JP5283552B2 - Ophthalmic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ophthalmological instrument which improves operability by the control lever of a loaded electrical control lever mechanism. <P>SOLUTION: The ophthalmological instrument 10 is provided with: a moving mechanism (18) for moving an ocular characteristic measurement part (31); the electrical control lever mechanism 20 for outputting tilting operation performed to the control lever 13; a control mechanism 19 which performs normal velocity control on the basis of operation to the control lever mechanism 20, and causes the ocular characteristic measurement part (31) to measure ocular characteristics; and an operation part (30) for outputting performed intermittent operation. When the tilting angle of the control lever 13 is smaller than an angle threshold &theta;l, the control mechanism 19 controls measurement while continuing the normal velocity control when detecting the intermittent operation to the operation part (30). When the tilting angle of the control lever 13 is larger than the angle threshold &theta;l, the control mechanism 19 changes the normal velocity control to fast velocity control when detecting the intermittent operation for the operation part (30). <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to an ophthalmologic apparatus capable of adjusting the position of an eye characteristic measuring unit with respect to an eye to be examined by an operation of tilting a control lever.

  Conventionally, as an ophthalmologic apparatus, an eye characteristic measurement unit for examining, observing, photographing, etc. of an eye to be examined is three-dimensionally provided on a base provided with a holding unit for holding the face of the subject. There is a configuration in which the position of the eye characteristic measuring unit with respect to the subject's eye held by the subject can be adjusted by tilting a control lever. As such an ophthalmologic apparatus, when the control lever is tilted, the eye characteristic measuring unit mechanically moves back and forth and right and left with respect to the eye to be examined (subject) according to the tilt direction and tilt angle. Some models are equipped with a control lever mechanism.

  Further, in recent years, based on a movement mechanism that electrically moves the eye characteristic measurement unit, an electric control lever mechanism that outputs a tilting operation performed on the control lever as an electric signal, and an operation signal therefrom. There has been proposed an ophthalmic apparatus configured to include a control mechanism that transmits a control command to a moving mechanism. In such an ophthalmologic apparatus, the control mechanism sets a threshold value for the tilt angle of the control lever, and if the tilt angle is smaller than the threshold value, the movement distance is made to correspond to the magnitude of the tilt angle of the control lever. If the tilt angle is larger than the threshold value, the operability by tilting the control lever is improved by using the speed control that corresponds to the speed of the tilt angle of the control lever. (See, for example, Patent Document 1).

  In addition, in an ophthalmologic apparatus configured to include a moving mechanism, an electric control lever mechanism, and a control mechanism as described above, the control mechanism can detect the operation speed when the control lever is tilted, and the operation speed can be detected. The amount of movement of the eye characteristic measurement unit is changed according to the size of the eye, and it is possible to detect that the control lever is tilted to the limit angle. When the control lever is tilted to the limit position, the eye characteristic measurement unit is coarsely operated. It is considered that the operability by tilting the control lever is improved (for example, see Patent Document 2).

JP 2002-369799 A JP 2009-56247 A

  However, in the ophthalmologic apparatus of Patent Document 1, the control method is simply switched according to the tilt angle of the control lever, and when it is tilted beyond the threshold, it switches to speed control. If the eye characteristic measurement unit is tilted to move the eye characteristic measurement unit greatly when the speed is set low, it takes time to move the eye characteristic measurement unit, and if the movement speed in the speed control is set large, the eye characteristic measurement unit When it is greatly tilted for position adjustment, it becomes difficult to adjust the position, so there is room for improvement in operability.

  Further, in the ophthalmologic apparatus of Patent Document 2, the amount of movement of the eye characteristic measurement unit is changed according to the magnitude of the operation speed of the control lever. Therefore, when the position of the eye characteristic measurement unit is adjusted while largely moving, Since it is necessary to incline slowly and greatly, there is room for improvement in operability, and when tilting to the limit position, a problem similar to that of the ophthalmic apparatus of Patent Document 1 occurs due to the speed setting in the coarse motion operation. Here, Patent Document 2 describes that a speed adjustment switch for adjusting the moving speed when tilting to the limit position is provided, but operating the speed adjustment switch separately from the control lever is troublesome. Invitation Patent Document 2 describes that the measurement start switch provided on the control lever has a function as a speed adjustment switch. However, the measurement start switch may be adjusted by a pressing operation. In order to adjust the speed, it is necessary to repeat the pressing operation of the measurement start switch many times, resulting in complicated operation.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an ophthalmologic apparatus capable of improving the operability of a control lever of an electric control lever mechanism mounted thereon.

  The invention according to claim 1 is an eye characteristic measurement comprising an optical system for measuring the subject's eye with respect to a base provided with a holding portion for holding the subject's face to be fixed. A movement mechanism that electrically moves the part, and an electric control lever mechanism that outputs, as an electrical signal, a tilting operation performed on the control lever to adjust the position of the eye characteristic measurement unit with respect to the eye to be examined. Based on the signal from the control lever mechanism, normal speed control is performed for generating a control command for the movement speed of the eye characteristic measurement unit according to the tilt angle of the control lever and transmitting it to the movement mechanism, and A control mechanism for performing measurement control for generating and transmitting a control command for executing eye characteristic measurement of the optometry to the eye characteristic measuring unit, and the controller performing the intermittent operation performed by itself as an electrical signal An operation unit that outputs to the control unit, wherein the control mechanism operates when the tilt angle of the control lever is smaller than a preset angle threshold for the tilt operation to the control lever. When the intermittent operation to the unit is detected, the measurement control is performed while continuing the normal speed control. When the tilt angle of the control lever is larger than the angle threshold, the normal speed is detected when the intermittent operation to the operation unit is detected. The control is changed to high-speed speed control that moves the eye characteristic measurement unit at a moving speed larger than the normal speed control.

  According to the ophthalmologic apparatus of the present invention, when the tilt angle of the control lever is smaller than a preset angle threshold for the tilt operation to the control lever, the normal speed is detected when the intermittent operation to the operation unit is detected. When the measurement control is performed while the control is continued, and the tilt angle of the control lever is larger than the angle threshold, when the intermittent operation to the operation unit is detected, the moving speed larger than the normal speed control from the normal speed control To change to high speed control for moving the eye characteristic measuring unit.

  That is, normal speed control is performed according to the tilting operation to the control lever, and when the control lever is tilted smaller than the angle threshold, the eye characteristic measurement unit performs the eye characteristic measurement by the intermittent operation to the operation unit. When the control lever is tilted more than the angle threshold value, the inspector can change the control lever tilt operation and the operation unit by changing from normal speed control to high speed control by intermittent operation to the operation unit. The eye characteristic measurement can be performed at an arbitrary position by the intermittent operation, and the eye characteristic measurement unit can be appropriately moved at high speed. Here, since the operation unit for performing the eye characteristic measurement is easy to perform intermittent operation (position and operation method) for the examiner who is tilting the control lever, all the above-described operations are performed. The operation is not complicated. Further, since it is not necessary to care about the speed of the tilting operation of the control lever, the tilting operation of the control lever is easy.

  As a result, the operability by the control lever of the mounted electric control lever mechanism can be improved.

It is a typical perspective view which shows an example of the external appearance structure of the ophthalmologic apparatus which concerns on this invention. It is a front view which shows the ophthalmologic apparatus seen from the subject side. It is a side view which shows the ophthalmologic apparatus seen from the side. It is a block diagram for demonstrating movement control of the eye characteristic measurement mechanism with respect to tilting operation of the control lever in an ophthalmologic apparatus. It is a typical perspective view which shows a control lever mechanism. It is a flowchart which shows an example of the content of the movement control process of the apparatus main body with respect to operation performed by the control lever and press switch in the control part of a control mechanism. It is a schematic diagram which shows the image of the eye to be examined displayed on the display. It is explanatory drawing which shows the concept of the map used for the movement control in Example 1. FIG. It is explanatory drawing which shows the map used for the movement control in Example 1 as an example of movement control. It is explanatory drawing for demonstrating a prohibition area | region. It is explanatory drawing for demonstrating the alerting symbol in Example 1 as an example of an alerting | reporting means. It is explanatory drawing for demonstrating the basic concept of the switching of the control with respect to the press operation to the press switch according to the inclination-angle of a control lever. It is explanatory drawing which shows a mode that the measurement center position moved relatively on the image of the eye to be examined.

  Embodiments of an ophthalmologic apparatus according to the present invention will be described below with reference to the drawings.

  FIG. 1 is a schematic perspective view showing an example of an external configuration of an ophthalmologic apparatus 10 according to the present invention. FIG. 2 is a front view showing the ophthalmologic apparatus 10 viewed from the subject side, and FIG. 3 is a side view showing the ophthalmologic apparatus 10 viewed from the side. FIG. 4 is a block diagram for explaining movement control of the eye characteristic measurement mechanism 31 with respect to the tilting operation of the control lever 13 in the ophthalmologic apparatus 10. FIG. 5 is a schematic perspective view showing the control lever mechanism 20.

  The ophthalmologic apparatus 10 is a composite ophthalmologic apparatus capable of performing a plurality of types of examinations, and includes a base 11 and an apparatus main body 12 provided above the base 11 as shown in FIGS. The base 11 is provided with a control lever 13 and an operation switch 14 on one side, and a chin rest 15 and a forehead pad 16 on the other side. The apparatus main body 12 is provided with a display 17 on the surface on which the control lever 13 and the operation switch 14 are provided.

  In the ophthalmologic apparatus 10, the subject examines the eye E (see FIG. 3) in a state where the subject is placed on the chin rest 15 and the forehead 16 is in contact with the forehead 16 while facing the main body 12. Observation, shooting, etc. For this reason, the chin rest 15 and the forehead support 16 function as a holding part for holding the face of the subject in the ophthalmologic apparatus 10.

  The control lever 13 is operated by an examiner (operator) to move the apparatus main body 12 that can be moved as described later (position adjustment of an eye characteristic measuring mechanism 31 described later). This operation will be described in detail later. The operation switch 14 is operated for adjusting the positions of the chin rest 15 and the forehead pad 16.

  In the ophthalmologic apparatus 10, basically, the examiner is positioned on the side where the control lever 13 and the operation switch 14 are provided, and the subject's eye E (held by the chin rest 15 and the forehead rest 16. (See FIG. 3). When the subject is opened, the examiner may be located on the side of the ophthalmologic apparatus 10. Here, in the following and each drawing, the vertical direction is the up-down direction (see arrow Y), and the direction in which the examiner and the subject are facing each other orthogonally to the up-down direction is the front-back direction (see arrow Z). The direction orthogonal to the direction and the front-rear direction is the left-right direction (see arrow X).

  The base 11 houses a main body drive mechanism 18, a control mechanism 19, a control lever mechanism 20 (see FIG. 4), a power supply circuit and the like (not shown). The base 11 holds the apparatus main body 12 movably in three dimensions, that is, up and down, front and rear, and left and right, via the main body drive mechanism 18 (see FIG. 4), and the eye accommodated in the apparatus main body 12 It functions as a moving mechanism that electrically moves the characteristic measuring mechanism 31. As shown in FIG. 4, the main body drive mechanism 18 includes a first drive unit 21 for moving in the left-right direction (see arrow X in FIG. 1 and the like) and a front-rear direction (see arrow Z in FIG. 1 and the like). A second drive unit 22 for moving the second drive unit 22, a third drive unit 23 for moving in the vertical direction (see arrow Y in FIG. 1 and the like), and each drive unit 21 according to a control command from the control mechanism 19. , 22, and 23. Although not shown in the drawing, each of the drive units 21, 22, and 23 is configured to move the apparatus main body 12 with respect to the base 11 using the driving force of the motor. The drive circuit unit 24 moves the movement amount and the movement speed. Can be adjusted. Since the main body drive mechanism 18 is the same as the conventional configuration, detailed description thereof is omitted. As will be described later, the main body drive mechanism 18 measures the eye E using the eye characteristic measurement mechanism 31, and moves the apparatus main body to a position suitable for the subject held by the chin rest 15 and the forehead pad 16. 12 is moved with respect to the base 11.

  The control mechanism 19 includes a control unit 25, a storage unit 26, and a main body position detection unit 34. The control unit 25 (control mechanism 19) appropriately reads a control program and various data stored in the storage unit 26, performs measurement (measurement control) by an eye characteristic measurement mechanism 31 described later, and a control lever mechanism 20 (control lever). 13 and a press switch 30 described later (determination of lever operation), switching of various movements for operations performed on the control lever mechanism 20 (control lever 13 and press switch 30 described later) (control switching determination) ), Various movement commands to the main body drive mechanism 18 (drive control), display on the display 17 and position determination in the image (image display control), and the like are comprehensively controlled. Further, the control unit 25 (control mechanism 19) can acquire position information of the apparatus main body 12 (eye characteristic measurement mechanism 31) with respect to the base 11 based on a detection signal from the main body position detection unit 34. The main body position detection unit 34 may detect the position of the apparatus main body 12 in an area in which movement is possible on the base 11, and the apparatus main body 12 prohibits an area Ap (described later with reference to FIG. 10). ) May be determined.

  As shown in FIG. 5, the control lever mechanism 20 instructs the drive direction, drive amount, and drive speed of the apparatus body 12 by tilting and rotating the control lever 13, and the control lever 13 (FIG. 1). The tilting operation and the rotation operation performed on the control unit 19 are transmitted to the control unit 25 of the control mechanism 19. That is, when the control lever 13 is tilted in the front-rear direction (see arrows F and B), the apparatus body 12 is instructed to approach / separate from the eye E (subject) (see arrow Z in FIG. 1). When the control lever 13 is tilted in the left-right direction (see arrows L and R), an instruction is given to move the apparatus body 12 in the eye width direction of the eye E (see arrow X in FIG. 1), and the control lever 13 is turned in the left-right direction. When rotated (see arrows U and D), an instruction to move the apparatus main body 12 in the vertical direction (see arrow Y in FIG. 1) is given. For this reason, as will be described later, the examiner tilts and rotates the control lever 13 so as to measure the eye E using the eye characteristic measurement mechanism 31 and to the chin rest 15 and the forehead pad 16. The apparatus main body 12 (eye characteristic measuring mechanism 31) can be moved in a three-dimensional direction with respect to the base 11 to a position suitable for the held subject.

  As shown in FIGS. 4 and 5, the control lever mechanism 20 includes a first potentiometer 27 that detects the tilt angle of the control lever 13 in the left-right direction (see arrows L and R), and the front-rear direction of the control lever 13 ( The second potentiometer 28 detects the tilt angle to the arrow F and B), and the rotary encoder 29 detects the rotation angle of the control lever 13 in the left-right direction (see arrows U and D). Although not shown, the first potentiometer 27 is connected to a rotation shaft for tilting the control lever 13 in the left-right direction, and detects either the left-right tilt direction and the tilt angle to the control unit 25. Send. The second potentiometer 28 is connected to a rotating shaft for tilting the control lever 13 in the front-rear direction, although not shown in the figure, and detects the tilt direction and the tilt angle of the front-rear direction and the control unit 25. Send to. Although not shown, the rotary encoder 29 is connected to a rotation shaft for rotating the control lever 13 in the left-right direction. The rotary encoder 29 detects one of the left and right rotation directions and the rotation angle, and sends the detected rotation direction to the control unit 25. Send.

  In the control lever mechanism 20, as shown in FIGS. 1, 3, and 5, a pressing switch 30 is provided on the front end surface of the control lever 13. The control lever mechanism 20 performs the measurement operation by the pressing operation to the pressing switch 30 in addition to the driving direction, driving amount, and driving speed of the apparatus main body 12 by the tilting operation and the rotation operation to the control lever 13 described above. As shown in FIG. 4, the pressing operation performed on the pressing switch 30 is transmitted to the control unit 25 of the control mechanism 19. From this, in Example 1, the push switch 30 functions as an operation part. For this reason, as will be described later, the examiner is positioned to fit the subject held on the chin rest 15 and the forehead support 16 with respect to the base 11 by tilting and rotating the control lever 13. The apparatus main body 12 (eye characteristic measuring mechanism 31) can be moved in the three-dimensional direction and the eye characteristic measurement mechanism 31 of the apparatus main body 12 performs eye characteristic measurement of the eye E (see FIG. 3 and the like). be able to. In the first embodiment, the control unit 25 of the control mechanism 19 is in the ON state when the pressing switch 30 is turned ON by the pressing operation in the control lever mechanism 20 (when an electrical intermittent operation is detected). And the tilt angle θ of the control lever 13 at the time point is stored in the storage unit 26 of the control mechanism 19.

  Further, in the control lever mechanism 20, when the control lever 13 is tilted and the control lever 13 is released (when the urging force is released), the control lever 13 is returned to the original state (X-axis direction and Z-axis direction). The tilt angle to the back is 0 degree). Since the structure for returning the control lever 13 to the original state is the same as that of the conventional one, detailed description thereof is omitted.

  A display 17 is provided on the apparatus main body 12 which is operated to move by the control lever mechanism 20 (see FIG. 1 and the like). As shown in FIGS. 1 and 3, the display 17 is disposed on the side where the control lever 13 and the operation switch 14 are provided, that is, on the side where the examiner is located. As shown in FIG. 4, the display 17 has an image such as an anterior segment image of the eye E based on the image data from the eye characteristic measurement mechanism 31 under the control of the control unit 25 of the control mechanism 19 (FIG. 7). Reference) and various examination information from the eye characteristic measurement mechanism 31 (examiner information, examination conditions, examination results, etc.). Further, the display 17 is a touch panel in the first embodiment, and software keys for various operations in the ophthalmologic apparatus 10 are displayed under the control of the control unit 25, and the eye E to be examined is operated by operating the software keys. Various operations such as alignment, setting of various inspection conditions, and adjustment of the display 17 can be performed.

  When an operation for executing alignment is performed on the software switch on the operation switch 14 or the display 17, the control unit 25 of the control mechanism 19 transmits a control command to the main body drive mechanism 18 and the eye characteristic measurement mechanism 31. By doing so, the alignment with respect to the eye E is automatically performed. Auto-alignment in the measurement of these various tests is performed by the apparatus main body 12 with respect to the subject held by the chin rest 15 and the forehead pad 16, that is, the base 11, and the main body drive mechanism 18 in the front-rear direction (see arrow Z). , By moving in the vertical direction (see arrow Y) and the horizontal direction (see arrow X). Since this auto alignment is the same as the conventional configuration and operation, a detailed description thereof will be omitted.

  The ophthalmologic apparatus 10 is capable of measuring eye characteristics, and an eye characteristics measuring mechanism 31 (see FIG. 4) as an eye characteristics measuring unit for the measurement is housed in the apparatus body 12. In the first embodiment, the eye characteristic measurement mechanism 31 is not shown in the drawing, but objectively determines the wavefront sensor optical system for measuring the wavefront aberration and the refraction state of the eye E (sense of the subject (= awareness)). The refractometer optical system for measuring and the platide optical system for projecting a concentric placido ring image on the cornea from the projection surface 31a (see FIG. 2) are configured as the same measurement optical axis. ing. Since the eye characteristic measuring mechanism 31 is the same as the conventional configuration, detailed description thereof is omitted.

  Further, as shown in FIG. 4, the eye characteristic measurement mechanism 31 includes a wavefront imaging camera 32 for measuring wavefront aberration and an anterior segment imaging camera 33 for observing the anterior segment of the eye E to be examined. Then, each image data acquired by each camera is output to the control unit 25 of the control mechanism 19. Based on the image data from the anterior segment imaging camera 33, an image of the eye E (anterior segment) is displayed in real time on the display 17 under the control of the control unit 25 of the control mechanism 19. (See FIG. 7).

  Note that, as an eye characteristic measurement mechanism mounted in the ophthalmologic apparatus according to the present invention, in the acquired image of the eye E, the measurement optical axis of the eye characteristic measurement unit can be placed at an arbitrary position (for example, the center position) of the eye E. If the examiner uses the control lever 13 to adjust the position (alignment), the eyesight test, corneal thickness test, corneal topography test, color vision test, visual field test, anterior ocular radiography, corneal endothelium Imaging, fundus imaging, OCT (Optical Coherence Tomography) inspection, SLO (Scanning Laser Ophthalmoscope) inspection, ultrasonic inspection, radiological inspection, and the like may be used, and are not limited to the first embodiment.

  In the ophthalmologic apparatus 10, as described above, the control lever 13 and the push switch 30 are operated while viewing the image of the eye E to be examined displayed in real time on the display 17 in order to perform measurement with the eye characteristic measurement mechanism 31. Thus, the positional relationship of the eye characteristic measurement mechanism 31 with respect to the eye E can be adjusted, and the eye characteristic measurement by the eye characteristic measurement mechanism 31 can be executed. This will be described below.

  FIG. 6 is a flowchart showing an example of the contents of the movement control process of the apparatus main body 12 in response to operations performed on the control lever 13 and the push switch 30 in the control unit 25 of the control mechanism 19. FIG. 7 is a schematic diagram showing an image of the eye E displayed on the display 17. FIG. 8 is an explanatory diagram showing the concept of a map used for movement control in the first embodiment, and FIG. 9 is an explanatory diagram showing a map used for movement control in the first embodiment as an example of movement control. FIG. 10 is an explanatory diagram for explaining the prohibited area, and FIG. 11 is an explanatory diagram for explaining the notification symbol I in the first embodiment as an example of notification means.

  In the ophthalmologic apparatus 10, as described above, the subject performs the measurement while placing the chin on the chin rest 15 while bringing the forehead into contact with the forehead pad 16 and facing the main body 12. At this time, as shown in FIG. 7, the image of the eye E to be examined acquired by the anterior segment imaging camera 33 of the eye characteristic measurement mechanism 31 is displayed on the display 17 in real time under the control of the control unit 25. . At this time, in the first embodiment, the control unit 25 overlaps the image of the eye E with the index indicating the center position of the eye E (hereinafter referred to as the center position Ec), and the eye characteristic measurement mechanism 31. An index indicating the measurement optical axis (hereinafter referred to as measurement center Ma) is displayed.

  In the ophthalmologic apparatus 10 according to the present invention, basically, the control unit 25 of the control mechanism 19 is configured such that the tilt angle θ of the control lever 13 exceeds the angle threshold θl according to the tilt angle of the control lever 13. By determining whether or not there is, control for pressing operation to the pressing switch 30 is switched. Hereinafter, each step of the flowchart of FIG. 6 which is an example of the movement control process of the apparatus main body 12 in response to an operation performed on the control lever 13 in the control unit 25 of the control mechanism 19 will be described with reference to FIGS. In the following description, in the movement control process in the control unit 25, the process for the rotation operation to the control lever 13 is the same as the conventional process, and is omitted for easy understanding. Further, as described above, the movement control process in the control unit 25 for the tilting operation to the control lever 13 is performed in the front-rear direction (see arrows F and B in FIG. 1 and the like) and the left and right direction (arrows L and R in FIG. However, for the sake of easy understanding, the following movements are performed at the same time after both the front-rear direction and the left-right direction are determined. Only the movement control process with respect to the direction will be described. In the first embodiment, the tilt angle refers to the control lever 13 (its center line) in the tilted state with respect to the control lever 13 (its center line) in the original state (neutral position (angle 0)). The angle to do. Further, the first potentiometer 27 and the second potentiometer 28 for detecting the tilting operation performed in the front-rear direction and the left-right direction with respect to the control lever 13 are configured to detect the tilt direction and the tilt angle. Therefore, the tilt angle is detected as a positive (plus) value between 0 degree and the maximum tilt angle (the limit angle at which the control lever 13 can be tilted) regardless of the tilt direction.

  In step S1, image data is acquired, and the process proceeds to step S2. In this step S1, the image data of the eye E acquired by the anterior segment imaging camera 33 of the eye characteristic measurement mechanism 31 is acquired, and the image of the eye E is displayed in real time 17 as shown in FIG. To display. Further, based on the acquired image data, the center position Ec of the eye E to be examined is detected, and the center position Ec is displayed so as to be superimposed on the image of the eye E to be examined. Further, the measurement center Ma is displayed on the image of the eye E to be examined.

  In step S2, following the acquisition of image data in step S1, the tilt angle applied to the control lever 13 is detected, and the process proceeds to step S3. In this step S2, the tilting direction (X-axis direction or Z-axis direction) applied to the control lever 13 is not tilted based on the detection signal from the control lever mechanism 20 (the first potentiometer 27 and the second potentiometer 28). With the state as the center (tilt angle 0 degree), one is a plus side and the other is a minus side) and a tilt angle are acquired and stored as a tilt angle θ associated with the tilt direction. The tilt angle θ data is stored in, for example, the storage unit 26 of the control mechanism 19.

  In step S3, following the detection of the tilt angle θ in step S2, it is determined whether or not the high-speed control mode is set. If Yes, the process proceeds to step S11. If No, the process proceeds to step S4. In step S3, it is determined whether or not movement control (see step S9) of the eye characteristic measurement mechanism 31 (device main body 12) in a high-speed control mode, which will be described later, is being executed.

  In step S4, it is determined that the mode is not the high speed control mode in step S3, or the determination that the push switch 30 is not in the ON state in step S11, or the tilt angle θ in step S12 is greater than the angle threshold θl. Following the determination that it is small or the determination that the apparatus main body 12 is in the prohibited area Ap (see FIG. 10) in step S13, the movement speed corresponding to the tilt angle θ is calculated, and the movement speed is calculated. The movement of the eye characteristic measurement mechanism 31 (device main body 12) in the tilt direction is started, and the process proceeds to step S5 (movement control unit). In step S4, the moving speed at the tilt angle θ is calculated using a map showing the moving speed of the eye characteristic measuring mechanism 31 with respect to the tilt angle of the control lever 13 shown in FIG. 9 (FIG. 8). Thereafter, a command to move the eye characteristic measuring mechanism 31 toward the tilt direction side at the calculated moving speed is transmitted to the main body driving mechanism 18, and the eye characteristic measuring mechanism 31 is moved by the main body driving mechanism 18. The movement of the eye characteristic measurement mechanism 31 at the calculated movement speed is continued until the tilt angle of the control lever 13 is set to 0 degree (original state) (see the map in FIG. 9 (FIG. 8)). A basic concept of a map showing the moving speed of the eye characteristic measuring mechanism 31 with respect to the tilt angle of the control lever 13 will be described with reference to FIG. As shown in FIG. 8, this map is for the main body drive mechanism 18 for moving the apparatus main body 12, that is, the eye characteristic measurement mechanism 31 with respect to the tilt angle θ with respect to the original state (neutral position) of the control lever 13. The relationship between the rotational speed of a motor (not shown) used in the first drive unit 21 and the second drive unit 22, in other words, the tilt angle of the control lever 13 and the movement speed of the eye characteristic measurement mechanism 31 is shown. It is. Specifically, the relationship between the tilt angle θ of the control lever 13 and the pulse frequency pps of the drive voltage applied to the motor (not shown) used in the first drive unit 21 and the second drive unit 22 is shown. It is a thing. In the map shown in FIG. 8, it is assumed that the maximum tilt angle of the control lever 13 is 20 degrees, the tilt angle of the control lever 13 is proportional to the motor speed, and the control lever 13 is 20 degrees (maximum tilt angle). The motor speed is set to 7000 pps at the time (hereinafter, movement control using this characteristic line is referred to as normal speed control, and the eye characteristic measuring mechanism 31 is moved by this normal speed control. Is called normal control mode). Further, in this map, a characteristic line (refer to a one-dot chain line) that makes the motor speed faster than the characteristic line in the normal control mode with respect to a value that is larger than the angle threshold value θl when viewed from the tilt angle. Regardless of the tilt angle, a characteristic line (refer to the alternate long and short dash line) that sets the motor speed to 30000 pps is set (hereinafter, movement control using this characteristic line is referred to as high-speed speed control. The movement of the measurement mechanism 31 is referred to as a high speed control mode). This one-dot chain line characteristic line is used when the mode is changed to the high-speed control mode, as will be described later. The characteristic line in the high-speed control mode may be any motor speed that is faster than the characteristic line in the normal control mode when viewed from the same tilt angle. For example, as shown by a two-dot chain line, the control lever 13 is tilted. The angle and the motor speed may be proportional to each other, and the motor speed may be set to 30000 pps when the control lever 13 is at the maximum tilt angle. In the first embodiment, as shown in FIG. 9, a map in which the angle threshold θl is set to 19 degrees is used for calculating the moving speed according to the tilt angle θ. In the map of FIG. 9, the change in motor speed with respect to the tilt angle of the control lever 13 is a staircase in consideration of the output characteristics of motors (not shown) used in the first drive unit 21 and the second drive unit 22. In other words, the angle between 0 degree and the maximum tilt angle is divided into a plurality of angle ranges, and the motor speed corresponding to each angle range is set to increase stepwise. Further, in the map of FIG. 9, a characteristic line (refer to the alternate long and short dash line) of the high speed control mode for increasing the motor speed from 7000 pps to 30000 pps is set between the angle threshold θl of 19 degrees and the maximum tilt angle of 20 degrees. Has been. In this step S4, the movement control in the normal control mode is started, that is, the movement speed corresponding to the tilt angle θ is calculated using the characteristic line (see solid line) of the normal control mode in the map of FIG. The normal speed control for moving the eye characteristic measurement mechanism 31 (device main body 12) toward the tilt direction is started. Note that this map is stored in the storage unit 26 in the control mechanism 19, and the control unit 25 performs the above calculation by appropriately reading from the storage unit 26.

  In step S5, following the start of movement control of the eye characteristic measurement mechanism 31 (device main body 12) in step S4, it is determined whether or not the tilt angle θ is larger than the angle threshold θl. If Yes, the process proceeds to step S6. If No, go to Step S14. In step S5, it is determined whether the control lever 13 is tilted beyond the angle threshold θl regardless of the tilt direction in order to determine whether the function of the push switch 30 is switched. Further, in step S5, when the notification symbol I (see FIG. 11) is displayed on the display 17 as described later and it is determined No (after returning to step S1 through step S7 described later, the process can proceed to step S5). Display of the notification symbol I is stopped.

  In step S6, following the determination that the tilt angle θ is larger than the angle threshold θl in step S5, it is determined whether or not the apparatus main body 12 is in the prohibited region Ap (see FIG. 10). It progresses to step S10, and in No, it progresses to step S7. In step S6, based on the signal from the main body position detector 34, whether or not the position on the base 11 of the apparatus main body 12 that houses the eye characteristic measurement mechanism 31 is the prohibited area Ap (see FIG. 10). Judging. Further, in step S6, as described later, when the notification symbol I (see FIG. 11) is displayed on the display 17 and it is determined to be Yes (step S6 which will be described later returns to step S1 after step S6 can proceed to step S6). Display of the notification symbol I is stopped. In the first embodiment, the prohibited area Ap is an area in which the apparatus main body 12 can be relatively moved when the base 11 is viewed in the XZ plane as shown in FIG. Af), a band-like region having a width of 10 mm from the end on the subject side (Z-axis direction plus side) (the movement limit position on the plus side in the Z-axis direction) to the examiner side (minus side in the Z-axis direction) Is set. Here, the movable area Af is a rectangular area formed by the movable range in the X-axis direction and the movable range in the Z-axis direction in the first embodiment, and in FIG. The reference position is schematically shown as an area that can be moved on the XZ plane. In the first embodiment, the forbidden area Ap is a proximity that gives a feeling of pressure to the subject in a state where the chin is placed on the chin rest 15 and the forehead 16 is brought into contact with the forehead pad 16 to face the main body 12. It is set from the viewpoint of preventing the movement of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the position in the high-speed control mode described later. Therefore, the prohibited area may be set by changing the width viewed in the Z-axis direction according to the shape of the surface of the apparatus main body 12 facing the subject. In addition, when the apparatus main body 12 is in the prohibition area Ap, control for notifying that effect may be performed, such as displaying it on the display 17.

  In step S7, following the determination that the apparatus main body 12 is not in the prohibited area Ap (see FIG. 10) in step S6, control (notification control) for notifying that switching to the high speed control mode is possible is performed. The process proceeds to step S8 (notification control unit). This step S7 executes notification control for notifying that the normal control mode can be changed to the high speed control mode by pressing the pressing switch 30. In the first embodiment, as shown in FIG. 11, this notification control is performed by superimposing the notification symbol I on the image of the eye E to be examined acquired by the anterior segment imaging camera 33 displayed in real time on the display 17. Is displayed. The notification control can be changed from the normal control mode (normal speed control) to the high speed control mode (high speed control) by pressing the push switch 30 (the tilt angle θ of the control lever 13 is an angle). As long as it informs the examiner that the threshold value is greater than the threshold value θl, for example, it may be displayed by characters or may be displayed by symbols, and the color of at least a part of the screen is changed. It may be displayed. In addition, if the press switch 30 is pressed to notify the examiner that the normal control mode can be changed to the high-speed control mode, a sound or sound is displayed instead. You may utilize a vibration etc.

  In step S8, following execution of the notification control in step S7, it is determined whether or not the pressing switch 30 has been pressed under a situation where the tilt angle θ is larger than the angle threshold θl. If yes, the process proceeds to step S9. In the case of No, the process proceeds to step S10 (control switching determination unit). In step S8, it is determined whether or not the pressure switch 30 is in the ON state. If the pressure switch 30 is in the ON state, the pressure operation is performed when the tilt angle θ is larger than the angle threshold θl (is greatly tilted). Therefore, it is determined whether or not it is in the ON state. If these two determinations are satisfied, “Yes” is determined. Otherwise, “No” is determined. This is because it is assumed that the control lever 13 is tilted while the push switch 30 is being pressed (while being in the ON state). In the first embodiment, the push switch 30 is changed from the OFF state to the ON state. This is because the control for the pressing operation to the pressing switch 30 corresponding to the tilt angle θ of the control lever 13 is switched based on the time point when the pressing operation is performed.

  In step S9, it is determined that the pressing switch 30 has been pressed in a situation where the tilt angle θ in step S8 is larger than the angle threshold θl, or the apparatus main body 12 in step S13 is in the prohibited area Ap (see FIG. 10). Following the determination that the high-speed control mode is not entered (determination that the high-speed control mode is to be continued), movement control in the high-speed control mode is started, and the process returns to step S1. In step S9, the moving speed corresponding to the tilt angle θ is calculated using the characteristic line (see the alternate long and short dash line) of the high-speed control mode in the map of FIG. 9, and the eye characteristic measuring mechanism 31 moves toward the tilt direction at the moving speed. High-speed speed control for moving (device main body 12) is started. That is, under a situation where the tilt angle θ is larger than the angle threshold θl, the control for the pressing operation to the pressing switch 30 is performed so that the pressing switch 30 functions as an operation unit for instructing execution of movement control in the high speed control mode. Is switched. In step S9, when the notification symbol I is displayed over the image of the eye E on the display 17 (see step S7), the display of the notification symbol I is stopped.

  In step S10, it is determined that the apparatus main body 12 is in the prohibited area Ap (see FIG. 10) in step S6, or the pressing switch 30 is used under the situation where the tilt angle θ in step S8 is larger than the angle threshold θl. Following the determination that the pressure switch is not operated, the eye characteristic measurement is performed only when the pressure switch 30 is in the ON state by the pressure operation in a situation where the tilt angle θ is smaller than the angle threshold value θl. Then, the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode is continued, and the process returns to step S1. In this step S10, since the control is performed in a situation where it is determined that the change to the high-speed control mode is not performed under the situation where the tilt angle θ is larger than the angle threshold value θ1, the apparatus main body 12 (eye characteristic measurement mechanism 31 in the normal control mode). ) Movement control is continued. In addition to this, in step S10, when the pressure switch 30 is turned on by a pressing operation under a situation where the tilt angle θ is smaller than the angle threshold value θl, the eye characteristic measurement mechanism 31 performs eye characteristic measurement. Execute (measurement control). As will be described later, the pressing operation to the pressing switch 30 is performed for the execution of the eye characteristic measurement by the eye characteristic measuring mechanism 31 (see Step S14 and Step S15). This is because the state is maintained. In step S10, when the press switch 30 is not in the ON state, and when the press switch 30 is in the ON state by a pressing operation under a situation where the tilt angle θ is larger than the angle threshold θ1, The eye characteristic measurement by the eye characteristic measurement mechanism 31 is not executed. In the former case, since the pressing switch 30 is not in the ON state, the execution of the eye characteristic measurement is not required. In the latter case, although the pressing switch 30 is pressed, the apparatus main body 12 is prohibited in step S6. This is because the scene is determined to be in the area Ap (see FIG. 10).

  In step S11, following the determination that the high-speed control mode is in step S3, it is determined whether or not the push switch 30 is in the ON state. If Yes, the process proceeds to step S12. If No, the process proceeds to step S4. move on. In step S11, it is determined whether or not to continue the high speed control mode from the state of the push switch 30.

  In step S12, following the determination that the pressing switch 30 is in the ON state in step S11, it is determined whether the tilt angle θ is larger than the angle threshold θl. If yes, the process proceeds to step S13, and No If so, the process proceeds to step S4. In step S12, it is determined whether or not to continue the high speed control mode from the tilted state of the control lever 13.

  In step S13, following the determination that the tilt angle θ is larger than the angle threshold θl in step S12, the apparatus main body 12 enters the prohibited area Ap (see FIG. 10) based on the signal from the main body position detector 34. If yes, the process proceeds to step S4. If no, the process proceeds to step S9. In step S13, it is determined whether or not to continue the high-speed control mode from the position of the apparatus main body 12.

  In step S14, following the determination that the tilt angle θ is smaller than the angle threshold θl in step S5, it is determined whether or not the pressing switch 30 has been pressed under a situation where the tilt angle θ is smaller than the angle threshold θl. In the case of Yes, the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode is continued and the process proceeds to step S15, and in the case of No, the apparatus main body 12 in the normal control mode (eye characteristic measurement mechanism 31). ) Movement control is continued and the process returns to step S1 (control switching determination unit). In step S14, it is determined whether or not the pressing switch 30 is in the ON state. If the pressing switch 30 is in the ON state, the pressing operation is performed when the tilt angle θ is smaller than the angle threshold θl (tilted slightly). Therefore, it is determined whether or not it is in the ON state. If these two determinations are satisfied, “Yes” is determined. Otherwise, “No” is determined. As described above, in the first embodiment, the pressing operation to the pressing switch 30 according to the tilt angle θ of the control lever 13 is based on the time when the pressing switch 30 is pressed from the OFF state to the ON state. This is because the control is switched over.

  In step S15, following the determination that the pressing switch 30 has been pressed under the situation where the tilt angle θ is smaller than the angle threshold θl in step S14, the apparatus main body 12 (eye characteristic measuring mechanism 31) in the normal control mode is operated. The eye characteristic measurement is executed while continuing the movement control, and the process returns to step S1. In step S15, since the tilt angle θ is smaller than the angle threshold θ1, the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode is continued and the eye characteristic measurement mechanism 31 is continued. Execute eye characteristic measurement by (measurement control). In other words, under a situation where the tilt angle θ is smaller than the angle threshold θl, the pressure switch 30 is pressed so that the pressure switch 30 functions as an operation unit for instructing the eye characteristic measurement mechanism 31 to execute the eye characteristic measurement. The control for the operation is switched.

  Next, the operation will be described.

  After explaining the “basic concept and its action” of the control for the operation of the control lever 13 and the push switch 30 in the ophthalmic apparatus 10 of the first embodiment, “the control action with a small tilt angle” and “the large tilt angle” Will be described separately. FIG. 12 is an explanatory diagram for explaining a basic concept of control switching for a pressing operation to the pressing switch 30 in accordance with the tilt angle θ of the control lever 13. FIG. 13 is an explanatory diagram illustrating a state in which the measurement center position is relatively moved on the image of the eye E to be examined.

"Basic concepts and their actions"
In the ophthalmologic apparatus 10 according to the present invention, the control unit 25 of the control mechanism 19 determines whether or not the tilt angle θ of the control lever 13 exceeds the angle threshold θl in detail according to the tilt angle of the control lever 13. By judging the above, the control for the pressing operation to the pressing switch 30 is switched.

  That is, as shown in FIG. 12, the control unit 25 of the control mechanism 19 basically moves the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode in response to the tilting operation to the control lever 13. Control (normal speed control) is performed (see step S4). Here, when the tilt angle θ is smaller than the angle threshold value θl, when the push switch 30 is pressed and turned on, the eye characteristic measurement by the eye characteristic measurement mechanism 31 is executed (see step S14 and step S15). ). When the tilt angle θ is larger than the angle threshold θl, when the push switch 30 is pressed and turned on, the movement control (high speed speed) of the apparatus body 12 (eye characteristic measurement mechanism 31) in the high speed control mode is performed. Control) (see step S9).

  For this reason, the examiner can adjust the position of the eye characteristic measurement mechanism 31 (device main body 12) by tilting the control lever 13, and when the tilt angle θ is smaller than the angle threshold θl. The eye characteristic measurement can be executed by pressing the push switch 30. When the tilt angle θ is larger than the angle threshold θl, the device body 12 (eye characteristic measurement) is operated by pressing the push switch 30. The mechanism 31) can be moved at high speed. Therefore, unlike the above-described ophthalmic apparatus of Patent Document 2, it is not necessary to care about the speed of the tilting operation of the control lever 13, so that the tilting operation of the control lever 13 is easy and the eye characteristic measuring mechanism 31 (device main body) The case where 12) is moved for position adjustment and the case where the eye characteristic measuring mechanism 31 (device main body 12) is moved at high speed can be easily changed. Further, when changing the movement speed in the coarse movement operation with the speed adjustment switch as in the above-described ophthalmic apparatus of Patent Document 2, the pressing operation of the speed adjustment switch is repeated many times, or the speed adjustment switch is rotated. Although it is conceivable that the push switch 30 is pressed once for changing the mode of the command for executing the eye characteristic measurement or the movement control, the above-described operation can be easily performed. In particular, in the first embodiment, since the pressing switch 30 is provided on the tip surface of the control lever 13, the examiner can easily perform the above-described operation with one hand.

"Control action with small tilt angle"
The control action at a small tilt angle refers to the movement control of the eye characteristic measuring mechanism 31 with respect to the tilt operation to the control lever 13 under the situation where the tilt angle θ of the control lever 13 is smaller than the angle threshold θl, and the control to the push switch 30. This refers to the action of controlling the pressing operation. The control unit 25 of the control mechanism 19 performs the control of the pressing operation to the pressing switch 30 under the situation where the tilt angle θ of the control lever 13 is smaller than the angle threshold θl, and performs the eye characteristic measurement by the eye characteristic measuring mechanism 31. Switch to instructions.

  That is, when the control lever 13 is tilted and the tilt angle θ is smaller than the angle threshold θl, the process proceeds from step S1 to step S2 to step S3 to step S4 in the flowchart of FIG. The movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode is started, the process proceeds from step S5 to step S14, and the process returns from step S14 to step S15 to step S1 or directly returns to step S1. Thus, the movement control of the apparatus main body 12 (eye characteristic measuring mechanism 31) in the normal control mode is continued. At this time, when the pressing switch 30 is pressed, it is determined in step S14 that the pressing switch 30 has been pressed under a situation where the tilt angle θ is smaller than the angle threshold value θl, and the process proceeds to step S15 and the eye characteristics. The eye characteristic measurement by the measurement mechanism 31 is executed. Here, if the ON state is maintained by the pressing operation of the pressing switch 30, the process returns from step S15 to step S1, and from step S1, step S2, step S3, step S4, step S5, step S14, and step S15. Since the eye characteristic measurement by the eye characteristic measurement mechanism 31 is executed again, the eye characteristic measurement by the eye characteristic measurement mechanism 31 is repeated at a fixed timing.

  Further, in a situation where the ON state of the pressing switch 30 is maintained by a pressing operation under a situation where the tilt angle θ is larger than the angle threshold θl, the control lever 13 is tilted and the tilt angle θ is smaller than the angle threshold θl. If the high-speed control mode is selected, the process proceeds to step S1, step S2, step S3, step S11, step S12, step S4, step S5, and step S14. In the normal control mode, step S1 to step S2 to step The process proceeds from step S3 to step S4 to step S5 to step S14. In step S14, it is determined that the pressing switch 30 has not been pressed under a situation where the tilt angle θ is smaller than the angle threshold θl, and step S1 is directly performed. By returning to the main body 12 (eye) in the normal control mode. Continued movement control sexual measuring mechanism 31). That is, the control lever 13 is tilted while the ON state of the push switch 30 is maintained by the pressing operation under the situation where the tilt angle θ is larger than the angle threshold θl, and the tilt angle θ becomes smaller than the angle threshold θl. In this case, the apparatus main body 12 in the normal control mode (eye characteristics) is not performed until the eye characteristics measurement mechanism 31 performs the eye characteristics measurement until the pressing operation to the pressure switch 30 is once released (turned off). The movement control of the measurement mechanism 31) is continued. In other words, when the pressing operation on the pressing switch 30 is once released (turned off) and then turned on by the pressing operation on the pressing switch 30, the tilt angle θ is set to the angle threshold value in step S14. Since it is determined that the pressing switch 30 has been pressed under a condition smaller than θl, the process proceeds to step S15, and eye characteristics measurement by the eye characteristics measuring mechanism 31 is executed.

  As described above, when the control lever 13 is tilted and the tilt angle θ is smaller than the angle threshold θl, the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode is continued. When the state is newly turned on by a pressing operation to the pressing switch 30, eye characteristics measurement by the eye characteristics measuring mechanism 31 is executed.

  Therefore, as shown in FIG. 13, the examiner tilts the control lever 13 while viewing the image of the eye E displayed on the display 17, so that the apparatus main body 12 in the normal control mode, that is, the eye characteristics is displayed. The position of the eye can be adjusted by moving the measuring mechanism 31 and pressing the pressing switch 30 provided on the front end surface of the control lever 13 at any position P1, P2 of the eye E. It can be performed. That is, when the position of the apparatus main body 12 (eye characteristic measurement mechanism 31) relative to the eye E (subject) is adjusted by tilting the control lever 13, the display 17 uses the measurement optical axis of the eye characteristic measurement mechanism 31 on the display 17. The image of the eye E to be moved moves with respect to a certain measurement center Ma, and the eye characteristic can be measured at the point where the measurement center Ma is located when the pressing switch 30 is pressed. The eye characteristics can be measured at arbitrary positions P1 and P2 in the eye E. In other words, since the examiner can cause the eye characteristic measurement to be executed by pressing the push switch 30 while the control lever 13 is tilted, the eye characteristic measuring mechanism 31 (apparatus body) is used for position adjustment. 12), the eye characteristic measurement can be performed without missing the timing at which the measurement center Ma that moves relatively on the eye E is at a desired position. This is because, for example, the auto-alignment function aligns the eye characteristic measuring mechanism 31 with respect to the corneal center of the eye E, so that the eye E has a keratoconus or corneal disease (corneal erosion, corneal ulcer, etc.) In this case, there is a possibility that the auto-alignment function does not work correctly (cannot be accurately aligned). However, by measuring the eye characteristics at an arbitrary position of the eye E to be measured, even under the above conditions, the measurement is appropriately performed. Make it possible.

"Control action at large tilt angles"
The control action at a large tilt angle refers to the movement control of the eye characteristic measuring mechanism 31 with respect to the tilt operation to the control lever 13 under the situation where the tilt angle θ of the control lever 13 is larger than the angle threshold θl, and to the push switch 30. This refers to the action of controlling the pressing operation. The control unit 25 of the control mechanism 19 moves the apparatus main body 12 (eye characteristic measurement mechanism 31) to control the pressing operation to the pressing switch 30 under the situation where the tilt angle θ of the control lever 13 is larger than the angle threshold θl. Switch control to change to high speed control mode.

  That is, when the control lever 13 is tilted and the tilt angle θ is larger than the angle threshold θl (assuming that the control lever 13 is not in the high speed control mode), step S1 → step S2 → step S3 → Proceeding to step S4, the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode is started in step S4, the process proceeds from step S5 to step S6, and the apparatus main body 12 is prohibited in step S6. If it is not in the area Ap (see FIG. 10), the notification symbol I is displayed on the display 17 in step S7, and the process proceeds to step S8. At this time, when the pressing switch 30 is pressed, it is determined in step S8 that the pressing switch 30 has been pressed under a situation where the tilt angle θ is larger than the angle threshold value θl, and the process proceeds to step S9 to proceed to the high speed control mode. The movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) is started. Here, when the apparatus main body 12 is in the prohibited area Ap (see FIG. 10) or when the pressing switch 30 is not pressed under a situation where the tilt angle θ is larger than the angle threshold θ1, normal control is performed. The movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the mode is maintained.

  Further, when the tilt angle θ of the control lever 13 is larger than the angle threshold θl and the high-speed control mode is set, the process proceeds from step S1 to step S2 to step S3 to step S11 in the flowchart of FIG. If the pressure switch 30 is not in the ON state, the process proceeds to step S4, and the operation is the same as described above. If the pressure switch 30 is in the ON state in step S11, the process proceeds from step S12 to step S13. If the main body 12 is in the prohibited area Ap (see FIG. 10), the process proceeds to step S4 and the operation is the same as described above. In step S13, the apparatus main body 12 is not in the prohibited area Ap (see FIG. 10). Proceeding to step S9, movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the high-speed control mode is performed. Continue.

  Further, in the scene where the ON state of the pressure switch 30 is maintained by the pressing operation under the situation where the tilt angle θ is smaller than the angle threshold θl, the control lever 13 is tilted and the tilt angle θ is larger than the angle threshold θl. In this case, the process proceeds from step S1, step S2, step S3, step S4, step S5, and step S6. If the apparatus main body 12 is in the prohibited area Ap (see FIG. 10) in step S6, the process proceeds to step S10. If the apparatus main body 12 is not in the prohibited area Ap (see FIG. 10) in step S6, the notification symbol I is displayed on the display 17 in step S7, and the process proceeds to step S8. In step S8, the tilt angle θ is displayed. Is determined that the pressing switch 30 is not pressed under the condition that the angle is larger than the angle threshold θl. Proceeding to step S10, it is determined in step S10 that the pressure switch 30 is in the ON state by pressing the tilt angle θ under a condition where the tilt angle θ is smaller than the angle threshold value θl. Perform characteristic measurements. That is, the control lever 13 is tilted and the tilt angle θ becomes larger than the angle threshold θl by maintaining the ON state of the push switch 30 by the pressing operation under the situation where the tilt angle θ is smaller than the angle threshold θl. In this case, the normal control is performed without changing to the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the high-speed control mode until the pressing operation to the pressing switch 30 is once released (turned off). The eye characteristic measurement by the eye characteristic measurement mechanism 31 is executed while continuing the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the mode. In other words, when the pressing operation on the pressing switch 30 is once released (turned off) and then turned on by the pressing operation on the pressing switch 30, the tilt angle θ is set to the angle threshold value in step S8. Since it is determined that the pressing switch 30 has been pressed under a condition larger than θl, the process proceeds to step S9 to execute movement control of the apparatus main body 12 (eye characteristic measuring mechanism 31) in the high speed control mode.

  As described above, when the control lever 13 is tilted and the tilt angle θ is larger than the angle threshold θl, when the control lever 13 is newly turned on by the pressing operation to the pressing switch 30, The movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) is executed.

  For this reason, when the examiner greatly tilts the control lever 13 (tilt operation exceeding the angle threshold θl) to greatly move the apparatus body 12 (eye characteristic measurement mechanism 31), the apparatus body 12 (eye characteristic measurement mechanism). When the position adjustment of 31) is performed, the apparatus main body 12 (eye characteristic measurement mechanism 31) can be moved in the normal control mode by only performing the tilting operation of the control lever 13, and the apparatus main body 12 (eye) can be moved more quickly. When it is desired to move the characteristic measuring mechanism 31), the device main body 12 (eye characteristic measuring mechanism 31) is moved in the high-speed control mode by pressing the pressing switch 30 provided on the front end surface of the control lever 13 ( Move at high speed). That is, when the control lever 13 is operated to tilt more than the angle threshold value θl, the examiner presses the pressing switch 30 to control the movement of the apparatus body 12 (eye characteristic measuring mechanism 31) in the normal control mode and the high speed control. In the normal control mode, the moving speed of the apparatus main body 12 can be changed according to the change by changing the tilt angle θ even between the angle threshold θl and the maximum tilt angle. Yes (see map in FIG. 8). In particular, as described above, if the characteristic line of the high-speed control mode has a proportional relationship between the tilt angle of the control lever 13 and the motor speed (see the two-dot chain line in FIG. 8 and the one-dot chain line in FIG. 9), Even if it exists, by changing the tilt angle θ between the angle threshold θl and the maximum tilt angle, the moving speed of the apparatus main body 12 can be changed according to the change.

  Further, the examiner performs the movement control of the apparatus main body 12 (eye characteristic measuring mechanism 31) from the normal control mode to the high-speed control mode by the pressing operation of the push switch 30 by the notification symbol I (see FIG. 9) displayed on the display 17. It can be recognized that the change can be made. Therefore, the eye characteristic measurement mechanism 31 (device main body 12) can be moved by the tilting operation of the control lever 13 without taking the eyes off the image of the eye E to be examined, and the position adjustment can be made easier. it can.

  Further, when the control lever 13 is tilted more than the angle threshold value θl, the movement control is continued from the normal control mode to the high-speed control mode while continuing the movement control of the apparatus main body 12 (eye characteristic measurement mechanism 31) in the normal control mode. Can be changed to the high-speed control mode as appropriate without stopping the movement of the eye characteristic measurement mechanism 31 (device main body 12), and the control lever 13 is tilted to the limit. Even if it is a case, the movement of the eye characteristic measurement mechanism 31 (device main body 12) in the normal control mode can be maintained. On the other hand, in the above-described ophthalmologic apparatus of Patent Document 2, since the coarse control operation is performed when the control lever is tilted to the limit, the control is performed even when the coarse control operation is not desired. If the lever reaches the limit tilt angle, the coarse operation is forcibly performed. Therefore, a delicate tilt operation of the control lever is required. In addition, in the above-described ophthalmic apparatus of Patent Document 2, it is also described that a switch that disables the coarse movement operation when the control lever reaches the limit tilt angle is provided. The movement of the characteristic measurement mechanism (measurement unit) will be stopped.

  Next, since the control for the pressing operation to the pressing switch 30 is switched depending on whether the tilting angle θ of the control lever 13 is larger than the angle threshold θl, the tilting operation performed on the control lever 13 is controlled by the control mechanism. Since the function of the control lever mechanism 20 for transmitting to the 19 control units 25 can be used as it is, it is not necessary to provide a new part for switching the control. On the other hand, in the above-described ophthalmologic apparatus of Patent Document 2, it is necessary to provide a detection unit for detecting that the control lever is tilted to the limit.

  When the control lever 13 is tilted larger than the angle threshold value θl, if it is determined in step S6 that the apparatus main body 12 is in the prohibited area Ap (see FIG. 10), the pressing switch 30 is pressed. Since the normal control mode is not changed to the high-speed control mode, the apparatus main body 12 can be reliably prevented from being moved in the high-speed control mode near the subject. It can be prevented that a feeling of pressure is given to the subject due to the movement. Here, when the apparatus main body 12 is in the prohibited area Ap (see FIG. 10), the notification symbol I (see FIG. 9) appears on the display 17 even if the control lever 13 is tilted larger than the angle threshold value θl. Is not displayed (the process proceeds from step S6 to step S10), the examiner does not feel uncomfortable.

  Next, the effect will be described.

  In the ophthalmologic apparatus of Example 1, the effects listed below can be obtained.

  (1) Eye characteristics including an optical system for measuring the subject's eye E with respect to the base 11 provided with the holding portions (15 and 16) for holding the subject's face to be fixed. A moving mechanism (18) for electrically moving the measurement unit (31) and a tilting operation performed on the control lever 13 to adjust the position of the eye characteristic measurement unit (31) with respect to the eye E to be examined are electrically performed. An electric control lever mechanism 20 that outputs as a signal, and a control command for the movement speed of the eye characteristic measuring unit (31) according to the tilt angle of the control lever 13 based on the signal from the control lever mechanism 20 Then, normal speed control (step S4) to be transmitted to the moving mechanism (18) is performed, and a control command for executing the eye characteristic measurement of the eye E is generated to the eye characteristic measuring unit (31). An ophthalmologic apparatus 10 comprising: a control mechanism 19 that performs measurement control (step S15) to be transmitted; and an operation unit (30) that outputs an intermittent operation performed by itself to the control mechanism 19 as an electrical signal. The control mechanism 19 detects the intermittent operation to the operation unit (30) when the tilt angle of the control lever 13 is smaller than an angle threshold value θl set in advance for the tilt operation to the control lever 13. Then, the measurement control is performed while continuing the normal speed control. When the tilt angle of the control lever 13 is larger than the angle threshold value θl, when the intermittent operation to the operation unit (30) is detected, the normal speed control is started. The speed is changed to high speed control (step S9) in which the eye characteristic measuring unit (31) is moved at a moving speed larger than the normal speed control. For this reason, the operativity by the control lever 13 of the mounted electric control lever mechanism 20 can be improved.

  (2) The control mechanism 19 sets a movement speed based on a correspondence relationship (FIGS. 8 and 9) between a preset tilt angle of the control lever 13 and a movement speed of the eye characteristic measurement unit (31). To do. For this reason, in the normal speed control and the high speed control, the manner of movement of the eye characteristic measuring unit (31) can be made unambiguous with respect to the tilting operation to the control lever 13, and the operability by the control lever 13 is improved. Can be improved.

  (3) When the tilt angle of the control lever 13 is larger than the angle threshold θl and the control mechanism 19 does not detect the intermittent operation to the operation unit (30), the control mechanism 19 Notification control (step S7) is performed to notify that the normal speed control can be changed to the high speed control by the intermittent operation to 30). Therefore, the examiner can recognize that the normal speed control can be changed to the high speed control by the intermittent operation to the operation unit (30), and the operability by the control lever 13 can be improved. .

  (4) The operation unit (30) is a press switch 30 provided on the control lever 13 and pressed for intermittent operation. For this reason, the examiner can easily issue a command for executing eye characteristic measurement and a command for changing from normal speed control to high speed control with one hand.

  (5) The control lever mechanism 20 returns the control lever 13 to its original state when the urging force applied to the control lever 13 is released while the control lever 13 is tilted. Therefore, once the control lever 13 is released, the control lever 13 is further finely adjusted by tilting from the original state (tilt angle 0 degree) with reference to the eye characteristic measurement unit (31) after fine adjustment. Can do.

  (6) The control mechanism 19 includes a position detection unit (34) that detects the position of the eye characteristic measurement unit (31) with respect to the base, and the position of the eye characteristic measurement unit (31) is set in advance. If the tilt angle of the control lever 13 is larger than the angle threshold value θl, even if an intermittent operation to the operation unit (30) is detected, the high speed control is performed from the normal speed control. Do not change to. For this reason, for example, when the eye characteristic measurement unit (31) sets the prohibited area at a position close to the subject, the eye characteristic measurement unit (31) is reliably moved at a high speed at the position close to the subject. Therefore, it is possible to prevent the subject from being given a feeling of pressure due to the movement under the high speed control.

  In the first embodiment described above, the prohibited area is provided. However, the normal speed control is executed in response to the tilting operation to the control lever, and when the control lever is tilted smaller than the angle threshold, When the control lever is tilted more than the angle threshold, the normal speed control is changed to the high speed control by the intermittent operation to the operation unit. As long as it is a thing, it is not necessary to provide a prohibited area.

  In the first embodiment described above, the prohibition area is set at a position where the apparatus main body 12 is close to the subject in the movable area Af. However, the movement control of the apparatus main body 12 in the high-speed control mode is limited. However, the position is not limited to that of the first embodiment as long as it is set to a desirable position or a position where movement control of the apparatus main body 12 in the high-speed control mode is not required. For example, since it is considered that movement control of the apparatus main body 12 in the high-speed control mode is not required in a predetermined area centered on the alignment position, the area may be set as a prohibited area. With this setting, it is possible to prevent the apparatus main body 12 from being moved at high speed despite being in the vicinity of the alignment position.

  Furthermore, in the first embodiment described above, the control lever 13 is provided on the front end surface of the control lever 13 as an operation unit that is a target for switching control with respect to the pressing operation (intermittent operation) according to the tilt angle of the control lever 13. The push switch 30 is shown, but it outputs the intermittent operation performed by itself to the control mechanism 19 (its control unit 25) and is provided at a location where the subject can easily perform the intermittent operation. However, the present invention is not limited to the first embodiment.

  In the first embodiment described above, the angle threshold value θl is set to 19 degrees, but it can be set to any value between 0 degrees and the maximum tilt angle when viewed from the tilt angle of the control lever 13. Here, the angle threshold value θl takes into consideration the characteristic line of the normal control mode, the moving speed required to perform the eye characteristic measurement while moving the eye characteristic measurement mechanism 31 (device main body 12), and the eye at high speed. It is desirable to set in consideration of the tilt angle θ required to move the characteristic measuring mechanism 31 (device main body 12).

DESCRIPTION OF SYMBOLS 10 Ophthalmological apparatus 11 Base 13 Control lever 15 Jaw holder (as holding part) 16 Forehead rest (as holding part) 18 Main body drive mechanism (as moving mechanism) 19 Control mechanism 20 Control lever mechanism 30 (As operation part) ) Push switch 31 Eye characteristic measuring mechanism (as an eye characteristic measuring unit) 34 Body position detecting unit (as a position detecting unit) E Eye to be examined Ap Forbidden region θl Angle threshold

Claims (6)

An eye characteristic measuring unit including an optical system for measuring an eye characteristic of the subject's eye is electrically moved with respect to a base provided with a holding unit that holds the face of the subject to be fixed. A moving mechanism;
An electric control lever mechanism that outputs, as an electrical signal, a tilting operation performed on the control lever to adjust the position of the eye characteristic measurement unit with respect to the eye to be examined;
Based on the signal from the control lever mechanism, normal speed control is performed for generating a control command for the movement speed of the eye characteristic measurement unit according to the tilt angle of the control lever and transmitting it to the movement mechanism, and A control mechanism for performing measurement control for generating and transmitting a control command for execution of ophthalmic characteristic measurement of the optometry to the ophthalmic characteristic measurement unit;
An ophthalmologic apparatus comprising: an operation unit that outputs an intermittent operation performed by itself to the control mechanism as an electrical signal;
When the tilt angle of the control lever is smaller than a preset angle threshold for the tilt operation to the control lever, the control mechanism continues the normal speed control when detecting an intermittent operation to the operation unit. When the control control is performed and the tilt angle of the control lever is larger than the angle threshold value, when the intermittent operation to the operation unit is detected, the eye characteristic is moved from the normal speed control to a higher moving speed than the normal speed control. An ophthalmologic apparatus characterized by changing to high-speed speed control for moving the measurement unit.   The ophthalmologic apparatus according to claim 1, wherein the control mechanism sets a movement speed based on a correspondence relationship between a preset tilt angle of the control lever and a movement speed of the eye characteristic measurement unit.   The control mechanism is a case where the tilt angle of the control lever is larger than the angle threshold value, and when the intermittent operation to the operation unit is not detected, the normal speed control is performed by the intermittent operation to the operation unit. The ophthalmologic apparatus according to claim 1, wherein notification control is performed to notify that the high-speed speed control can be changed.   The ophthalmologic apparatus according to any one of claims 1 to 3, wherein the operation unit is a push switch provided on the control lever and pressed for an intermittent operation.   2. The control lever mechanism according to claim 1, wherein when the biasing force to the control lever is released in a state where the control lever is tilted, the control lever is returned to the original state. Item 5. The ophthalmologic apparatus according to any one of items 4. The control mechanism includes a position detection unit that detects a position of the eye characteristic measurement unit with respect to the base, and when the position of the eye characteristic measurement unit is in a preset prohibited region, 6. The change from the normal speed control to the high speed speed control is not performed even if an intermittent operation to the operation unit is detected when a tilt angle is larger than the angle threshold. The ophthalmic apparatus according to any one of the above.

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