KR100897736B1 - Eye examining apparatus having temperature variation compensating member - Google Patents

Abstract

Even when the operating temperature of the optometrist changes, an optometrist having a temperature compensating unit capable of minimizing a measurement error is disclosed. The optometry includes (i) an optometry light source that emits an optometry measurement light, an objective lens that focuses the measurement light emitted from the light source, and focuses the signal light reflected by the eye, and the signal light reflected by the eye An optometry comprising a prism lens for dividing the signal into a plurality of signal lights for each region, and a detector for detecting a plurality of signal lights divided by the prism lens; (ii) a temperature compensating unit including a temperature compensating light source for emitting the temperature compensating measurement light and a temperature compensating lens unit for receiving the measurement light emitted from the temperature compensating light source and generating signal light; And (iii) comparing the present measured value of the signal light generated from the temperature compensating lens unit with the reference measured value of the signal light generated from the temperature compensating lens measured at the reference temperature when the optometrist is manufactured, and calculating the amount of change. And a control unit for correcting the signal light generated from the eye to be examined using the calculated amount of change.

Optometry, temperature, compensation, light source for temperature compensation, amount of change

Description

Eye examination apparatus having a temperature compensation unit {Eye examining apparatus having temperature variation compensating member}

1 is a view for explaining an optometry with a temperature compensation unit according to an embodiment of the present invention.

FIG. 2 is a plan view of the lens assembly shown in FIG. 1. FIG.

3 is a view showing an optometry according to another embodiment of the present invention.

The present invention relates to an optometrist having a temperature compensator, and more particularly, to an optometrist having a temperature compensator which can minimize a measurement error even when the operating temperature of the optometrist changes.

An optometry is an optical optics measuring instrument that combines the fields of optics, electronics, precision instrumentation and computer program, and does not depend on the judgment of the subject to determine the characteristics of the eye, such as refractive power, astigmatism and astigmatism axis It is an instrument that accurately and quickly measures by means of electronic system. The optometrist includes an optical system composed of a plurality of lenses and a mirror, and irradiates measurement light to the eye to be examined through the optical path of the optical system, and from the optical signal reflected from the eye, Check the condition. In general, the optics of an optometry is considerably larger than components, and even minute distance changes between the lens and the lens have a great influence on the measurement signal, so that the measured value can be relied upon if the distance between the lenses is kept constant. However, among the accessories of the optometrists, many of them generate heat during operation, and since the temperature of the optometry varies depending on the region, the optometry accessories are thermally expanded or deformed by heat, and the distance between the lenses is changed. As such, when the distance between the lenses changes, an error occurs in the measured value. Therefore, it is necessary to configure a separate temperature compensating device so as to minimize this.

In order to compensate for such temperature, during the manufacture of the optometrist, correction data for various temperatures are input to the optometrist, a temperature sensor is mounted inside the optometrist, and the measured values measured at each temperature are corrected using the correction data. The method is used. However, in this case, not only does it take a lot of time and money to obtain the correction data according to the temperature change, process and input it, but also uses an approximation value in actual use or calculates the measured value using the coefficient value. There is a limit to the removal of the error. As described above, in the conventional temperature compensator for an optometrist, since an apparatus cost is high and there is a limit in error elimination, an optometry without a temperature compensator is generally used. In this case, the optometry temperature and use time are limited. This will occur.

Accordingly, it is an object of the present invention to provide an optometrist with a temperature compensator which can minimize measurement errors even when the operating temperature of the optometrist changes.

Another object of the present invention is to provide an optometrist having a temperature compensator which can efficiently correct an error in a measured value even when the distance between lenses changes due to a change in ambient temperature or heat generation of an internal element. will be.

In order to achieve the above object, the present invention, (i) the optometry light source for emitting the optometry measurement light, the objective of focusing the signal light reflected from the eye while focusing the measurement light emitted from the light source to the eye. An optometry unit comprising a lens, a prism lens for dividing the signal light reflected by the eye to be divided into a plurality of signal lights for each region, and a detector for detecting the plurality of signal lights split from the prism lens; (ii) a temperature compensating unit including a temperature compensating light source for emitting the temperature compensating measurement light and a temperature compensating lens unit for receiving the measurement light emitted from the temperature compensating light source and generating signal light; And (iii) comparing the present measured value of the signal light generated from the temperature compensating lens unit with the reference measured value of the signal light generated from the temperature compensating lens measured at the reference temperature when the optometrist is manufactured, and calculating the amount of change. Next, by using the calculated amount of change, provides an optometry comprising a control unit for correcting the signal light generated from the eye to be examined.

Hereinafter, with reference to the accompanying drawings, it will be described in more detail the optometry according to the present invention. 1 is a view for explaining the configuration of an optometry with a temperature compensation unit according to an embodiment of the present invention. As shown in FIG. 1, the optometrist according to the present invention includes an optometry unit and a temperature compensating unit, and the optometry unit includes an optometry light source 10, a hole-mirror assembly 12, an objective lens 14, and a prism lens ( 16) and a detector 18, wherein the temperature compensating part includes a temperature compensating lens part 20 and a temperature compensating light source 28.

The optometry used in the present invention functions substantially the same as a normal optometry device. That is, the optometry light source 10 of the optometry part emits the measurement light for the optometry, and as the light source 10, a light emitting diode (LED), a laser diode (LD), a super light emitting diode ( Super luminescent diodes (SLD) and the like can be used. The objective lens 14 causes the focus of the measurement light emitted from the light source 10 to be focused on the eye 5, specifically, the retina of the eye 5, and at the same time, the signal light reflected from the eye 5. The objective lens for focusing the eyepiece. The hole-mirror assembly 12 is used to separate the paths of the measurement light emitted from the optometry light source 10 and the signal light reflected from the eye 5, and is emitted from the optometry light source 10. A hole for passing the measurement light incident to the eye 5 may be formed in the center, and a mirror for changing the path of the signal light reflected from the eye 5 may have a structure formed around the hole. have. The prism lens 16 divides the signal light reflected by the eye 5 into a plurality of signal lights for each region, and a conventional microlens array may be used as the prism lens 16. The detector 18 is for detecting a plurality of signal lights divided by the prism lens 16. Specifically, the detector 18 detects the position, intensity, and the like of the divided signal lights. Preferably, the detector 18 may include an imaging lens 18a for focusing signal light and a charge-coupled device detector (b) which detects the signal light formed by the imaging lens 18a.

Referring to the operation of the optometry, the measurement light emitted from the optometry light source 10 converges through the hole and the objective lens 14 formed in the center of the hole-mirror assembly 12, focusing on the eye 5 Are formed, and at the same time, they are reflected by the eye 5 to form signal light. The signal light reflected by the eye 5 is converged again through the objective lens 14, after convergence, reflected by the mirror of the hole-mirror assembly 12, and divided into a plurality of signal lights by the prism lens 16. Next, it is detected by the detector 18. Since the positions of the divided signal light detected by the detector 18 differ from each other depending on the characteristics of the eye 5, the refractive power of the eye 5 is determined from the position of the divided signal light. Visual information, such as visual power (C) and astigmatic axis (a), may be calculated. That is, the measurement light is emitted as a single point in the light source 10, but is divided into a plurality of points through the optical system, and comparing the distance between the points with the data previously input to the control unit 30 of the optometry, The measured value is output as data such as a refractive power value of the eye 5, a lens value for glasses (that is, a diopter), and the like. In this case, each of the signal light data corresponding to the diopters of the various eye to be examined 5 is built in the control unit 30 of the eyepiece, and the data makes a model eye to replace the eye to be examined 5, It measures and inputs at the time of manufacture.

In such an optometrist, an error occurs due to a change in distance between optical elements, such as a lens and a mirror, due to a temperature change inside and outside of the optometrist, such as heat is emitted from the optometry light source 10. In order to achieve this, a temperature compensation unit is provided. As shown in FIG. 1, the temperature compensator includes a temperature compensating lens unit 20 and a temperature compensating light source 28.

The temperature compensation light source 28 emits the temperature compensation measurement light, and the temperature compensation lens unit 20 receives the measurement light emitted from the temperature compensation light source 28 to generate a signal light. In this case, the signal light has an optical path corresponding to the refractive power of the lens unit 20 for temperature compensation, that is, the diopter of the lens unit 20. The signal light generated by the temperature compensating lens unit 20 is changed in a half mirror 26 or the like as necessary, and moves along a path in which the signal light from the eye 5 is advanced. It is detected by the detector 18. In this case, the controller 30 measures the current measured value of the signal light generated by the temperature compensation lens unit 20 (for example, the size of the signal light) and the reference temperature (for example, 25 ° C.) when the optometry is manufactured. The reference measurement value of the signal light generated from the lens for temperature compensation 20 is compared, the amount of change is calculated, and then the calculated amount is used (for example, multiplied by the change ratio), and the eye to be examined 5 Correct the signal light generated from Here, the half mirror 26 is located in the path of the signal light emitted from the eye 5, and the distance between the half mirror 26 and the temperature compensation lens unit 20 is equal to the half mirror 26. It is preferable that it is equal to the distance between the eye to be examined 5. As such, when the distance between the temperature compensation lens unit 20 and the eye to be examined 5 is the same from the half mirror 26, since the traveling lengths of the two signal lights are the same, the signal light can be more precisely corrected.

In this case, as shown in FIG. 1, the temperature compensation lens unit 20 includes a lens assembly 23 mounted with a plurality of lenses 22 capable of generating signal light corresponding to each diopter, and the lens assembly 23. The lens assembly 23 may be rotated to include the step motor 24 that sequentially positions the plurality of lenses 22 in the path of the measurement light for temperature compensation. FIG. 2 is a plan view of the lens assembly 23 illustrated in FIG. 1. As shown in FIG. 2, the lens assembly 23 has a disc shape, and various diopter lenses are formed at the edges of the lens assembly 23. 22 may be disposed circumferentially, and may be sequentially positioned in the path of the temperature compensation measurement light as the lens assembly 23 rotates. As the position information of the lens assembly 23, the initial position of the lens assembly 23 is set using a photo interrupt (not shown) or the like, and the amount of rotation of the lens assembly 23 is adjusted to the step motor 24. Can be controlled by step. When the lenses 22 of various diopters are used in this manner, the signal light generated from the eye 5 can be corrected by using the lens 22 of the diopter closest to the diopter of the eye 5 to be measured.

When the measured value measured at the reference temperature (for example, 25 ° C.) is not embedded in the control unit 30 of the optometrist, the measured value is obtained at the reference temperature by using the lens assembly 23 for temperature compensation. This may be stored in the controller 30 and used for temperature compensation. In this case, the temperature compensation lens assembly 23 functions to generate data for optometry set up. The data for setting up the optometrist may be useful when the use environment of the optometrist is remarkably changed or when data stored in the optometry is lost.

3 is a view showing an optometry according to another embodiment of the present invention. In the embodiment shown in FIG. 3, as the temperature compensating lens unit 20 shown in FIG. 1, a plurality of diopter-specific lenses are not used. For example, only one temperature compensation lens 22 capable of implementing a reference value (for example, zero diopter), that is, having a reference diopter value is used. In the present embodiment, the current measurement value of one signal light generated from the temperature compensation lens 22 and the temperature compensation lens 20 measured at a reference temperature (for example, 25 ° C.) at the time of manufacturing the optometry The reference measurement values of the signal lights are compared, the amount of change is calculated, and then the signal light generated from the eye 5 is corrected using the calculated amount of change. In this case, when the diopter value of the eye to be examined differs from the diopter value of the temperature compensation lens unit 20, the signal light generated from the eye 5 may be corrected by multiplying or adding a weight corresponding to the difference in the diopter value.

As described above, the optometrist according to the present invention has a temperature compensator which can minimize measurement errors even when the operating temperature of the optometrist changes, and therefore, due to a change in ambient temperature or heat generation of an internal element, Even when the distance between the lens of the optometrist changes, the error of the measured value can be corrected efficiently.

Claims (5)

An optometry light source that emits optometry measurement light, an objective lens that focuses the measurement light emitted from the light source, and focuses the signal light reflected from the eye, and a plurality of signal lights for each area of the signal light reflected by the eye An optometry comprising a prism lens to be divided into a detector, and a detector for detecting a plurality of signal lights divided by the prism lens; A temperature compensating unit including a temperature compensating light source for emitting the temperature compensating measurement light and a temperature compensating lens unit for receiving the measurement light emitted from the temperature compensating light source and generating signal light; And Comparing the current measurement value of the signal light generated from the temperature compensation lens unit with the reference measurement value of the signal light generated from the temperature compensation lens measured at the reference temperature when manufacturing the optometry, the amount of change is calculated, and then calculated A control unit for correcting the signal light generated from the eye to be examined using a change amount, The lens unit for temperature compensation includes a lens assembly mounted with a plurality of lenses capable of generating signal light corresponding to respective refractive powers, respectively; And a step motor which rotates the lens assembly to sequentially position the plurality of lenses in the path of the measurement light for temperature compensation. The optometry of claim 1, wherein the signal light generated from the temperature compensating lens unit has an optical path corresponding to the refractive power of the temperature compensating lens unit. The apparatus of claim 1, further comprising a half mirror positioned in a path of the signal light emitted from the eye to be examined and changing a path of the signal light generated by the temperature compensation lens unit to a path of the signal light emitted from the eye to be examined. Optometry. delete delete

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