阅读说明：本技术 验光装置 (Optometry device ) 是由 边光春 后藤佳人 于 2019-09-11 设计创作，主要内容包括：本公开的一个方面的验光装置具备支撑结构、照明光源、观察光学系统、以及控制部。支撑结构被构造成支撑受检者的脸部。照明光源被构造成照亮受检眼。观察光学系统具备被构造成接收来自受检眼的反射光的摄像元件。控制部从摄像元件获取第一图像以及第二图像,并基于第一图像和第二图像之间的差异来判定受检者的脸部是否放置在支撑结构上,其中,该第一图像是在照明光源点亮期间拍摄的图像,该第二图像是在照明光源熄灭期间拍摄的图像。(An optometry apparatus according to an aspect of the present disclosure includes a support structure, an illumination light source, an observation optical system, and a control unit. The support structure is configured to support a face of a subject. The illumination source is configured to illuminate the eye. The observation optical system includes an image pickup element configured to receive reflected light from the eye to be inspected. The control section acquires a first image and a second image from the image pickup element, and determines whether the face of the subject is placed on the support structure based on a difference between the first image and the second image, wherein the first image is an image captured during the lighting of the illumination light source, and the second image is an image captured during the lighting of the illumination light source.)

1. An optometry apparatus comprising:

a support structure configured to support a face of a subject;

an illumination light source configured to illuminate an eye of the subject, i.e., a subject eye;

an observation optical system for observing the eye and including an image pickup element configured to receive reflected light from the eye; and

a control part for controlling the operation of the display device,

the control section turns on and off the illumination light source,

the control portion acquires a first image from the image pickup element, the first image being an image captured by the image pickup element during a period in which the illumination light source is turned on, and acquires a second image from the image pickup element, the second image being an image captured by the image pickup element during a period in which the illumination light source is turned off, and

the control portion determines whether the face of the subject is placed on the support structure based on a difference between the first image and the second image.

2. Optometric instrument of claim 1,

the control section determines whether the face of the subject is placed on the support structure based on a difference in luminance between the first image and the second image.

3. Optometric instrument of claim 2,

the control portion determines that the face of the subject is placed on the support structure when a difference in luminance between the first image and the second image is a reference value or more, and determines that the face of the subject is not placed on the support structure when the difference in luminance is less than the reference value.

4. Optometric device of any one of claims 1 to 3,

a drive system for changing the relative position of the observation optical system with respect to the support structure is provided,

the control section controls the drive system to align the observation optical system with the eye to be inspected, under a condition that it is determined that the face of the subject is placed on the support structure.

5. Optometric instrument of claim 4,

the control unit detects a pupil position of the eye based on an image captured by the image pickup device while the illumination light source is turned on, and controls the drive system based on the pupil position to align the observation optical system with the eye.

6. Optometric instrument of claim 4 or 5,

a position detection system that irradiates light to the cornea of the eye to be examined and receives reflected light from the cornea of the eye to be examined to detect a position of a vertex of the cornea,

the control section gradually aligns the observation optical system with the eye to be inspected by performing a coarse alignment process and a fine alignment process,

the coarse alignment process includes the following processes:

under a condition that it is determined that the face of the subject is placed on the support structure, a pupil position of the eye to be examined is detected based on an image taken by the image pickup element while the illumination light source is turned on, and

controlling the drive system based on the detected pupil position to align the observation optical system with the eye to be examined,

the fine alignment process is performed after the coarse alignment process,

the fine alignment process includes a process of, i.e.,

controlling the drive system based on the position of the corneal vertex obtained from the position detection system to align the observation optical system with the eye to be inspected.

Technical Field

The present disclosure relates to optometry equipment.

Background

The optometric device as disclosed in japanese patent laid-open No. 2000-254098 is configured to detect a subject. In a known optometric instrument, index light is emitted by blinking a light emitting element at a predetermined frequency. A light receiving signal from the light receiving element is input to the bypass circuit. A signal having a predetermined frequency is selectively extracted from the light reception signal by a bypass circuit. When a subject is present, a component of index light reflected from the subject is extracted. The optometric instrument determines whether a subject is present based on the extraction signal.

There is also known an optometric apparatus provided with a sensor for determining whether or not a subject is present on a mandibular stage on which a face of the subject is placed.

Disclosure of Invention

Conventional apparatuses include a physical structure such as a dedicated circuit for detecting a subject and not directly related to optometry.

Here, according to an aspect of the present disclosure, it is desirable to provide an optometric apparatus capable of inspecting a subject using a configuration for optometry.

An optometry apparatus according to an aspect of the present disclosure includes a support structure, an illumination light source, an observation optical system, and a control unit. The support structure is configured to support a face of a subject. The illumination light source is configured to illuminate an eye of a subject, i.e., an eye under examination. The observation optical system includes an image pickup element configured to receive reflected light from the eye to be inspected. The viewing optics are arranged as an eye for viewing the eye to be examined.

The control portion is configured to turn on or off the illumination light source. The control section is configured to acquire a first image from the image pickup element, the first image being an image captured by the image pickup element during lighting of the illumination light source. The control section is configured to acquire a second image from the image pickup element, the second image being an image captured by the image pickup element during a period in which the illumination light source is turned off. And the control portion is configured to determine whether the face of the subject is placed on the support structure based on a difference between the first image and the second image.

According to this optometry apparatus, it is possible to determine whether or not the face of the subject is placed on the support structure by the illumination light source for optometry and the observation optical system.

According to an aspect of the present disclosure, the control portion may determine whether the face of the subject is placed on the support structure based on a difference in luminance between the first image and the second image.

According to an aspect of the present disclosure, the control section may determine that the face of the subject is placed on the support structure when a difference in luminance between the first image and the second image is a reference value or more, and may determine that the face of the subject is not placed on the support structure when the difference in luminance is less than the reference value.

According to one aspect of the present disclosure, an optometric instrument may be provided with a drive system for changing the relative position of a viewing optical system with respect to a support structure. The control section may control the driving system to align the observation optical system with the eye to be inspected, on a condition that it is determined that the face of the subject is placed on the support structure.

According to an aspect of the present disclosure, the control section may detect a pupil position of the eye based on an image captured by the image pickup element during lighting of the illumination light source, and control the driving system to align the observation optical system with the eye based on the pupil position.

According to an aspect of the present disclosure, an optometry apparatus may include a position detection system that detects a position of a corneal vertex by irradiating light to a cornea of an eye to be examined and receiving reflected light from the cornea of the eye to be examined. The control section may gradually align the optical system with the eye to be inspected by performing the coarse alignment process and the fine alignment process.

The rough alignment process may include a process of detecting a pupil position of the eye to be inspected based on an image captured by the image pickup element during lighting of the illumination light source under a condition that it is determined that the face of the subject is placed on the support structure, and controlling the driving system based on the detected pupil position to align the observation optical system with the eye to be inspected.

The fine alignment process may include a process of controlling the driving system based on the position of the corneal vertex obtained from the position detecting system to align the observation optical system with the eye to be inspected. The fine alignment process may be performed after the coarse alignment process.

Drawings

Fig. 1 is a diagram showing an external configuration of an optometric instrument.

Fig. 2 is a block diagram showing the internal configuration of the optometric instrument.

Fig. 3 is a diagram showing the configuration of an optical system.

Fig. 4 is a flowchart of the alignment process performed by the control device.

Fig. 5 is an explanatory diagram about luminance.

Fig. 6A and 6B are explanatory diagrams of a method of detecting the position of the eye in the Z direction based on the distance between the reflection points of the light source.

Detailed Description

Exemplary embodiments which are examples of the present disclosure are described below with reference to the accompanying drawings.

The optometric instrument 1 of the present embodiment shown in fig. 1 is configured to function as a pachymeter for measuring the corneal thickness of an eye to be examined E and a tonometer for measuring the intraocular pressure. The optometric instrument 1 includes a head portion 3, a body portion 5, a support structure 7, and a display 9.

The head 3 is attached to the body 5 so as to be movable in XYZ (left-right, up-down, front-back) directions relative to the body 5. The support structure 7 is configured to support the face of the subject, particularly the lower jaw of the subject, and is fixed to the body portion 5. The display 9 is provided at a rear portion in the head 3 on the side of the head 3 opposite to the front portion facing the subject.

At the time of refraction, the face of the subject is placed on the support structure 7. The position of the eye to be examined E is stabilized by supporting the face of the subject by the support structure 7. Further, in the optometry, the head 3 is moved relative to the body 5 in XYZ directions, and the optical system incorporated in the head 3 is aligned with the eye E.

As shown in fig. 2, the head 3 includes an alignment optical system 100, an observation optical system 300, a fixation optical system 400, a first measurement optical system 500, and a second measurement optical system 600 as the above optical systems.

The main body 5 includes a control device 700, a storage device 710, an XYZ drive system 720, and an operating system 740. The control device 700 is configured to perform overall control of the entire optometric instrument 1 and process measurement data of the eye E.

The control device 700 includes, for example, a processor 701 and a memory 703. The processor 701 is configured to execute processing in accordance with a computer program stored by the storage device 710.

The processing performed by the control device 700 described below may be understood as being realized by the processor 701 executing the processing in accordance with a computer program. The storage device 710 is constructed of a nonvolatile memory such as a flash memory, which can electrically rewrite data.

The XYZ drive system 720 is configured to cause the head 3 to perform relative movement in the XYZ directions with respect to the main body 5 based on instructions from the control device 700. The operating system 740 includes a joystick 741 for receiving an operation from an examiner.

Further, a touch panel (not shown) that is a part of the operating system 740 may be provided on the screen of the display 9. The display 9 is configured to be controlled by the control device 700 to display an image of the eye E to be examined and various information such as the measured intraocular pressure and corneal thickness to the examiner.

As shown in fig. 3, the alignment optical system 100 built in the head 3 includes a light source 101, a hot mirror 102, an objective lens 103, and a hot mirror 104. The light source 101 is configured to output aiming light.

Alignment light from the light source 101 is reflected by the hot mirror 102, passes through the objective lens 103, is reflected by the hot mirror 104, and then passes through the observation port 200 and is irradiated toward the cornea of the eye E. The light source 101 is, for example, an LED that outputs infrared light.

The observation port 200 includes a nozzle 201 and a flat glass 205. The nozzle 201 includes a transparent window member 201a facing the eye E and an opening 201 c. The opening portion 201c is configured as an injection path of the compressed air, and an injection port 201b is formed in the center of the window member 201 a.

When measuring the intraocular pressure, compressed air is sent from the ejection port 201b to the eye E through the opening 201 c. The alignment light reflected by the hot mirror 104 is irradiated to the eye E through the flat glass 205 of the observation port 200 and the opening 201c of the nozzle 201.

Light reflected by the cornea of the eye E to be examined propagates within the observation optical system 300 disposed on the main optical axis O1. The observation optical system 300 includes a two-dimensional imaging element 306. The light reflected by the cornea of the eye E is received by a two-dimensional image pickup device (CCD) 306. Thereby, the reflected light corresponding to the alignment light is captured by the two-dimensional imaging element 306.

The control device 700 processes an image signal from the two-dimensional image sensor 306 including a captured image of the reflected light. The control device 700 detects the position of the corneal vertex of the eye E in the XY direction based on the reflected light included in the image signal. Thus, the alignment optical system 100 and the observation optical system 300 function as a position detection system.

The XYZ drive system 720 moves the head 3 based on the detected position of the eye E in the XY directions to align the head 3 with the eye E in the XY directions.

The observation optical system 300 further includes a light source 301, a light source 302, an objective lens 303, a dichroic mirror 304, and an imaging lens 305. The light source 301 and the light source 302 are provided to illuminate the anterior ocular region of the eye E. The light source 301 and the light source 302 employ LEDs that output infrared light having a wavelength smaller than that of the light source 101 for alignment. Hereinafter, the light from the light source 301 and the light source 302 is referred to as observation light.

Observation light from the light source 301 and the light source 302 is reflected by the eye E. The reflected light passes through the hot mirror 104, passes through the objective lens 303, the dichroic mirror 304, and the imaging lens 305, and is received by a two-dimensional image pickup element (CCD) 306. By this light receiving operation, the anterior ocular region of the eye E is imaged by the two-dimensional imaging element 306. An image signal representing a captured image is output from the two-dimensional image pickup element 306. The control device 700 controls the display 9 based on the image signal from the two-dimensional image pickup element 306 to display the anterior segment image of the eye E on the display 9.

The fixation optical system 400 includes a light source 401, a relay lens 403, and a mirror 404. The light source 401 operates in such a manner as to irradiate light for prompting the subject to perform fixation (hereinafter referred to as fixation light).

The fixation light passes through the relay lens 403 and is reflected by the mirror 404, and then is reflected by the dichroic mirror 304 and passes through the main optical axis O1, and passes through the objective lens 303 and the hot mirror 104 to be imaged on the retina of the eye E. The eye E is brought into a vision fixation state by the fixation light, in which the eye characteristics can be examined, for example, by intraocular pressure examination. The light source 401 employs an LED that outputs visible light that is visually recognizable by the subject.

The first measurement optical system 500 for measuring intraocular pressure includes a light source 501, a half mirror 502, a condenser lens 503, and a light receiving element 504. Light from the light source 501 (hereinafter referred to as first measurement light) passes through the half mirror 502, passes through the hot mirror 102 and the objective lens 103, is reflected by the hot mirror 104 to pass through the main optical axis O1, and passes through the plane glass 205 and the opening portion 201c of the nozzle 201 to be irradiated to the cornea of the eye E.

The light applied to the cornea of the eye E is reflected by the cornea, goes back along the outward path, passes through the opening 201c of the nozzle 201 and the flat glass 205, is reflected by the hot mirror 104, passes through the objective lens 103 and the hot mirror 102, is reflected by the half mirror 502, passes through the condenser lens 503, and is received by the light receiving element 504.

When examining the intraocular pressure, compressed air is jetted from the nozzle 201 toward the cornea of the eye E to be examined. The cornea of the eye E to be examined is displaced and deformed when the compressed air is ejected, thereby causing a change in the amount of light received by the light receiving element 504. The intraocular pressure of the eye E is calculated from the degree of change in the light amount.

The light source 501 employs an LED that outputs infrared light having a wavelength longer than that of observation light and shorter than that of alignment light. The wavelengths of the alignment light, the observation light, the fixation light, and the first measurement light are set as described above, and the reflection/transmission characteristics of the hot mirrors 102, 104 and the dichroic mirror 304 are appropriately set, whereby the four lights are caused to propagate along appropriate optical paths.

The second measurement optical system 600 for measuring the corneal thickness includes a light source 601, a lens 602, a cylindrical lens 603, and a light receiving element 604. Light from a light source 601 (hereinafter referred to as second measurement light) is irradiated to the cornea of the eye E after being converted into parallel light by a lens 602 through a transparent window part 201a of the observation port 200. The second measurement light irradiated to the cornea is reflected at the corneal endothelium and the corneal epithelium of the eye E to be examined. These reflected lights pass through the transparent window part 201a of the observation port 200 and pass through the cylindrical lens 603 to be received by the light receiving element 604. The light source 601 is, for example, a superluminescent diode (SLD) having coherence. The light source 601 is not limited to the SLD, and a light source (diode) having coherence such as a Laser Diode (LD) may also be employed.

When a coherent light source is used as the light source 601, speckle noise may be generated, and the measurement accuracy of the corneal thickness may be reduced. However, as described above, the second measurement light reflected at the corneal endothelium and the corneal epithelium of the eye E to be inspected passes through the cylindrical lens 603 and is shaped into linear light, whereby speckle noise can be reduced.

The control device 700 processes the light receiving signal from the light receiving element 604. The control device 700 operates in such a manner as to measure the corneal thickness of the eye E to be examined based on the difference between the light receiving positions on the light receiving surface of the first reflected light and the second reflected light determined from the light receiving signal. The first reflected light is reflected light from the corneal endothelium of the eye E to be examined. The second reflected light is reflected light from the corneal epithelium.

In addition, the second measurement optical system 600 also serves as a Z-alignment optical system before optometry. The light receiving position of the reflected light in the light receiving element 604 changes based on the position of the cornea of the eye E in the Z direction. The control device 700 detects the position of the cornea of the eye E in the Z direction based on the light receiving position. The XYZ drive system 720 adjusts the position of the head 3 relative to the eye to be examined E in the Z direction based on the detected position.

In the optometry apparatus 1, the alignment of the head 3 with respect to the eye E in the Z direction (coarse alignment) is automatically performed based on, for example, an anterior segment image of the eye E indicated by an image signal from the two-dimensional image pickup element 306, and then, the alignment of the head 3 with respect to the eye E in the Z direction (fine alignment) is automatically and highly accurately performed based on the second measurement light.

As described above, the alignment of the head 3 with respect to the eye to be inspected E in the XY directions (coarse alignment) is also automatically performed based on the anterior segment image of the eye to be inspected E indicated by the image signal from the two-dimensional image pickup element 306 in the same manner, and then, the alignment of the head 3 with respect to the eye to be inspected E in the XY directions (fine alignment) is automatically and highly accurately performed based on the alignment light. When the rough alignment cannot be automatically performed, the rough alignment is manually performed by the inspector using the joystick 741.

Next, details of the alignment process performed by the control device 700 will be described with reference to fig. 4. The control apparatus 700 automatically performs alignment of the head 3 with respect to the eye to be inspected E while the face of the subject is placed on the support structure 7 by repeatedly performing the alignment process shown in fig. 4.

When the execution of the alignment process is started, the control device 700 determines whether the fine alignment process can be executed (S110). When the relative position of the head 3 with respect to the eye E is within a range in which the fine alignment process can be performed, the control device 700 makes an affirmative determination in S110, and for the other cases, makes a negative determination in S110.

In order to determine whether or not the fine alignment process can be performed, the control device 700 can irradiate alignment light from the light source 101 and acquire an image signal from the two-dimensional image pickup element 306. Further, when the image signal includes a reflected light component corresponding to the alignment light and the position of the corneal vertex can be detected from the reflected light component, it can be determined that the fine alignment processing can be performed.

If it is determined in S110 that the fine alignment process can be performed (S110: yes), the control device 700 performs the fine alignment process in S220. Then, the alignment process is ended.

If a negative determination is made in S110, control device 700 causes light source 301 and light source 302 to be turned on and off (S120). Then, control device 700 acquires image signals from two-dimensional image sensor 306 during the on and off states, respectively (S120). The image signal at the time of lighting represents a captured image (light reception image) of the two-dimensional imaging element 306 at the time of lighting. The image signal at the time of turning off indicates a captured image (light-receiving image) of the two-dimensional imaging element 306 at the time of turning off.

The control device 700 calculates the luminance B1 of the captured image at the time of lighting and the luminance B2 of the captured image at the time of lighting-off based on the acquired image signals (S130). Then, control device 700 calculates a difference between luminance B1 at the time of lighting and luminance B2 at the time of lighting off, that is, a luminance difference BD, as B1-B2 (S140).

The luminance B1 and the luminance B2 may be the sum or average of the luminance of each pixel in the entire captured image, or may be the sum or average of the luminance of each pixel in a predetermined central portion of the captured image.

Based on the above-described calculated luminance difference BD, control device 700 determines whether the face of the subject is placed on support structure 7 (S150). As shown in fig. 5, when the face of the subject is not placed on the support structure 7, most of the light reaching the two-dimensional image pickup element 306 is background light that propagates from the outside through the observation port 200, and the luminance of the captured image of the two-dimensional image pickup element 306 is low regardless of whether the light source 301 and the light source 302 are in the lit state. In fig. 5, the case where the luminance is low is indicated by hatching.

In contrast, when the face of the subject is placed on the support structure 7, the light from the light source 301 and the light source 302 is reflected at the face of the subject, particularly at the eyes, and the reflected light is received by the two-dimensional image pickup element 306, and therefore, the brightness of the captured image is low when it is extinguished and high when it is lit. In S150, using this phenomenon, it is determined whether the face of the subject is placed on the support structure 7 based on the luminance difference BD.

Specifically, when the luminance difference BD is equal to or greater than the predetermined threshold value, the control apparatus 700 may determine that the face of the subject is placed on the support structure 7 (S150: yes), and in the case other than this, may determine that the face of the subject is not placed on the support structure 7 (S150: no).

If the control apparatus 700 determines that the face of the subject is not placed on the support structure 7 (S150: no), the light source 301 and the light source 302 are turned on and off again (S120). Then, the processing of S130 to S150 is executed again. The next lighting and extinguishing may be performed at intervals from the immediately preceding lighting and extinguishing.

If the control device 700 determines that the face of the subject is placed on the support structure 7 (S150: YES), the head 3 is arranged at the origin position in the Z direction to photograph the eye E and detect the pupil (S160).

Specifically, the control device 700 first moves the head 3 to the origin position in the Z direction by the XYZ drive system 720. The origin position corresponds to a position at which the head 3 is farthest from the eye E in the Z direction within a range in which the pupil of the eye E can be photographed. Here, the reason why the head 3 is disposed at the origin position is to prevent the head 3 from contacting the subject (particularly, the eye to be examined E) due to the subsequent movement of the head 3.

Then, the control device 700 turns on the light sources 301 and 302 in a state where the head 3 is disposed at the origin position, and acquires an image signal at the time of the turning on from the two-dimensional imaging element 306, thereby capturing an image of the eye E. The image signal basically represents a captured image of the anterior ocular region of the eye E. The control device 700 analyzes the acquired image signal, and detects the pupil of the eye E and the position thereof in the XY direction by detecting the black circular area in the captured image of the anterior segment area indicated by the image signal.

Here, when the pupil can be detected, control device 700 makes an affirmative determination in S170, and executes the process of S180. On the other hand, when the pupil cannot be detected, control device 700 makes a negative determination in S170, and executes the process of S120 again.

In S180, control device 700 executes rough alignment processing in the XY direction based on the detected position of the pupil. That is, the control device 700 moves the head 3 in the XY directions by the XYZ drive system 720 so that the head 3 is aligned with the center of the detected pupil.

Then, control device 700 determines whether or not the rough alignment process in the Z direction can be executed (S190). Specifically, control device 700 analyzes the image signal from two-dimensional imaging element 306, and determines whether or not distance D between the position of the reflected light from light source 301 reflected on the pupil and the position of the reflected light from light source 302 reflected on the pupil can be calculated.

The image signal of the analysis target may be an image signal obtained by a photographing operation after the rough alignment process in the XY direction (S180) is performed. That is, in S190, in order to make the above determination, control device 700 may obtain an image signal at the time of lighting again from two-dimensional imaging element 306 in a state where light source 301 and light source 302 are lit, and analyze the image signal. As another example, the determination in S190 may be made based on an image signal acquired in the process (S160) before the rough alignment process in the XY direction is performed.

In the present embodiment, the light source 301 and the light source 302 are disposed on the left and right sides of the eye E, respectively. Therefore, when the distance D can be calculated, although an error due to a difference in curvature of the eye E is included, the position of the eye E in the Z direction can be roughly determined from the distance D.

For example, in the case where the distance D is long as shown in fig. 6A, it means that the distance between the eye E and the head 3 is smaller than that in the case where the distance D is short as shown in fig. 6B. The shaded circular areas shown in fig. 6A and 6B represent the eye E, and the white circular areas represent reflected light reflected in the eye E. The relationship between the distance D and the position of the eye E in the Z direction can be derived in advance through experiments or through desktop calculations.

When the distance D within the predetermined normal range can be calculated, the control device 700 may determine that the rough alignment process in the Z direction can be performed, and may determine that the rough alignment process in the Z direction cannot be performed otherwise.

If control device 700 determines that the rough alignment process in the Z direction can be performed (S190: yes), the rough alignment process in the Z direction is performed based on the position of eye E in the Z direction determined by distance D described above (S200).

That is, the control device 700 moves the head 3 in the Z direction by the XYZ drive system 720 to position the head 3 at a position separated from the position of the eye E by an appropriate distance in the Z direction (S200). Then, control device 700 makes a determination at S110. In this case, the relative position of the head 3 with respect to the eye E to be inspected is substantially within a range in which the fine alignment process can be performed. Therefore, the control device 700 makes an affirmative determination in S110, and performs the fine alignment process (S220).

On the other hand, if the control device 700 determines that the rough alignment process in the Z direction cannot be performed (S190: no), the examiner is instructed via the display 9 to manually perform the alignment in the Z direction. Further, the control device 700 receives the operation of the joystick 741 and moves the head 3 relative to the body 5 (S210). The examiner can manually align the head 3 with the eye E based on the photographed image of the anterior ocular region of the eye E displayed on the display 9.

When the above manual operation is completed, control device 700 makes a determination at S110. When the head 3 is adjusted to a position where the fine alignment process can be performed by a manual operation, the control device 700 makes an affirmative determination in S110, and performs the fine alignment process (S220).

Alternatively, if the rough alignment process in the Z direction can be executed as a result of the manual operation after the transition to S210, control device 700 may end the acceptance of the manual operation and execute the rough alignment process in the Z direction in the same manner as in S200. Then, the control device 700 can make an affirmative determination in S110 and perform the fine alignment process (S220).

In the fine alignment process (S220), control device 700 detects the position of the corneal vertex of the subject based on the reflected light component of the alignment light included in the image signal from two-dimensional image pickup element 306. Further, the control device 700 moves the head 3 in the XY directions by the XYZ drive system 720 to align the head 3 to the detected position of the corneal vertex of the eye to be examined E.

The control device 700 controls the second measurement optical system 600 to irradiate the second measurement light from the light source 601 and to acquire a light reception signal of the reflected light from the light receiving element 604. The control device 700 moves the head 3 in the Z direction by the XYZ drive system 720 to position the head 3 to an appropriate position with respect to the position of the eye to be examined E in the Z direction determined by the reflected light component contained in the acquired light reception signal. Then, control device 700 ends the alignment process shown in fig. 4. Control device 700 may perform optometry processing, specifically, processing for measuring the thickness of the cornea and processing for measuring the intraocular pressure, after finishing the alignment processing.

The optometry apparatus 1 of the present embodiment described above can detect the face of the subject placed on the support structure 7 by turning on and off the illumination light source 301 and the light source 302 provided for observing the eye E. After inspection, the optometric instrument 1 is able to automatically perform the alignment of the head 3 with the eye E to be inspected.

Therefore, according to the optometry apparatus 1, the preparation operation for optometry can be automatically performed quickly while suppressing the burden on the examiner due to optometry. This automatic execution helps to shorten the examination time. Therefore, the present embodiment can provide the optometry apparatus 1 with high convenience.

In the present embodiment, the face of the subject is automatically detected, and the alignment of the head 3 is automatically performed. Therefore, it is possible to prevent a situation in which the driving of the head 3 is performed to make unnecessary alignment although the face of the subject is not placed on the support structure 7.

Further, in the present embodiment, a dedicated component is not required as a configuration for detecting the face of the subject. That is, the optometry apparatus 1 does not require dedicated hardware, and is capable of detecting the face of the subject only by software processing such as blinking the light source 301 and the light source 302 and analyzing the captured image. Therefore, according to the present embodiment, it is possible to detect a subject by effectively utilizing the configuration for optometry in the optometry apparatus.

In the above, the exemplary embodiments of the present disclosure are explained, but the present disclosure is not limited to the above embodiments and various manners may be adopted. For example, a plurality of functions of one constituent element in the above-described embodiments may be distributed among a plurality of constituent elements. The functions possessed by a plurality of constituent elements may be integrated into one constituent element. A part of the constitution of the above embodiment may be omitted. Various aspects included in the technical idea defined by the terms described in the patent claims are embodiments of the present disclosure.