KR100618280B1 - Lensmeter - Google Patents

Abstract

For contact lens inspection, by installing a lens cap with a convex spherical surface and a movable jig in which the lens cap is movably mounted, the position of the contact lens is fixed stably even during the movement or during the measurement of the contact lens. In addition, a lens meter is provided which can stably and easily move the contact lens. In addition, the lens meter receives the signal signal detected by the image sensing element of the optical system, calculates a variable representing the characteristics of the lens under measurement corresponding to the signal signal, and analyzes the state of the signal signal according to the measurement point of the lens under measurement. An operating circuit including an image distributor for transmitting an image of a signal signal received from an image sensing device to a display device in real time; And including a display device for displaying the results of the operation circuit, it is possible to confirm the reliability and accuracy of the results output by the lens inspection.

Lens meter, contact lens, signal distortion, signal image

Description

Lens meter

1 shows a perspective view of a general lens meter.

2 shows a perspective view of a lens cap for a contact lens, used in a conventional lens meter.

3 shows a perspective view of a lens meter that can be used in the present invention.

4 is a view illustrating the contact lens mounting portion of FIG. 3 in detail, and shows a contact lens lens cap and a moving jig in which the lens cap is mounted.

5 shows a circuit block diagram for operating a lens meter according to the present invention.

6 shows a screen configuration of the display device of the lens meter according to the present invention.

The present invention relates to a lens meter, and more particularly to a lens meter suitable for the inspection of soft contact lenses.

The lens meter detects the beam (or signal) of the light emitter reflected from the lens under measurement by using the light emitter and the position sensing element, and grasps the degree of deviation of the signal from the normal path, and the deviation value. Is computed, and includes a lens characteristic variable corresponding to the deviation value (including a refractive power, a blind power, a blind axis and a prism of the spectacle lens or the contact lens). Equipment to calculate An example of such a lens meter is shown in FIG. Referring to FIG. 1, the lens meter is disposed on the lens cap 11 on which the normal lens to be measured, the spectacle lens or the contact lens is placed, the lens pedestal 13 supporting the lens cap 11, and the lens cap 11. And a lens holder 14 for fixing a lens placed on the lens cap 11, and a display device 15 for displaying variables representing characteristics of the lens under measurement. In the housing 16 of the lens meter, an optical system including a light emitter for irradiating a beam for measuring lens characteristics, an arithmetic unit for calculating optical information of a lens under measurement, the optical system, arithmetic unit, and the above-described lens holder, A control unit is formed to control the operation of all elements of the lens meter including the lens support.

The conventional lens meter shown in Fig. 1 is suitable for inspecting a general lens or spectacle lens, but the following problem occurs when inspecting a soft contact lens.

First, in order to match the optical axis of the optical system with the center of the soft contact lens to be measured, the soft contact lens located on the lens cap 11 must be moved. In the case of a contact lens, such movement is very difficult. The reason is that not only the small contact lens with curvature needs to be moved by hand, but also the soft contact lens is made of an elastic material, so that the contact lens does not move and the curvature is frequently aggregated during the movement. In addition, since the contact lens is small in size, it is almost impossible to fix the contact lens using the lens holder 14 designed to fit the size of the general lens or the spectacle lens during the movement of the contact lens.

Second, in the case of a contact lens, unlike a general lens or spectacle lens, the reliability of the measured value is lacking. The reason is that the contact lens is contained in the liquid during storage, and if you want to measure the characteristics of the contact lens, remove the contact lens from the liquid to remove moisture. However, even if the moisture on the surface of the contact lens is removed, the material contains water, and the moisture contained in the contact lens evaporates with time, so that the contact lens hardens little by little over time. This is slightly different. That is, since the curvature value changes depending on the measurement time point, unlike the general lens, the reliability of the measured value is lowered.

On the other hand, in the conventional automatic lens meter, the result indicating the characteristics of the lens to be measured is displayed on the display device 15. Therefore, when the contact lens is inspected using the conventional automatic lens meter, the display device 15 is described above. Only the result at any one measurement time point is displayed, which does not consider the change in the characteristic value of the contact lens based on the reason as described above. Thus, the user may not have confidence in the measured value displayed on the display device when measuring the contact lens.

Nevertheless, in the conventional lens meter, almost no auxiliary device for inspecting the contact lens is provided, but in view of the small size of the contact lens, as shown in FIG. 2, as shown in FIG. ) And tongs (not shown: tweezer) for holding contact lenses are sometimes provided. In the lens cap 20 of FIG. 2, since the upper inlet 21 has a cylindrical shape, a contact lens having a convex spherical surface may not be stably seated. That is, when the contact lens is placed on the lens cap 20 and the contact lens is moved or when the lens meter is finely moved by external influence even during the measurement, the position of the contact lens may change slightly. In addition, since the forceps are used when the contact lens is moved, difficulty of movement still exists. In addition, even when the contact lens is inspected using the lens cap 20 described above, the problem of the change in the characteristics of the contact lens according to the measurement time point and the deterioration of the reliability and accuracy of the measured value remain.

It is therefore an object of the present invention to provide a lens meter suitable for the measurement of contact lenses.

Another object of the present invention is to provide a lens meter including a lens cap capable of stably fixing its position even when the contact lens is moved or during measurement.

Still another object of the present invention is to provide a lens meter capable of improving the reliability and accuracy of a measured value by monitoring a characteristic change of a contact lens according to a measurement time point.

In order to achieve the above object, the present invention, an optical system including an image sensing element for detecting a signal signal projected on the lens to be measured; A lens mounting unit which fixes the lens to be measured and makes the center of the lens to be aligned with the optical axis of the optical system; An operation circuit including a microprocessor for controlling the optical system and receiving a signal signal sensed by the image sensing device of the optical system, and calculating a variable representing a characteristic of a lens under measurement corresponding to the signal signal; And it provides a lens meter including a display device for displaying the output of the operation circuit.

Here, the operation circuit further includes an image divider for delivering the image of the signal signal received from the image sensing element to the display device in real time, the microprocessor is to inform that the signal signal image provided from the image divider is delivered to the display device. In response to the signal, the diopter scale image is transmitted to the display device. The microprocessor further includes a signal state analysis module that receives the signal signal sensed by the image sensing device, analyzes the state of the signal signal according to the measurement time point of the lens under measurement, and transmits the output to the display device. . Accordingly, a screen of the display device may include a first screen on which an output of the signal state analysis module is displayed, a second screen on which a parameter representing a characteristic of a lens under measurement output from the microprocessor is displayed, and the image distributor. And a third screen displaying a diopter scale image provided from the microprocessor on a real time signal signal image. The signal state analysis module calculates an average magnitude S of the N signal signals detected by the image sensing device, and compares the magnitude ratio of each of the N signal signals with respect to the average size of the signals (Ri = Si / S. Here, Si represents the magnitude of the i-th signal.), And it is determined whether the magnitude ratio Ri of all the signals is included in the confidence interval determined according to the lens under measurement.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

3 is a perspective view of a lens for a contact lens that can be used in the present invention, Figure 4 shows a lens jig for a contact lens and the moving jig is mounted to the lens cap of Figure 3, Figure 5 is a lens meter according to the present invention A circuit block diagram for operating is shown. 6 shows a screen configuration diagram of a display device of a lens meter according to the present invention. In the lens meter of FIG. 3, the same reference numerals are given to the same components as the lens meter of FIG. 1.

As shown in FIG. 3, the lens meter includes a lens cap 31 designed to stably place a contact lens, a moving jig 32 in which the lens cap 31 is movable, and the moving jig 32. It includes a lens support 13 for supporting the lens, and a lens holder 14 for fixing the spectacle lens or a normal lens disposed on the lens cap 31, the lens cap 31. Here, the lens holder 14 is not used for fixing the contact lens, but is used for fixing the general lens or the spectacle lens.

In addition, inside the housing 16 of the lens meter, (i) a light emitter (40 in FIG. 5) irradiating a beam and a signal signal reflected from the lens are used to inspect the lens placed on the lens cap 31. Optical system including an image sensing element (42 in FIG. 5) for sensing, and (ii) variables for determining the characteristics of the lens under measurement based on the signal signal image acquired by the image sensing element by the optical system operation (hereinafter, For example, a microprocessor (51 of FIG. 5) that calculates and outputs a refractive power, astigmatism, astigmatism axis, and prism of a lens and analyzes a signal state of a signal signal image of a lens to be inspected. And an operation circuit (50 of FIG. 5) for transmitting the signal signal image detected by the optical system to the display device 15. As the display device 15, an LCD or a CRT monitor may be used. The display device 15 includes a first screen showing a result of state analysis of a signal signal output from the microprocessor 51, a second screen showing a lens characteristic variable of a contact lens to be measured, and a second screen showing an image of a signal signal in real time. 3 A screen and a fourth screen indicating the lens position are displayed together. Here, the first screen is called a 'status analysis indicator', the second screen is called a 'lens characteristic variable output device', the third screen is called a 'signal video indicator', and the fourth screen is called a 'lens position indicator'. . In addition, since the 'lens characteristic variable output unit' and the 'lens position indicator' also appear on the display device of the conventional lens meter, the description thereof will be omitted.

The lens cap 31 and the moving jig 32 which is a means of moving the lens cap 31, which can be used in the lens meter of the present invention, are shown in detail in FIG. Referring to FIG. 4, the lens cap 31 that can be used in the lens meter of the present invention extends in a direction perpendicular to the upper portion 31a of the convex spherical surface, the middle portion 31b of a cylindrical shape, and the middle portion 31b. It consists of the lower part 31c which has the wing which was made. The upper portion 31a of the lens cap 31 has a radius of curvature substantially the same as the average radius of curvature of the contact lens, and has a curved surface suitable for about 7.8 mm, for example, the radius of curvature of a commercially available contact lens. Here, the radius of curvature of the convex sphere is substantially the same as the radius of curvature of the contact lens, but does not necessarily have the same radius of curvature, and if the contact lens can be easily seated, it is slightly smaller than the radius of curvature of the commercially available contact lens. It can be big or small. Specifically, since the curvature radius of currently available contact lenses is about 5 to 10 mm, the radius of curvature of the upper portion 31a of the lens cap 31 may also be designed to be within this range.

On the other hand, the lens cap 31 is not placed directly on the lens support 13, but on the upper surface of the moving jig 32, which is a moving means for finely moving the lens cap 31 on which the contact lens is seated in the vertical and horizontal directions. The movable jig 32 is fixed to the lens support 13. In FIG. 4, the movable jig 32 is connected to the upper plate 32a, the lower plate 32b positioned below the upper plate 32a, the base 32c positioned below the lower plate 32b, and the upper plate 32a. It is comprised by the 1st moving shaft 32d for moving 32a in an X-axis direction, and the 2nd moving shaft 32e for moving the lower board 32b in a Y-axis direction by being connected to the lower board 32b. In addition, the lower plate 32b is provided with a first guide 32f for guiding its movement when the upper plate 32a moves in the X-axis direction. One surface of the first guide 32f is in sliding contact with one surface of the upper plate 32a, and a rail (not shown) extending in the X-axis direction is formed on one surface of the first guide 32f that is in contact with the upper plate 32a. It forms, and the upper plate 32a moves through this rail. The base 32c is provided with a second guide 32g for guiding the movement when the lower plate 32b moves in the Y-axis direction. One surface of the second guide 32g is in sliding contact with one surface of the lower plate 32b, and similarly to the first guide 32f, one surface of the second guide 32g is in contact with the lower plate 32b of the second guide 32g in the Y-axis direction. An extending rail (not shown) is formed.

In the movable jig 32 of FIG. 4, concentric holes 32h are formed in the middle of the upper plate 32a, the lower plate 32b, and the base 32c, and the lens cap 31 is formed in the hole 32h. The lower portion 31c) is inserted, and the lens cap 31 is stably mounted to the moving jig 32. On the other hand, the upper plate 32a is provided with a groove into which the lower portion 31c of the lens cap 31 is fitted without providing the concentric hole 32h in the center portion of the upper plate 32a, the lower plate 32b and the base 32c. The lens cap 31 can be attached to the movable jig 32 even if formed only in the After attaching the lens cap 31 to the moving jig 32, in order to move the contact lens in the left-right (X-axis direction) and the front-rear (Y-axis direction) directions, the first moving shaft 32d and the second moving The shaft 32e is rotated. For the movement in the X-axis direction, when the first moving shaft 32d is rotated clockwise, the upper plate 32a moves toward the second guide 32g along the rail of the first guide 32f. Therefore, the contact lens seated on the lens cap upper portion 31a mounted on the upper plate 32a moves in the X-axis direction. Similarly, in order to move the contact lens seated on the upper portion 31a of the lens cap 31 in the Y-axis direction, the second moving shaft 32e is rotated. Then, the lower plate 32b moves along the second guide 32g in the direction perpendicular to the rotation direction.

In addition, the contact lens may be fixedly mounted on the upper portion 31a of the lens cap 31 or may be rotatably mounted. For fixed seating, the upper plate 32a and the lens cap 31 may be joined by a method such as welding, or the upper plate 32a and the lens cap 31 may be integrally formed. The rotatable seating may be fixed by fitting the lens cap 31 between the upper plate 32a and the lower plate 32b. In addition, when the lens cap 31 is rotatably seated, the user may grasp and rotate the middle portion 31b of the lens cap 31 by hand to match the astigmatism axis of the contact lens. The state where the center of the contact lens is aligned with the optical axis of the optical system using the lens cap 31 and the moving jig 32 can be confirmed from the 'lens position indicator' on the upper left of FIG. 6. Next, the center of the contact lens and the optical axis of the optical system (not shown) are aligned using the lens cap 31 and the moving jig 32, and then the optical system is driven. Since the optical system can use a known optical system used in a conventional lens meter, detailed description thereof will be omitted here. After driving the optical system, the signal image passing through the contact lens seated on the lens cap 31 is imaged on the image sensing element (42 in FIG. 5) of the optical system. The image formed is input to the lens meter operating circuit 50 according to the present invention.

Referring to FIG. 5, the operation circuit 50 of the lens meter stores a microprocessor 51, a flash memory 52 in which an operation program of the lens meter is stored, and an equipment value necessary for constant driving of the lens meter. EEPROM 53, video distributor 54, and video RAM (RAM) 55. The microprocessor 51, based on the signal signal image formed in the image sensing element 42 of the optical system, the calculation module 51a and the signal of the signal signal image for calculating the characteristic variables of the various lenses including the contact lens Analyzing the state, and determining whether the signal signal of the contact lens under measurement is distorted. Looking at the operation of the operation circuit 50, when the power of the lens meter is turned on, the microprocessor 51 controls the flash memory 52 to drive the operation program. At this time, the center of the contact lens and the optical axis of the optical system (not shown) are aligned using the lens cap 31 and the moving jig 32. Next, when the user presses the contact lens inspection mode button, the microprocessor 51 turns on the light emitter 40 to drive the optical system. The signal signal image for the contact lens is formed in the image sensing element 42 of the optical system, and the output of the image sensing element 42 is input to the image divider 54 of the operation circuit 50.

The image distributor 54 is preferably made of a field programmable gate array (FPGA), receives a signal signal image of the image sensing device 42, and transmits the signal image to the display device 15 in real time. Under the control of the microprocessor 51, the signal signal image is captured and transmitted to the video RAM 55 as a storage means. At this time, in the microprocessor 51, a signal signal image is provided from the image distributor 54 so that the user can read the refractive power of the contact lens based on the size of the signal signal on the screen of the display device 15, the display device The diopter scale image is transmitted to the display device 15 in response to the signal indicating that the signal is transmitted to the display device 15. The diopter scale image is stored in the above-described flash memory 52. The microprocessor 51 reads the diopter scale image and stores the RAM in the RAM 55 when the lens meter is driven. 15) to pass. Therefore, on the screen of the display device 15, a signal video display (upper right in FIG. 6) in which the diopter scale image and the signal image are displayed together is displayed. On the other hand, the microprocessor 51, so that the cross marker is displayed in the center coordinates of the signal displayed on the signal video display, so that the user can know the center of the signal signal.

The signal image stored in the video RAM 55 is transferred to the operation module 51a and the signal state analysis module 51b of the microprocessor 51. The calculation module 51a of the microprocessor 51 calculates the characteristic variables of the contact lens under measurement from the output of the video RAM 55 and transmits the result to the display device 15. Since the calculation module 51a is also used in a conventional lens meter, a detailed description thereof will be omitted. Then, the lens characteristic variable output screen shown in the lower right of Figure 6 is displayed on the display device (15).

As described above, the output of the video RAM 55 is also transmitted to the signal state analysis module 51b of the microprocessor 51. As described in the related art, the contact lens, unlike a general lens or an eyeglass lens, may cause distortion of a signal signal depending on a measurement time point. Therefore, it is necessary to inform the inspector of the distortion information of the signal signal, and this function is achieved by the signal state analysis module 51b. In the case where there are N signal signals formed by the image sensing device 42, when the general lens or the spectacle lens is to be measured, the size of the N signal signals is almost the same. However, in the case of the contact lens, since the distortion of the signal signal may occur, the size of the N signal signals may be different from each other. Accordingly, the signal state analysis module 51b calculates their average magnitude (S = ∑Si / N, where Si represents the magnitude of the i th signal signal) from the N signal signals, and calculates the average magnitude (S). The size ratio (Ri = Si / S) of each signal with respect to) is calculated. Then, it is judged whether or not the size ratio Ri of all signals is included in the confidence interval determined according to the lens under measurement. The signal is treated as substantially free of signal distortion, and a confidence interval (signal size ratio Ri above a predetermined value) at which the reliability of the measurement can be recognized depends on the type and nature of the lens under measurement. For example, in the signal status indicator screen on the lower left of FIG. 6, when all the signals (four signals) have a signal size ratio equal to or greater than the dotted line indicated by reference numeral 60, the measurement using the signal is accurate and reliable. I judge it. When the calculated signal size ratio Ri is 1 (corresponding to a portion indicated by 100 of the vertical axis of FIG. 6), all signal signals have the same magnitude, and there is no distortion of the signal signal generated from the contact lens. Means. On the other hand, the output of the signal state analysis module 51b is displayed on the screen of the display device 15. In this embodiment, the Ri of each signal is displayed in a bar graph form and displayed on the display device 15 (FIG. 6). Bottom left). On the other hand, the image of the signal video display of the upper right of Figure 6 appears differently with time. Then, Ri of each signal of the signal status indicator on the bottom left is changed, and the value of the lens characteristic variable outputter displayed on the bottom right is also changed.

For example, during measurement, the position of the lens may change, so the user often looks at the lens position indicator, checks whether the center of the lens is in the correct position, and if the center is not in the correct position, The moving jig is moved to coincide with the center of the contact lens and the optical axis of the optical system. At this time, the position of the lens is determined through the lens position indicator (upper left of FIG. 6). Then, while looking at the graph of the signal status indicator (lower left in FIG. 6) that changes over time, the reliability of the measurement at each time point is determined, and when the size ratio of each signal is in the confidence interval, the lower right is displayed. Read the result of the lens characteristic variable output as a measured value, or read the refractive power from the signal size of the signal moving image display displayed on the upper right. That is, the user may select a value having the best reliability among the measured values several times. Meanwhile, a technique of dividing the screen of one display device 15 into four sections and displaying different images (lens position indicator, lens characteristic variable output device, signal moving picture indicator, and signal state indicator) in each section is well known. Since the technology can be used, description thereof is omitted here.

The foregoing description has been limited to the case where the contact lens is inspected using the lens meter according to the present invention, but the present invention is not limited thereto. For example, the spectacle lens or the general lens is seated on the lens cap 31 according to the present invention, the lens is fixed with the lens holder 14, and then the moving jig 32 is used to move the center of the lens and the optical axis of the optical system. Can be matched. Thereafter, the refractive power, astigmatism, astigmatism axis and prism of the general lens or the spectacle lens can be measured. In addition, by using the microprocessor 51 including the image divider 54 and the signal analysis module 51b according to the present invention, it is possible to inspect a spectacle lens or a general lens that is scratched or degraded in quality. That is, the user can determine the replacement time of the lens by checking the image and signal state of the signal signal reflected from the scratched or deteriorated spectacle lens from the signal moving image indicator and the signal analyzer of the display device 15. . In addition, the state of the signal signal and the signal signal image of the high refractive lens or the progressive focus lens can be confirmed.

When the lens is inspected using the lens meter according to the present invention, particularly when the contact lens is inspected, its position is stably fixed even during the movement or during the measurement of the contact lens, and the center of the contact lens is It can be easily matched to the optical axis. Therefore, by monitoring the characteristic change of the lens in real time, it is possible to improve the reliability and accuracy of the measured value.

Claims (4)

An optical system including an image sensing element configured to sense a signal signal projected on the lens to be measured; A lens mounting unit which fixes the lens to be measured and makes the center of the lens to be aligned with the optical axis of the optical system; An operation circuit including a microprocessor for controlling the optical system and receiving a signal signal sensed by the image sensing device of the optical system, and calculating a characteristic variable of a lens under measurement corresponding to the signal signal; And A display device for displaying the output of the operation circuit, The microprocessor further includes a signal state analysis module that receives the signal signal sensed by the image sensing element, analyzes the state of the signal signal according to a measurement time point of the lens under measurement, and transmits the output to the display device. The screen of the display device may include a first screen on which an output of the signal state analysis module is displayed and a second screen on which characteristic variables of a lens under measurement output from the microprocessor are displayed. Lens meter. The signal state analysis module of claim 1, wherein the signal state analysis module calculates an average size S of the N signal signals detected by the image sensing device, and a size ratio of each of the N signal signals to the average size of the signal. (Ri = Si / S. Here, Si represents the magnitude of the i-th signal.) To determine whether the magnitude ratio Ri of all signals is included in the confidence interval determined according to the lens under measurement. Lens meter, characterized in that. The image processing apparatus of claim 1, wherein the operation circuit further comprises an image divider configured to deliver an image of a signal signal received from the image sensing element to the display device in real time, and the microprocessor includes a signal signal image provided from the image divider. In response to the signal indicating that the display device is transmitted to the display device, a diopter scale image is received from the storage means of the operation circuit and transmitted to the display device. Accordingly, the screen of the display device is displayed on the first screen and the second screen. And a third screen on which a diopter scale image provided from the microprocessor is displayed on a screen and a real-time signal signal image provided from the image distributor. The lens mounting apparatus of claim 1, wherein the lens mounting unit comprises: a lens cap having an upper end treated with a convex curved surface so that the lens under measurement is stably placed; Lens cap moving means to which the lens cap is movably mounted; And a lens support for supporting the lens cap moving means.

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