KR101105855B1 - Optometric System - Google Patents

Abstract

It is to provide an economically advantageous optometry system with less redundancy.

The optometry system includes a measurement optical system that transmits the measurement light to the eye fundus of the subject's eye and receives the measurement light reflected from the eye fundus, an observation optical system that captures the shape of the eye of the subject's eye, and the measurement optical system and the observation optical system are arranged. A measurement unit and a moving unit for moving the measurement unit with respect to the eye of the examinee, and having an angle-of-eye refractive power measuring device for measuring the refractive power of the eye of the examinee in an objective manner, a swash window, and a plurality of optical elements are arranged in each A plurality of lens chamber units, each of which has a plurality of lens disks disposed in each of the plurality of lens disks, and includes a subjective eye refractive power measuring apparatus for subjectively measuring the refractive power of the subject's eye, and a measuring mode of the system in the angle measuring mode and the subject measuring mode. Measurement mode switching means for inputting a switching signal for switching to any one, a monitor for inputting an operating signal In the steering angle measurement mode, the measurement information of the steering angle measuring device including the shape of the front part is displayed on the monitor by the observation optical system based on the means and the input switching signal, and the driving of the steering angle measuring device based on the operation signal of the operating means. In the subjective measurement mode, the display unit displays the measurement information of the subjective measuring device on a monitor and controls the driving of the subjective measuring device based on the operation signal of the operating means.

Penetration measuring device, subjective measuring device

Description

Optometry System

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram of the whole optometry system which is 1st Embodiment of this invention. 2 is a schematic block diagram of a control system of the entire optometry system according to the first embodiment. It is a schematic block diagram of the angle-of-eye refractive power measuring apparatus of 1st Embodiment.

4 is a schematic configuration diagram of a tray on which an angle-of-eye refractive power measuring apparatus is mounted.

5 is a view for explaining the function of the operation unit in the steering angle measurement mode.

6 is a view for explaining the function of the operation unit in the subjective measurement mode.

It is a schematic block diagram of the whole optometry system which is 2nd Embodiment of this invention.

The present invention relates to an optometry system for measuring the eye of a subject.

An optometry system for examining an eye of a subject includes a subjective eye refractive power measuring apparatus called a refractor and a poropter, which generally measures the power of the subject's eyes. A target presenting device for presenting a target (optotype, chart, etc.) to the eye, an operating member such as a subjective eye refractive power measuring device and a switch for operating the target presenting device, a monitor for displaying measurement information, etc. It is known to include an angle-of-eye refractive power measuring device called a refractometer for objectively measuring the controller and the subject's eye.

The angle-of-eye refractive power measuring apparatus used in the conventional optometry system is a static apparatus normally used alone, and has an operating member such as a switch for operating the apparatus, a monitor for displaying measurement information such as alignment information, and the like. Therefore, there are many overlapping parts (components) in the optometry system composed of the subjective eye power measuring device, the angle eye power measuring device, and the like.

SUMMARY OF THE INVENTION The present invention has been made in view of the problems of the prior art, and an object of the present invention is to provide an economically advantageous optometry system with fewer overlapping parts.

(1) In order to solve the above problems, the optometry system is a measurement optical system that transmits the measurement light to the fundus of the subject's eye, and receives the measurement light reflected from the fundus, an observation optical system for imaging the shape of the front part of the subject's eye, And a measurement unit on which the measurement optical system and the observation optical system are disposed, and a moving unit for moving the measurement unit with respect to the eye of the examinee, and having an angled eye refractive power measuring apparatus for measuring the refractive power of the eye of the examinee in an objective manner. A subjective eye refractive power measuring apparatus which includes a left and right lens chamber unit in which a plurality of lens disks each having a plurality of optical elements are arranged, respectively, and subjectively measure the refractive power of an eye of an examinee, a measurement mode of a system Measurement mode switching means for inputting a switching signal for switching between the steering angle measurement mode and the subjective measurement mode; Based on the monitor, the operating means for inputting the operation signal, and the input switching signal, in the steering angle measurement mode, the measurement information of the steering angle measuring device including the shape of the eyepiece is displayed on the monitor by the observation optical system, A control means for controlling the driving of the subjective measuring device on the basis of the control, and displaying the measurement information of the subjective measuring device on the monitor in the subjective measuring mode, and controlling the driving of the subjective measuring device based on the operation signal of the operating means. It is characterized by.

(2) In the optometry system of (1), preferably, the control means controls the drive of the moving means based on the operation signal of the operation means in the steering angle measurement mode.

(3) In the optometry system according to (1) or (2), preferably, the control means includes rotation of the lens disk based on an operation signal of the operation means in the subjective measurement mode. Control the drive.

(4) In the optometry system of (1), preferably, the monitor has a touch panel function, and the control means uses a switch or a button as the operation means for each measurement mode based on an input switching signal. Display on the monitor.

(5) The optometry system of the above (1), preferably further includes a printer for outputting measurement data by the angle measuring device and measurement data by the subjective measuring device.

(6) In the optometry system of (1), preferably, the apparatus further includes a target presentation device for presenting a target in the eye of the examinee, and the control means is configured to read the presentation target information of the target presentation device in the subject measurement mode. It displays on a monitor and controls the drive of the said target presentation device based on the operation signal of the said operation means.

(7) In the optometry system of (1), preferably, a table, a rudder measuring device, and a tray movable between the measuring position and the retracted position on the table, and the tray are measured. The sensor further comprises a sensor for detecting at least one of being disposed at a position and being disposed at a retracted position, wherein the measurement mode switching means includes a sensor, and inputs a detection signal of the sensor as a switching signal.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of this invention is described based on drawing. 1 is a schematic configuration diagram of an entire optometry system according to the first embodiment, and FIG. 2 is a schematic block diagram of a control system of the entire optometry system according to the first embodiment. The optometry system includes a table 10, a subjective eye refractive power measuring device 1, a target presentation device 20 and a target eye refractive power measuring device 30.

The subjective measuring device 1 suspended from the arm 12 extended from the support 11 of the table 10 has one lens chamber unit 2 and a support unit 3 that suspends and supports the lens chamber unit 2. Inside each lens chamber unit 2, a plurality of lens disks having a plurality of optical elements and openings arranged on the same circumference are rotatably arranged, and the optical elements or openings of the respective lens disks are switched to the window 4 Is placed. In addition, a spherical lens, a main surface lens, a cross cylinder lens, and the like are disposed on each lens disk as an optical element, and the spherical lens and the main surface lens are arranged at predetermined frequency steps. In addition, the structure of this subjective measuring device 1 is well-known, The description is abbreviate | omitted.

The target presentation device 20 is provided at a position away from the subjective measuring device 1 by a predetermined distance (for example, 1 m). In the target presentation device 20, a target presentation unit 21 having a rotatable target disk, an illumination light source, and the like and a target presentation optical system having a beam splitter 22, a concave mirror 23, a window 24, and the like are disposed, As a result, the target presentation distance is a predetermined distance (for example, 5 m). The structure of this target presentation apparatus 20 is well-known, The detailed description is abbreviate | omitted.

It is a schematic block diagram of the angle relief refractive index measuring apparatus of 1st Embodiment. The steering angle measuring device 30 is a face 31 (head) support unit 32 fixed to the base 31 with a pedestal 31, a jaw receptor 32a, a movable table 33 movably disposed on the pedestal 31, and a measurement unit movably disposed on the movable table 33. Contains 34. Inside the measurement unit 34, an eye refractive power measurement optical system 34a, an anterior eye part observation optical system 34b, and the like are disposed. The measurement optical system 34a includes a light transmission optical system that transmits the measurement light to the fundus of the eye of the examinee, and a light receiving optical system that receives the measurement light reflected from the fundus with the light receiving element. By the way, based on the output of the light-receiving element, the refractive power (spherical power S, main surface (astigmatism) frequency C, main surface (astigmatism) axial angle A, etc.) of the examinee's eye is required. The observation optical system 34b has an imaging lens, an imaging element, or the like arranged in an optical path branched from the optical path of the measurement optical system 34a by a beam split or the like, and the shape of the front part of the eye of the examinee is imaged by the imaging element. By the way, the image of the front eye region captured is displayed on the monitor 37 provided in the movement table 33. In addition, the structure of this steering angle measuring device 30 is well-known, and the detailed description is abbreviate | omitted.

The measuring unit 34 is moved in the horizontal direction (X direction), the vertical direction (Y direction), and the front-rear direction (Z direction) with respect to the eye of the examinee by the moving unit 36 provided in the moving table 33. The moving part 36 has a motor, a slide mechanism, etc. provided in each of X, Y, and Z directions. In this steering angle measuring device 30, the alignment state of the measuring unit 34 with respect to the eye of the examinee is detected on the basis of the alignment index projected on the subject's eye, and the driving of the moving unit 36 is controlled based on the detection result, and the measuring unit 34 is moved (this is an automatic alignment function).

The operation unit 40 is provided on the inspector side of the movement table 33. The operation unit 40 includes a monitor 37 having a touch panel function, a joystick 35, a rotary knob (dial) 35a installed on the joystick 35, a top switch (button) 35b, and switches (buttons 38a and 38b provided near the joystick 35). do. Each operation member disposed in the operation unit 40 is used as an operation member for the rudder type measuring device 30 in the rudder angle measuring mode by switching (selection) of the measurement mode described later, and operation for the subjective measuring device 1 in the subjective measuring mode. Used as a member.

4 is a schematic configuration diagram of a tray 60 on which the steering angle measuring device 30 is mounted. FIG. 4 (a) is a diagram when the steering angle measuring device 30 is disposed (facing) in a state where the operation unit 40 is at the target presentation device 20 side, and FIG. 4 (b) shows the steering angle measuring device 30 in the state of FIG. Is the time when is placed (facing). The moving keeper 61 is movable in the direction of the arrow A in FIGS. 1 and 4 by the guide configuration (not shown) provided in the table 10. In addition, the tray 60 is rotatably supported about the rotation shaft 62 by the movable cage 61. In addition, a stopper 63 for stopping the rotation of the tray 60 is provided in the tray 60. In the stopper 63 of this embodiment, the rubber plate 63b is moved downward by the rotation operation of the rotation knob 63a, and a frictional force is generated between the rubber plate 63b and the moving cage 61, and rotation is stopped. By the way, in Table 10, the detection part 13 which detects that the steering angle measuring device 30 mounted in the tray 60 was arrange | positioned at the measurement center of the table 10, and the steering angle measuring device 30 are arrange | positioned in the retracted position of the table 10 end. The detection part 14 which detects a thing is provided. These detection parts 13 and 14 contain well-known sensors, such as a micro switch. By the way, the detection signal of the detection parts 13 and 14 is used as a switching signal which switches a measurement mode into either a steering angle measurement mode and the subjective measurement mode.

In FIG. 2, the arithmetic and control unit 70 calculates the control of each component of the steering angle measuring device 30 and the refractive power. When switching to the subjective measurement mode, the calculation control unit 70 inputs the operation signal of the operation unit 40 as the subjective measurement operation signal, and outputs it to the subjective measurement device 1 and the target presentation device 20 through the replacement unit 50. The detection signals of the detection units 13 and 14 are input to the operation control unit 70 through the replacement unit 50, and the operation control unit 70 automatically switches the measurement mode based on the detection signal.

5 is a view for explaining the function of the operation unit 40 in the steering angle measurement mode. When the steering angle measuring device 30 is arranged together with the tray 60 at the measurement position on the table 10, the detection signal of the detection unit 13 is input to the calculation control unit 70 and is switched to the steering angle measurement mode. When switching to the steering angle measurement mode, the arithmetic control unit 70 displays the front part portion shape 100 by the observation optical system 34b as measurement information (alignment information) for steering angle measurement on the monitor 37. When the inspector manipulates the joystick 35 and the rotary knob 35a while observing the anterior eye shape 100 displayed on the monitor 37, the measuring part 34 is moved by the moving part 36. In other words, when the joystick 35 is tilted back and forth, left and right, the operation signal is input to the operation control unit 70, and the measurement unit 34 by the moving unit 36 is moved in the X direction and the Z direction. Moreover, when the rotation knob 35a is rotated, the operation signal is input to the calculation control part 70, and the measuring part 34 by the moving part 36 moves to a Y direction. By this, the joystick 35 and the rotary knob 35a are used for manual alignment for the meticulous alignment until the automatic alignment is activated, for the alignment of the subject's eyes which is not directed to the automatic alignment, and the like. Automatic alignment and manual alignment can be switched by the alignment switching switch (button) 105 displayed on the monitor 37. In addition, it is preferable that the movement of the X direction of the measurement part 34 of manual alignment is performed by moving the movement table 31 with a well-known joystick + slide mechanism via the calculation control part 70. FIG.

Further, when the switches 38a and 38b are pressed, the operation signal is inputted to the calculation control unit 70, and the jaw receptor 32a is moved in the vertical direction (Y direction) by the jaw receptor moving unit 54 having a motor, a slide mechanism, and the like. In addition, when the switch 35b is pressed, the measurement is started. The measurement data such as the obtained measurement result is displayed on the monitor 37. By the way, when the print switch (button) 106 displayed on the monitor 37 is pressed, the steering angle measurement data is output from the print 52.

In the case where the subjective measurement is continuously carried out after the end of the angle measuring, when the steering angle measuring device 30 is placed at the retracted position on the table 10 together with the tray 60, the detection signal of the detecting unit 14 is input to the calculation control unit 70 and is switched to the subject measuring mode. do. When the tray 60 is disposed in the retracted position, it is possible to change the direction of the steering angle measuring device 30 by rotating the tray 60 together with the position of the inspector so that the monitor 37 is easily visible.

6 is a diagram illustrating a function of the operation unit 40 in the subjective measurement mode. When switching to the subjective measurement mode, the arithmetic control unit 70 displays a switch (button) for inputting the measurement information for subjective measurement and an operation signal for operating the subjective measurement device 1 and the target presentation device 20 on the monitor 37. In the center of the measurement information display section 141, the current subjective measurement data (spherical power S, main surface power C, main surface axis angle A, etc.) is displayed, and next to the other angle measurement data for reference in case of subjective measurement is displayed. In the lower portion, the presently presented schedule, the next schedule in the optometry program, and the like are displayed. However, when the letter of R on the display unit 141 is pressed, the right eye measurement is selected, when the letter of L is pressed, the left eye measurement is selected, and when the letters of both eyes are pressed, both eye measurements are selected.

The setting switching switch section 143 has a switch (button) used when switching the display of the display section 141 to a menu screen to set parameters and the like. The target switching switch unit 144 has a switch (button) for switching the target presented by the target presentation device 20. The mask switching switch section 145 has a switch (button) for switching a mask caught in a part of the presented multiple targets. The measurement item instruction switch unit 146 has a switch (button) for designating a measurement item (spherical power S, main surface power C, main surface axial angle A, etc.) for adjusting the refractive power. The input data designation switch section 147 has a switch (button) for designating an item for inputting data. The input switch 148 is a switch (button) for inputting data from the steering angle measuring device 30, a lens mat not shown, or the like. The print switch 149 is a switch (button) for outputting measurement data such as measurement results. Shift key 150 is a switch for changing the function of the switch when it is pressed and another switch is pressed. The optometry program start switch 151 is a switch for starting an optometry program in which an inspection order is determined in advance.

The rotary knob 35a is used for vertical input (change) etc., and when the rotary knob 35a is rotated, the optical element arrange | positioned at the dead window 4 is switched, for example. The switch 35b is used as a switch for advancing the examination step of the optometry program stored in the memory 53. The switches 38a and 38b are used as switches for switching (rotating) the cross cylinder lens disposed in the inclined window 4 in the measurement of the principal surface power and the principal axis angle.

The steering angle measurement data obtained by the steering angle measurement device 30 is stored in the memory 53 by pressing the switch of the switch unit 147 and the input switch 148, and the optical element of the refractive power corresponding to the steering angle measurement data is arrange | positioned at the dead window 4. Thereafter, the measurement item is designated by the switch unit 146, and the subjective measurement proceeds by switching the optical elements arranged in the window 4 by the rotation knob 35a. When the optometry program by the switch 151 is executed, the switch 35b is pressed to proceed to the next inspection step. By the way, when the switch 149 is pressed, the subjective measurement data is output from the printer 52.

As described above, the operation unit 40 of the steering angle measuring device 30 functions as a controller of the subjective measuring device 1 and the target presentation device 20 in the subjective measuring mode. At this time, it is possible to reduce the overlapping parts (components) as the whole optometry system.

Moreover, although it is preferable that the operation member for rudder angle measurement and the operation member for subjective measurement are used together as possible, it is also preferable that there exists a dedicated operation member, respectively. At this time, the calculation control unit 70 disables input of the operation signal of the operation member for subjective measurement in the steering angle measurement mode. Conversely, in the subjective measurement mode, input of the operation signal of the steering angle measuring member is disabled. In addition, in the embodiment, when the monitor 37 has a touch panel function, the combined use of the operation member is effective.

In the above description, it is preferable that the measurement mode is switched in response to the arrangement position of the angle measuring device 30 mounted on the tray 60, but the switch (button) used for switching the measurement mode on the monitor 37 is preferably displayed.

It is a schematic block diagram of the whole optometry system of 2nd Embodiment. In the second embodiment, the controller of the subjective measurement device 1 and the target presentation device 20 functions as an operation unit of the steering angle measurement device 30. That is, with respect to the first embodiment in which the controller is integrally incorporated into the steering angle measuring device 30, the controller is in a separated form.

In FIG. 7, the controller 140 is usually mounted on a table 10. The controller 140 includes a monitor 137 and a switch panel 139. In this embodiment, the monitor 137 has a touch panel function, and the operation member for inputting an operation signal to the switch panel 139 is arrange | positioned. In addition, in the operation member arrange | positioned at the switch panel 139, when it is the same as the code | symbol shown in FIG. 6, it shall have the same function. In addition, in the same component as the apparatus shown in FIGS. 1-4, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

The switch 152 disposed on the switch panel 139 is a measurement mode switching switch (button) for switching the steering angle measurement mode and the subjective measurement mode. When switching to the steering angle measurement mode by the switch 152, the arithmetic and control unit 70 becomes measurement information (alignment information) for steering angle measurement on the monitor 137, and displays the front part portion shape 100 by the observation optical system 35b of the steering angle measurement device 30. In addition, in the steering angle measurement mode, the calculation control part 70 inputs the operation signal of the operation member arrange | positioned at the switch panel 139 as an operation signal for operating the steering angle measurement apparatus 30. The operation signal of the operation member used for subjective measurement becomes impossible to input.

After the steering angle measurement is finished, when the switch to the subjective measurement mode by the switch 152, the operation control unit 70 displays the measurement information for subjective measurement on the monitor 137. For example, the same thing as the display part 141 of FIG. 6 is displayed. In addition, in the subjective measurement mode, the calculation control unit 70 inputs an operation signal of the operation member disposed on the switch panel 139 as an operation signal for operating the subjective measurement device 1 and the target presentation device 20. The operation signal of the operation member used in the steering angle measurement becomes impossible to input.

As described above, the controller 140 functions as an operation unit of the rudder measuring device 30 in the steering angle measuring mode, and functions as a controller of the subjective measuring device 1 and the target presentation device 20 in the subjective measuring mode. At this time, it is possible to reduce the overlapping parts (components) as the whole optometry system.

 According to the present invention, it is possible to obtain an economically advantageous optometry system with fewer overlapping parts.

Claims (7)

A measurement optical system that transmits the measurement light to the eye fundus of the subject's eye and receives the measurement light reflected from the fundus, an observation optical system which captures the shape of the anterior eye of the subject's eye, a measurement unit in which the measurement optical system and the observation optical system are disposed; An angular eye refractive power measuring apparatus including a moving means for moving the measuring unit with respect to an eye of an examinee, and measuring the refractive power of an eye of an examinee in an objective manner; A unit separate from the angle refractive power measuring apparatus, which includes a left and right lens chamber units each having a sloping window, and a plurality of lens disks each having a plurality of optical elements arranged thereon, wherein the refractive power of the subject's eye is measured. Subjective eye refractive power measuring device, Measurement mode switching means for inputting a switching signal for switching the measurement mode of the system to either the steering angle measurement mode or the subjective measurement mode; Monitor with touch panel function, Operating means having a rotary knob for matching the position of the measuring unit with respect to the eye of the subject; When switching to the subjective measuring mode by the measuring mode switching means, an operation signal input switch of the subjective optometry unit is displayed on the panel of the monitor, and at the same time, the rotation knob of the operating means is switched on the optical element arranged in the dead window. An optometry system having control means functioning as an operation means for the use. The method of claim 1, And the control means controls driving of the moving means based on an operation signal of the operation means in the steering angle measurement mode. delete delete The method of claim 1, An optometry system further comprising a printer for outputting measurement data by the rudder measuring device and measurement data by the subjective measuring device. The method of claim 1, With a target presentation device for presenting the target in the eye of the examinee, And the control means displays the presentation target information of the target presentation device on the monitor in the subjective measurement mode, and controls the driving of the target presentation device based on an operation signal of the operation means. The method of claim 1, table, A tray on which the steering angle measuring device is mounted and which is movable between a measuring position on the table and a retracted position; and Further having a sensor for detecting at least one of the tray being disposed at the measurement position and the retracted position, The measurement mode switching means includes a sensor, the optometry system characterized in that for inputting the detection signal of the sensor as a switching signal.

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