker. Further, the operation controller 30 may be provided with a light source such as an LED, and the state of support of the face by the forehead rest 23 may be notified by controlling the color of the light emitted from the light source. Further, characters may be displayed on the display surface 31a to notify the user of the state of support of the face by the forehead rest 23. Furthermore, as shown in FIG. 6, for example, a bar area is displayed on the display unit 31 along the time axis, and a time period in which the face is not supported by the forehead rest part 23 is different from a time period in which the face is supported. The support state of the face by the forehead rest part 23 may be notified by indicating in color.

Furthermore, when notifying the support status of the face with voice or text, it is not just a continuous notification of whether or not the subject's face is supported, but also instructions based on the detection results (for example, "Strongly press the forehead. "Please guess," or "Please face the front," etc.) may be notified as appropriate.

Further, in the ophthalmological apparatus 1 of the first embodiment, an example was shown in which the operation controller 30 that receives the examiner's operation and outputs a control signal to the measurement unit 20 is separated from the measurement unit 20 and made portable. Not limited to. For example, the operation controller 30 and the measurement unit 20 may be provided in the same housing. Even in this case, by providing the icon 44 (notification section) on the operation controller 30 that accepts operations from the examiner, the examiner can easily grasp the state in which the examinee's face is supported by the forehead rest section 23. be able to.

Although the ophthalmologic apparatus 1 of the first embodiment includes the forehead rest part 23 that comes into contact with the forehead of the subject as a face support part that supports the face of the subject, the present invention is not limited to this. For example, the face support may be a chin rest that contacts and supports the chin of the subject, or a ring-shaped frame provided with a forehead rest and a chin rest may be used as the face support. In other words, the face support part can be used as a forehead rest if the subject's face comes into contact with the subject and prevents the position of the subject's face and the subject's eyes from moving during measurement of the ocular characteristics of the subject's eye. 23 or a chin rest.

Furthermore, in the ophthalmological apparatus 1 of Example 1, an example was shown in which the pressure sensor 26 detects whether or not the subject's face is supported by the forehead rest part 23 (face support part). However, it is not limited to this. For example, a distance sensor provided in the measurement unit 20 measures the distance from the measurement unit 20 to the subject's face, and based on this distance, the subject's face is supported by the forehead rest part 23 (face support part). It may also be possible to detect whether the Further, the face of the subject whose eye characteristics are being measured is photographed by a camera provided in the measurement unit 20, and the face of the subject is supported by the forehead rest part 23 (face support part) based on this photographed image. It may also be possible to detect whether the In other words, the detection unit may be one that continuously detects whether or not the subject's face is supported during the measurement of the eye characteristics of the subject's eye.

Furthermore, in the first embodiment, the pressure sensor 26 detects the pressure P acting on the forehead rest 23 and determines whether the subject's face is supported by the forehead rest 23 based on the value of the detected pressure P. An example of detecting whether or not the However, it is not limited to this. For example, the pressure sensor 26 only detects the pressure P acting on the forehead rest 23, and the measurement-side control unit 24, the image control unit 32a of the operation controller 30, etc. detects the support of the face based on the pressure value. It's okay. In this case, in addition to the pressure sensor 26, a control unit that detects whether or not the subject's face is supported based on the pressure value also corresponds to the “detection unit”.

1 Ophthalmology device 20 Measurement unit (optometry machine body)
22 Measuring head 22L Left measuring part 22R Right measuring part 23 Forehead rest part 25 Pressure sensor (detecting part)
26 Measurement side control section 26a Storage section 30 Operation controller (operation section)
31 Display section 31a Display surface 32 Operating side control section 32c Notification control section 44 Icon (notification section)

Claims (6)

An optometry machine body that measures the eye characteristics of the eye to be examined;
a face support part that is provided on the eye examination machine body and supports the face of the subject;
a detection unit that continuously detects whether or not the face is supported by the face support unit during the measurement of the eye characteristics by the optometry machine main body;
a notification unit that makes a predetermined notification based on the detection result of the detection unit during the measurement of the eye characteristics by the optometry machine main body;
a display unit that displays a measurement result by the optometry machine main body and a detection result by the detection unit in association with each other;
An ophthalmological device comprising: The ophthalmological device according to claim 1,
an operation section that is separated from the optometry machine main body, is capable of communicating with the optometry machine main body and the detection section, receives an operation by an examiner, and outputs a control signal to the optometry machine main body;
The ophthalmologic apparatus, wherein the notification section is provided in the operation section. The ophthalmological device according to claim 1 or 2,
An ophthalmological apparatus comprising: a storage unit that stores measurement results by the optometry machine body and detection results by the detection unit in association with each other. The ophthalmological device according to any one of claims 1 to 3,
The optometry machine body has a subjective measurement system that presents a subjective visual target to the eye to be examined and subjectively measures the optical characteristics of the eye to be examined based on the response of the examinee.
An ophthalmological device characterized by: The ophthalmological device according to any one of claims 1 to 4,
The detection unit detects whether the face is supported by the face support unit from different positions of the face support unit or from different angles with respect to the face support unit.
An ophthalmological device characterized by: The ophthalmological device according to any one of claims 1 to 5,
The notification unit notifies the detection result using at least one of an icon displayed on the screen, light, and sound.
An ophthalmological device characterized by: