KR20240062105A - Light reflection confirmation device - Google Patents

Abstract

The present invention is a light response confirmation device that tests pupil response that can be easily carried by medical workers or the general public to detect a patient's pupil response, and a pupil response test device that detects changes in pupil size by photographing the eye. It is formed at one end of the case and the case that radiates light from the case, is formed with a measuring unit that measures the distance between the eye and the case, is connected to the imaging unit that takes pictures of the eye, and detects changes in the pupil. A sensing unit is provided.

Description

Light reflection confirmation device}

The present invention relates to a light reflection confirmation device for testing pupil reaction that can be easily carried by medical workers or the general public to detect the pupil reaction of a patient.

)으로부터, 하기 수학식 1을 통하여 동공 직경(b)을 산출하는 것이며, [수학식 1] b=a*tan

상기 자동 초점 재설정 시간 측정 모듈은 빛 조사 전후의 동공 사이즈 변화 또는 변화 없음에 대응하여 자동 초점이 재설정되는데 소요되는 시간을 측정하는 기술을 제시하고 있다.Patent Document 001 is a penlight for measuring pupil reflection, wherein the penlight includes a camera unit including a camera mounted on one side of the penlight, and the camera includes an autofocus module that automatically adjusts focus with respect to the pupil. The autofocus module includes one or more of a pupil size calculation module and an autofocus reset time measurement module, and the pupil size calculation module includes the autofocus distance (a) between the camera and the pupil and the camera's view angle (

), the pupil diameter (b) is calculated through Equation 1 below, [Equation 1] b=a*tan

The autofocus reset time measurement module proposes a technology for measuring the time required for autofocus to be reset in response to a change or no change in pupil size before and after light irradiation.

Patent Document 002 states that a pupil reaction test request signal is generated in response to user manipulation following the execution of a pupil reaction test application for a smartphone; The control unit generates a camera control signal and a flash control signal according to the inspection request signal; The camera operates according to preset shooting conditions in response to camera control signals; The flash is operated according to preset light control conditions in response to a driving signal from a timer that operates according to the flash control signal; The control unit analyzes pupil changes in the images captured from the camera; We present a technology that processes the analysis results into display signals in the control unit.

Patent Document 003 includes a forehead rest that supports the patient's forehead, a chin rest whose height is adjusted up and down in combination with the forehead rest, and an examination of the eyeballs of a patient whose chin is supported on the chin rest by adjusting the height of the chin rest. It is an optometry device equipped with a control unit that measures the patient's corneal refractive index and radius of curvature through an optical system after moving it into position. A sensor is located at the top of the chin rest that detects when the patient's chin is positioned and transmits a patient detection signal to the control unit. is installed, and when a patient detection signal is transmitted from a sensor installed on the upper part of the chin rest, the control unit adjusts the height of the chin rest to move the patient's eyeballs to the examination position, then tracks the position of the pupil and detects the patient through the optical system. A technology to measure the corneal refractive index and radius of curvature is presented.

Patented invention 004 includes a camera operating unit that operates the camera of a smartphone so that an image of the eye can be captured with the smartphone; a video storage unit that stores video captured by the camera of the smartphone by the camera operating unit; an image selection unit that selects an eye image before flash operation and an eye image after flash operation from the video stored by the video storage unit; a pupil confirmation unit that checks each pupil in the eye image before and after flash operation selected by the image selection unit; a pupil change determination unit that determines a change in the pupil by comparing the size of the pupil before the flash and the size of the pupil after the flash confirmed by the pupil confirmation unit; A technology including a pupil information display unit that displays information about the pupil captured by a camera is presented.

KR 10-2193429 B1 (December 15, 2020) KR 10-2014-0111157 A (September 18, 2014) KR 10-2019-0058984 A (May 30, 2019) KR 10-1701059 B1 (January 23, 2017)

The present invention relates to a light reflection confirmation device for testing pupil reaction that can be easily carried by medical workers or the general public to detect the pupil reaction of a patient.

In order to solve the problems of the prior inventions, the present invention relates to a light reflection confirmation device, which is a pupil response test device. In the pupil response test device that detects changes in the size of the pupil 11 by photographing the eye 10, A case of irradiating light (100); A measuring unit 200 formed at one end of the case 100 and measuring the distance between the eye 10 and the case 100; An imaging unit 300 formed on the measuring unit 200 and photographing the eye 10; It is connected to the imaging unit 300 and consists of a detection unit 400 that detects changes in the pupil 11.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; A case cover 110 formed on one end of the case 100 and detachably coupled to the invention, which includes a sensing unit 400; a light-emitting device 120 formed on the case cover 110 and emitting light toward the front; A display device 130 is exposed to the outside of the case 100 and displays changes in the pupil 11.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; A light emitting diode 121 formed on the light emitting device 120 and mounted on the case cover 110 to emit light; An illuminance control device 122 is connected to the light emitting diode 121 and controls the illuminance of light.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; The invention consists of a sensing unit 400; an irradiation device 210 formed on the measuring unit 200 and irradiating infrared rays; A light receiving device 220 is formed on the irradiation device 210 and receives infrared rays reflected from the eye 10.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; The invention consists of a detection unit 400; a camera 310 formed in the photographing unit 300 and photographing the eye 10; An adjusting device 320 is formed on the camera 310 and controls focus.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; An extraction server ( 500); A calculation server 600 is formed in the extraction server 500 and calculates the size of the pupil 11.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; The invention consists of a detection unit 400; a determination unit 510 formed in the extraction server 500 and determining the color of the image; A correction unit 520 is formed in the determination unit 510 and corrects a color different from that of the pupil 11, iris 12, and sclera 13.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; The invention consists of a sensing unit 400; a dividing unit 610 formed in the calculation server 600 and dividing the pupil 11 and the iris 12 into a plurality of pixels 20; a conversion unit 620 formed in the division unit 610 and converting the plurality of pixels 20 into gray scale; A calculation unit 630 is formed in the conversion unit 620 and calculates the distance change of the pixel 20 converted to gray scale.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; The invention consists of a detection unit 400; a designation unit 621 formed in the conversion unit 620 and designating a pixel value 20 to which gray scale is applied to a plurality of pixels 20; A selection unit 622 is formed in the designation unit 621 and selects the pixel 20 formed in the pupil 11.

The present invention relates to a pupil reaction test device, and includes the case 100 presented above; Measuring unit 200; Photographing unit 300; The invention consists of a detection unit 400; a pixel measurement unit 631 formed in the calculation unit 630 and measuring the quantity of pixels 20 divided by the division unit 610; A size calculation unit 632 is formed in the pixel measurement unit 631 and calculates the change in size of the pupil 11.

The present invention allows medical workers or the general public to simply test a patient's pupil reaction by carrying a case.

The present invention allows the gap between the case and the eye to be easily adjusted using the measuring unit.

The present invention can clearly distinguish the pupil, iris, and sclera by using gray scale.

The present invention can simply calculate the size of the pupil by setting the pixel in the eye and then setting the gray scale value.

1 is an exemplary diagram showing a pupil reaction test using the pupil reaction test device of the present invention.
Figure 2 is a cross-sectional view of the pupil reaction test device of the present invention.
Figure 3 is a perspective view of the pupil reaction test device shown in Figure 2.
Figure 4 is a block diagram of the detection unit of the present invention.
Figure 5 is an exemplary diagram of the extraction server of the present invention.
Figure 6 is an exemplary diagram of the calculation server of the present invention.
Figure 7 is an exemplary diagram of a calculation unit of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. However, it goes without saying that the present invention is not limited to these embodiments and can be modified into various forms.

In the drawings, parts not related to the description are omitted in order to clearly and briefly explain the present invention, and identical or extremely similar parts are denoted by the same drawing reference numerals throughout the specification. In addition, in the drawings, the thickness, area, etc. are enlarged or reduced in order to make the explanation a little clearer, and the thickness, area, etc. of the present invention are not limited to what is shown in the drawings.

And when a part is said to “include” another part throughout the specification, it does not exclude other parts and may further include other parts, unless specifically stated to the contrary.

Hereinafter, the pupil reaction test device will be described in detail with reference to the attached drawings.

Figure 1 is an exemplary diagram showing a pupil reaction test using the pupil response test device of the present invention, Figure 2 is a cross-sectional view of the pupil response test device of the present invention, and Figure 3 is a perspective view of the pupil response test device shown in Figure 2. am.

As shown in Figures 1 to 3, the pupil response test device according to an embodiment of the present invention shines light on the pupil 11 of the patient to check the response of the pupil 11, thereby detecting the sympathetic nerve, parasympathetic nerve, brain and This is to check for abnormalities in the brainstem. In general, the characteristics of unconditional reflexes in vertebrates include somatic reflexes, in which the somatic nervous system responds to external stimuli and movement, and visceral reflexes, which are operated by the autonomic nervous system. This unconditional reflex detects changes in the pupil 11 to determine the patient's condition. The size of the pupil 11 is about 2 mm when exposed to light, and the diameter is about 6 mm in the dark. The shape of the pupil (11) is circular and the light reflex should respond immediately. Abnormal reactions of the pupil (11) include the pupil (11) not responding to light, nerve compression while the pupil (11) is dilated, midbrain damage where the pupil (11) is located in the center and showing no response, and the size of the pupil (11). It is small, the same size, and has several symptoms, including damage to the diencephalon that responds to light. Therefore, it is possible to determine which part of the brain is abnormal based on the shape and reaction of the pupil 11.

In particular, the response of the pupil 11 is an important clue in evaluating the prognosis of patients in emergency situations or intensive care units, and many attempts are being made to measure changes and reactivity of the pupil 11.

The present invention determines the reaction of the pupil 11 to measure the patient's condition, and is formed in a size that can be easily carried by doctors, nurses, or various people to determine the patient's condition, and the size of the pupil 11 By automatically measuring changes, the patient's condition can be accurately identified.

Such a pupil response test device is a pupil response test device that detects changes in the size of the pupil 11 by photographing the patient's eye 10, and includes a case 100 that radiates light from one end and one end of the case 100. It is formed in the measuring unit 200 and a measuring unit 200 that measures the distance between the eye 10 and the case 100, and a photographing unit 300 and a photographing unit 300 that photograph the eye 10. ), and a detection unit 400 that detects changes in the pupil 11 is formed. At this time, the case 100 is sized to be portable, and an anti-slip member made of rubber is formed to prevent the case 100 from slipping or coming off when held by the user. In addition, the case 100 is formed with a case cover 110 that is detachably coupled to one end, and one end of the case 100 to which the case cover 110 is coupled is formed with a circular cross-section, and the other end provides a grip when held by the user. In order to increase , it is preferable that it is formed in a flatter shape than one end. Additionally, the case cover 110 is coupled to the case 100 through a screw connection or interference fit.

In another embodiment, an opening device is formed on the case cover 110 to be detachable and opens the patient's eyes 10 while maintaining a constant distance from the patient's eyes 10. At this time, the opening device is formed on a coupling frame coupled to the case cover 110 and one end of the coupling frame, and a joining member in contact with the patient's eyelid and a sliding device for sliding the plurality of joining members are formed. The coupling frame is inserted into the case cover 110, and the distance between the case 100 and the eye 10 is determined depending on the length of the coupling frame. In addition, a reflector is formed on the outside of the coupling frame to allow light to be irradiated directly into the pupil 11, and the reflector is formed to be removable. And the joining member is made of rubber, silicone, etc. to open the patient's eyelids to a certain size. At this time, the plurality of joining members are formed to be in contact with each other, and are moved to the top and bottom by a sliding device, respectively. In this way, the sliding device that slides the joint member is connected to the joint member by a gear and a wire, and as the operation button formed on the sliding device is operated, the wire is wound and moves the joint member.

In addition, a light-emitting device 120 is formed on the case cover 110 to irradiate light into the pupil 11, and the light-emitting device 120 includes a light-emitting diode 121 mounted on the case cover 110 to irradiate light. is formed At this time, the light emitting diode 121 is formed of an IR LED, and the illuminance of the emitted light is adjusted by the illuminance control device 122. In this way, as the light emitting device 120 irradiates light, the size of the pupil 11 decreases, making it possible to determine the patient's condition according to the size of the pupil 11.

In addition, a display device 130 is formed on the outside of the case 100 to display the amount of change in the pupil 11 and the image captured by the imaging unit 300, and the display device 130 is detected by the detection unit 400. At the same time as the change in size of one pupil (11) is displayed, the person performing the test can directly check the image.

And inside the case 100, a control device is formed in which a battery that supplies current to the measuring device and imaging device is formed, and as a communication device is formed, the control device shares information with the user's terminal and PC through Bluetooth, Wi-Fi, etc. do.

Additionally, the battery that supplies power to the inspection device of the present invention may be a rechargeable element or a dry cell. The battery can be charged in a way that accumulates electric energy by external power, or it can be a self-generating type in which electric energy is accumulated by its own acceleration movement, sunlight, etc.

And the measuring unit 200 measures the distance between the eye 10 and the case 100 and is formed as a Time of Flight (ToF) sensor that irradiates infrared rays and detects infrared rays reflected from the eye 10. Such a measuring unit 200 is formed in the irradiation device 210 and a light receiving device 220 that receives infrared light reflected from the eye 10. At this time, the irradiation device 210 emits infrared rays, and a diffusion lens is formed to spread the infrared rays and transmit them more effectively. In addition, a light receiving device 220 is formed in the irradiation device 210 to receive reflected infrared rays, and the travel time of the infrared rays received by the light receiving device 220 is calculated to determine the distance between the eye 10 and the case 100. is to measure.

In addition, the imaging unit 300 is accommodated inside the case 100, and a camera 310 for photographing the patient's eye 10 and an adjustment device 320 formed on the camera 310 to adjust the focus are formed. do. And the camera 310 captures the size of the pupil 11 when light is irradiated by shooting an image or acquiring an image. In addition, the control device 320 can clarify the boundaries of the pupil 11, the iris 12, and the sclera 13 by adjusting the focus of the image or image captured by the camera 310.

Figure 4 is a block diagram of the detection unit 400 of the present invention.

As shown in FIG. 4, the sensing unit 400 according to an embodiment of the present invention adjusts the gap between the case 100 and the pupil 11 by the measuring unit 200 and then takes pictures at the photographing unit 300. It detects changes in the pupil (11) using images and images of one eye (10). At this time, the detection unit 400 includes an extraction server 500 that distinguishes the image captured by the photographing unit 300 and the color of the image, and a calculation server formed in the extraction server 500 to calculate the size of the pupil 11 ( 600) is formed.

Referring to Figure 5, the extraction server 500 is formed with a determination unit 510 that determines the color of the image, and is formed in the determination unit 510 to determine the pupil 11, the iris 12, and the sclera 13. A correction unit 520 is formed to correct a color different from that of the other color. Specifically, the extraction server 500 corrects the thread veins and foreign substances in addition to the sclera 13, iris 12, and pupil 11, which are formed in black and white in the images and images taken by the photographing unit 300, and the judgment unit 510 ) to determine blood vessels and foreign substances. Then, the correction unit 520 deletes the veins and foreign substances determined by the judgment unit 510 and transmits them to the calculation server 600.

Also, referring to FIG. 6, the calculation server 600 is formed with a division unit 610 that divides the image or image from which blood vessels and foreign substances have been removed from the extraction server 500 into a plurality of pixels 20. At this time, the dividing unit 610 divides the video or image into sections and divides it into a plurality of pixels 20 by setting a plurality of dividing lines horizontally and vertically according to the resolution. And the image or image divided into a plurality of pixels 20 in the division unit 610 is converted to grayscale (grayscale), which is formed in 9 levels of gray from white to black, in the conversion unit 620. This conversion unit 620 is formed with a designation part 621 that designates pixel values 20 from level 0 to level 9 from white to black with gray scale applied to the plurality of pixels 20, and the designation part ( 621), the closer it is to black, the higher the number is assigned. Then, the designator 621 sets the average pixel value 20 of the iris 12 position and the average pixel value 20 of the pupil 11 position to classify.

For example, if the average pixel value (20) of the iris (12) is 4 to 6, the pixel value (20) is set to 5 to compensate, and the pixel value (20) of the pupil (11) is darker than that of the iris (12). If it is formed from 8 to 9, the pixel value (20) is set to 8 to more clearly distinguish the pupil (11) and iris (12).

Referring to FIG. 7, among the iris 12 and the pupil 11 divided in this way, the pixel 20 formed in the pupil 11 is selected in the selection unit 622, and the pixel selected in the selection unit 622 ( 11) The calculation unit 630 determines the size of the pixel 20 according to the quantity of the pixel 20 inside. And the calculation unit 630 is a pixel measurement unit 631 that measures the quantity of pixels 20 formed horizontally or vertically with respect to the center of the pupil 11 in order to measure the size of the pupil 11 formed in a circle. ) is formed. Accordingly, the exact size of the pupil 11 is determined. Specifically, if the size of the pixel 20 is set to 1 mm and 20 pixels 20 are formed in the pupil 11, the size of the pixel 11 is formed to be 20 mm.

Additionally, a general grayscale image refers to 256 shades of gray ranging from 0 (black) to 255 (white), and the number of grayscale divisions can be determined by the user's selection.

However, in classifying the pupil, iris, etc., classifying the pixel value 20 from level 0 to level 9 in the designation unit 621 is in consideration of economy and efficiency in realizing the inspection politics of the present invention.

And after the quantity of pixels 20 of the pupil 11 is measured in the pixel measurement unit 631, the light emitting device 120 irradiates light to the pupil 11 to detect a change in the pupil 11 (a size calculation unit) 632) is formed, and the size calculation unit 632 measures the exact size of the pupil 11 according to the quantity of pixels 20 before and after light is irradiated.

In this way, measuring the size of the pupil 11 by assigning a gray scale value to the pixel 20 can simply and quickly measure accurate changes in the pupil 11.

In the above, a pupil response test device according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. In addition, a person skilled in the art who understands the spirit of the present invention will be able to easily suggest other embodiments by adding, changing, deleting, or adding components, etc., within the scope of the same spirit, but this is also within the scope of the present invention. They will say it costs money.

10: Eye 11: Pupil
12: Iris 13: Sclera
20: Pixel 21: Pixel value
100: case 110: case cover
120: light emitting device 121: light emitting diode
122: Illuminance control device 130: Display device
200: Measuring unit 210: Survey device
220: light receiving device 300: photographing unit
310: Camera 320: Controller
400: detection unit 500: extraction server
510: judgment unit 520: correction unit
600: calculation server 610: division unit
620: conversion unit 621: designation unit
622: selection unit 630: calculation unit
631: Pixel measurement unit 632: Size calculation unit

Claims (10)

In the pupil response test device that detects changes in the size of the pupil (11) by photographing the eye (10),
Case 100 where light is irradiated from one end;
A measuring unit 200 formed at one end of the case 100 and measuring the distance between the eye 10 and the case 100;
An imaging unit 300 formed on the measuring unit 200 and photographing the eye 10;
A pupil response test device comprising a detection unit (400) connected to the imaging unit (300) and detecting changes in the pupil (11).
In claim 1,
A case cover 110 formed at one end of the case 100 and coupled to be detachable;
a light-emitting device 120 formed on the case cover 110 and emitting light toward the front;
A pupil reaction test device comprising a display device (130) exposed to the outside of the case (100) and displaying changes in the pupil (11).
In claim 2,
a light emitting diode 121 formed on the light emitting device 120 and mounted on the case cover 110 to emit light;
A pupil response test device comprising: an illuminance control device (122) connected to the light emitting diode (121) and controlling the illuminance of light.
In claim 1,
An irradiation device 210 formed on the measuring unit 200 and irradiating infrared rays;
A pupil response test device comprising a light receiving device (220) formed on the irradiation device (210) and receiving infrared rays reflected from the eye (10).
In claim 1,
A camera 310 formed in the photographing unit 300 and photographing the eye 10;
A pupil response test device comprising a control device 320 formed on the camera 310 and controlling focus.
In claim 1,
An extraction server 500 formed in the sensing unit 400 and extracting the pupil 11 and the iris 12 by distinguishing the colors of the image captured by the photographing unit 300;
A pupil reaction test device comprising a calculation server (600) formed on the extraction server (500) and calculating the size of the pupil (11).
In claim 6,
A determination unit 510 formed in the extraction server 500 to determine the color of the image;
A pupil response test device including a correction unit 520 formed in the determination unit 510 and correcting a color different from that of the pupil 11, iris 12, and sclera 13.
In claim 6,
A dividing unit 610 formed in the calculation server 600 to divide the pupil 11 and the iris 12 into a plurality of pixels 20;
a conversion unit 620 formed in the division unit 610 and converting the plurality of pixels 20 into gray scale;
A pupil response test device comprising a calculation unit 630 formed in the conversion unit 620 and calculating a distance change of the pixel 20 converted to gray scale.
In claim 8,
A designation unit 621 formed in the conversion unit 620 and designating a pixel value 20 to which gray scale is applied to a plurality of pixels 20;
A pupil response test device comprising a selection unit 622 formed in the designation unit 621 and selecting the pixel 20 formed in the pupil 11.
In claim 8,
a pixel measurement unit 631 formed in the calculation unit 630 and measuring the quantity of pixels 20 divided by the division unit 610;
A pupil response test device comprising a size calculation unit 632 formed in the pixel measurement unit 631 and calculating a change in size of the pupil 11.