JP2015085199A - Eyeball temperature measurement and analysis system, reception analysis apparatus, and eyeball temperature measurement and analysis method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an eyeball temperature measurement and analysis system, a reception analysis apparatus, and an eyeball temperature measurement and analysis method.SOLUTION: There is provided an eyeball temperature measurement and analysis system including an eyeball temperature measurement apparatus provided on a surface of an eyeball and a reception analysis apparatus. The eyeball temperature measurement apparatus includes: a temperature detection device which generates an electric signal depending on temperature of the surface of the eyeball; and a signal transmission device for converting the electric signal to a wireless signal. The reception analysis apparatus includes: a signal reception unit for receiving the wireless signal; and an analysis unit for determining whether or not the temperature of the eyeball is normal by analyzing the temperature of the eyeball on the basis of the wireless signal.

Description

  The present invention relates to an eyeball temperature measurement and analysis system, a reception analysis apparatus, and a method thereof, and more particularly, to a system, an analysis apparatus, and a method for analyzing and judging the temperature of the eyeball surface.

  The temperature of the eyeball surface is one important indicator that responds to the health or disease of the eyeball because it corresponds to the state of the muscles or layers in each part of the eyeball. When inflammation or muscles are too tense (convulsions) in the eyeball, the eyeball temperature rises. For example, the surface temperature of a myopic eyeball due to ciliary muscle spasm increases. However, in patients with xerophthalmia, the amount of tears that reach the surface of the eyeball decreases due to opening of the eyelids, so the surface temperature of the eyeball decreases. Therefore, the rise and fall of the eyeball surface temperature can be used to judge eye health and illness.

  D. M.M. Maurice and A.M. S. Mushin, in his paper “Production of Myopia in Rabbits by Raised Body-Temperature and Increased Intraocular Pressure” (The Lancet; November 26, 1966, pp. 1160-1162), raised the body temperature of young rabbits to 41-43 ° C. If maintained for about 30 minutes, the rabbit dioptres will be -0.75 or higher. The cause of myopia is that the refractive power of the eye is too large, and parallel rays parallel to the eyeball axis gather in front of the retina, so that a clear image cannot be formed on the retina. Furthermore, the change in the center of the eyeball also leads to the temperature of the eyeball. Ciliary muscle spasms may result in unrecoverable intrinsic myopia by stimulating eyeball elongation. This paper also demonstrates that eyeball temperature is related to myopia and eyeball changes. As the eyeball temperature rises, the eyeball expands. Further, since the tissue around the eyeball has a stronger force against the expansion, the expansion force is transmitted to the back of the eyeball. As a result of the unreasonable deformation of the eyeball over a long period of time, the eyeball shaft becomes a longer eyeball.

  Also, a paper by Tien-Chun Chang et al. “Application of digital infrared thermal imaging in determining inflammatory state and follow-up effect of methylprednisolone pulse therapy in patients with Graves'ophthalmopathy” (Graefes Arch Clin Exp Ophthalmol; 2008, 246 vol., Pp 45-49) is effective for observing and recording eyeball inflammation by measuring a part of the temperature with far-infrared thermal images by computer for Graves' disease. . Also, a paper by hyang-Rong Shih et al. “The application of temperature measurement of the eyes by digital infrared thermal imaging as a prognostic factor of methylprednisolone pulse therapy for Graves' ophthalmopathy” (Acta Ophthalmologica; 2010 vol. 88, pp. 164-159 As can be seen, the eyeball temperature decreases with high dose steroid therapy. The degree of temperature drop is related to the eyeball temperature before treatment. These studies show that far infrared thermal imaging temperature measurements contribute to predicting the effect of treating thyroid ophthalmopathy with high doses of steroids.

  In addition, since electronic devices for different uses are miniaturized, the application of these electronic devices to wearable or insertable medical (or calibration) devices is also increasing. For example, in US 2012/0245444, a wearable contact lens with a biochip is posted and used to measure the concentration of a specific chemical in the anterior cornea (tear) membrane. In addition, in US 2010/0234717, US 2013/0041245 and PCT international application WO 03/001991, a contact lens to which an electronic pressure sensing device is coupled is posted and used for measuring the pressure in the eyeball. However, there are few patent documents and non-patent documents that measure the temperature of the eyeball surface with a contact lens combined with an electronic temperature measuring device, and the health and illness of the eyeball are judged by a contact lens having a temperature measurement effect. There is no prior literature on which the technical contents are posted.

  As described above, there is a need for a system and method that can determine eye health and illness in the area of eye treatment and eyesight calibration, and thus can be widely used in preventive medicine and calibration monitoring (monitoring).

  An object of the present invention is to provide an eyeball temperature measurement and analysis system, a reception analysis apparatus, and a method thereof, and by recording eyeball surface temperature data, analyze and judge eye health and illness. Can be used for preventive medicine and calibration monitors.

  In order to achieve the above object, the present invention includes an eyeball temperature measuring device provided on the eyeball surface and a reception analyzer, and the eyeball temperature measuring device generates an electrical signal according to the temperature of the eyeball surface. A temperature sensing device; and a signal transmission device that converts the electrical signal into a wireless signal. The reception analysis device includes a signal receiving unit that receives the wireless signal, and an eyepiece surface based on the wireless signal. There is provided an eyeball temperature measurement and analysis system comprising an analysis unit that analyzes temperature to determine whether the temperature is normal.

  The present invention further includes a signal receiving unit for receiving a wireless signal including eyeball surface temperature data, and an analysis unit for determining whether the eyeball surface temperature is normal based on the wireless signal. And a reception analysis apparatus for the eyeball temperature.

  The present invention includes a step of measuring the surface temperature of an eyeball by an eyeball temperature measuring device provided on the surface of the eyeball, a step of transmitting the surface temperature data by a wireless signal, and a step of receiving the wireless signal; And measuring the eyeball surface temperature based on the wireless signal to determine whether the eyeball surface is normal or not.

6 is a diagram showing temperature differences between daytime and nighttime with respect to the eyeball surface of the pseudomyopia group and normal vision group for Table 1. FIG. It is a reference figure showing an eyeball temperature measuring device concerning the present invention. FIG. 3 is a reference diagram showing a state where the eyeball temperature measuring device shown in FIG. 2 is mounted on the surface of the eyeball. It is a reference figure showing the measurement and analysis system of the eyeball temperature concerning the present invention. It is a reference figure which shows the other Example of the measurement and analysis system of the center temperature concerning this invention. It is a flowchart which shows the measurement and analysis method of the eyeball temperature concerning this invention. It is a reference figure showing other examples of an eyeball temperature measuring device concerning the present invention. It is a reference figure which shows the state with which the eyeball temperature measuring apparatus shown in FIG. 7 is mounted | worn on the surface of an eyeball.

  For the sake of brevity and clarity, the structure of the present invention is shown in the accompanying drawings, and the features and techniques equivalent to those of the prior art are omitted. Also, dimensions in the drawings are not shown for the purpose of limitation. For example, in order to understand the present invention, some parts shown in the drawings can be enlarged with respect to other parts. The same reference numerals in different drawings denote the same members.

  As described above, the increase or decrease in the eyeball surface temperature can be used to determine eye health or illness. In particular, convulsions of the ciliary muscle cause myopia and the surface temperature rises. Table 1 below shows data obtained by measuring the eyeball surface temperature for the pseudomyopia group and the normal vision group.

  Also in the medical literature, pay attention to objects (books, TVs, PCs, mobile phones, etc.) whose body temperature has risen (high fever) or whose eyeball surface temperature is short distance (especially for short distance and long distance targets) Attention)), the ciliary muscles are in a high tensile state for a long time, and the temperature of the eyeball increases with this high tensile state. Overuse the ciliary muscle during the day, but the temperature should drop as the ciliary muscle relaxes when sleeping at night. On the other hand, since the heel closes when sleeping, it interferes with heat dissipation to the outside, that is, the temperature of the eyeball is difficult or cannot be lowered. At the same time as sleeping, as the posture of the body changes (for example, lies down), the pressure received by the eyeball also changes, and the pressure around the vitreous body of the eyeball further improves. And high temperature and high pressure are transmitted from the inside to the back of the centerpiece. As a result, the eyeball extends along the direction of the eyeball axis. If the situation occurs over a long period of time, the length in the direction of the eyeball axis will increase, and finally myopia will occur.

  6 is a diagram showing temperature differences between daytime and nighttime with respect to the eyeball surface of the pseudomyopia group and normal vision group for Table 1. FIG. As can be seen from FIG. 1, the temperature difference between the daytime and nighttime for the eyeball surface in the pseudomyopia group is larger, that is, the nighttime temperature on the eyeball surface is clearly higher. On the other hand, the temperature difference between the daytime and nighttime with respect to the eyeball surface in the normal vision group is smaller, that is, the nighttime temperature on the eyeball surface is slightly higher. By recording the temperature data of the eyeball surface, it is possible to analyze and judge the health and illness of the eye, so that it can be used for preventive medicine and calibration monitoring. The present invention is not limited to use for the determination of myopia, and each embodiment of the present invention can be applied to dry eye disease or other eye diseases in which temperature can be changed. Also, the conditions of each embodiment can be changed according to the temperature change width and method. FIG. 1 shows the case of measuring the eyeball surface temperature at daytime and nighttime for two groups. The present invention measures the average difference in eyeball surface temperature between daytime and nighttime for the same person over a long period of time, or the maximum change in eyeball surface temperature at the same time every day for the same person or An average value can be measured, or an average value and a change value of the eyeball surface temperature at a specific time or a specific time zone can be measured. The present invention is not limited to the above-described embodiment, and the present invention can also be applied to measurement of a difference value or an average value of the eyeball surface temperature for a long time or a short time.

  As described above, the increase or decrease in the eyeball surface temperature can be used to determine eye health or illness. Especially in patients with xerophthalmia, the eyeball surface temperature changes clearly due to lack of tears. Table 2 below shows data for measuring the eyeball surface temperature for a patient group with dry eye disease and a patient group without dry eye disease.

To: The eyeball surface temperature measured immediately after the eyes winked and the eyelids were opened.
Tc: The eyeball surface temperature measured again after 6 seconds of measurement of To (or any time point between 6 seconds and 10 seconds), and the wrinkles remain open between the measurements of To and Tc.
Td: a difference value of To sum Tc.

  As can be seen from the data in Table 2, the difference value Td of the patient group with xerophthalmia is clearly lower than the difference value Td of the patient group without xerophthalmia. Therefore, this is taken as the basis for the occurrence of xerophthalmia. Moreover, it can be judged as follows. If the difference value Td is less than 0.2 ° C., it can be determined that there is xerophthalmia. If the difference value Td is 0.2 ° C. to 0.4 ° C., it can be determined that there is a risk of xerophthalmia. If the difference value Td is greater than 0.4 ° C., it can be determined that the possibility of dry eye disease is low. The present invention is not limited to this embodiment, and other judgment rules can be determined by using a single numerical value, or a curve formed from a plurality of numerical values of temperature value To or Tc. Judgment rules can be determined by changes (rapid increase, rapid decrease, increase, decrease) or gradient changes. Actually, the contents of the decision rule and the decision method change according to different symptoms of the eyes.

  FIG. 2 is a reference diagram showing an eyeball temperature measuring apparatus according to the present invention. The eyeball temperature measuring device in this embodiment is shown as a contact lens 20 having a temperature measurement effect, but the present invention is not limited to this embodiment, and any mounting device that can be attached to the eyeball surface and measure the eyeball temperature. There may be. The contact lens 20 mainly includes a transparent base material 21, a temperature sensing device (or temperature sensing circuit) 22, an antenna 23, and a signal transmission device 24. The material of the transparent base material 21 is silicon hydrogel (eg, HEMA), which has a merit of high oxygen permeability and excellent hydrophilicity. Can be installed. The material of the transparent base material 21 may be another transparent polymer material, but is not limited to this embodiment. The antenna 23 can transmit a wireless signal to the outside and can also receive energy from the outside. For example, the antenna 23 forms an electromagnetic link (inductive link or inductive coupling) with a radio frequency signal or other electromagnetic wave. As a result, electric power is generated and supplied to the temperature sensing device 22 and the signal transmission device 24. In addition, a device that emits a radio frequency signal or other electromagnetic wave can be installed in a scarf or in a pocket, or can be installed in another portable device (for example, a mobile phone or a bluetooth smartphone). Moreover, a present Example is not restricted to this, The battery of a micromachine (MEMS) may be provided in the surface of the said transparent base material 21, or inside.

  Since the area of the contact lens 20 is limited, the number of coils and dimensions of the antenna 23 are also limited. In order to solve the problem that the signal strength of the antenna 23 is insufficient, by attaching another external antenna around the eyes (for example, the eye socket), it is possible to receive signals even at a signal receiving device located at a far place. Become.

  In order to monitor the eyeball temperature change during the daytime and / or at bedtime for a long time, a plurality of annular lines (that is, temperature sensing devices) that can sense the temperature on the surface of the transparent base material 21 with the center of the contact lens 20 as a common center. 22), and the circular line may be a plurality of circular ring lines, a polygonal ring line or an irregular ring line. The temperature sensing device 22 can measure changes in temperature and reaction temperature, and may be an application specific circuit (ASIC) or a micromachine (MEMS), or nano or pico (PICO). It may be a sensing device comprised of a level chemical material, metal material or biomaterial. The signal transmission device 24 can convert an electrical signal (for example, a voltage signal or a current signal) generated from the temperature sensing device 22 into a radio frequency signal (RF) and transmit a wireless signal to the outside through the antenna 23. However, the present invention is not limited to the conversion from an electrical signal to a radio frequency signal (RF), but can also be converted to a signal such as Bluetooth (Bluetooth®) or WiFi. The antenna 23 is provided on the surface of the transparent base 21 and is a plurality of annular lines located outside the temperature sensing device, and is a wireless signal corresponding to a communication agreement, similar to the above-described annular line. Can be sent to the outside.

  FIG. 3 is a reference diagram showing a state where the eyeball temperature measuring device shown in FIG. 2 is attached to the surface of the eyeball. As shown in FIG. 3, when the user wears the contact lens 20 on the surface of the eyeball 30, the temperature sensing device 22 and the antenna 23 having the annular line are not provided in the visual light receiving area, so that the user enters the pupil. The light is not blocked, and it is not only worn during activities until noon, but it can also be worn at bedtime to measure temperature realistically. The contact lens 20 having the temperature measurement effect can be worn for a long time during daily life or at work, and the user is not limited to the place where the temperature measurement device is installed, for example, in front of the infrared temperature measurement device. Since the measurement can be performed while sleeping or for a long time, the accuracy of the determination result can be improved.

  FIG. 4 is a reference diagram showing an eyeball temperature measurement and analysis system according to the present invention. The system 40 includes a contact lens 20, a mobile interrogation unit 41, a data receiving unit 42, and a computer 43. The mobile question and answer unit 41 provides power to the signal transmission device 24 and the temperature sensing device 22 in a wireless manner by an annular sensing circuit 411, converts the wireless signal to obtain the electrical signal, Further, the electrical signal is converted from analog to digital to acquire digital data of the electronic signal, and thus a radio frequency signal is acquired from the digital data. The data receiving unit 42 receives the radio frequency signal by radio reception from the mobile question-and-answer unit 41 and converts the radio frequency signal to obtain digital data of the electronic signal. The computer 42 stores a correspondence table of digital data and eyeball surface temperature, and obtains the digital data by being electrically connected to the data receiving unit 42, and obtains the eyeball surface temperature based on the table. The temperature is displayed and stored.

  The computer 42 can analyze and store eyeball surface temperature data, and determine whether the eyeball surface temperature is normal. For example, the occurrence of myopia or pseudomyopia can be determined based on the difference in eyeball surface temperature between nighttime and daytime (see Table 1). If the difference value is smaller than 0.1 ° C., it can be determined that there is no fear of myopia. If the difference value is 0.1 ° C to 0.3 ° C, it can be determined that there is a possibility of myopia. If the difference value is greater than 0.3 ° C., it can be determined that there is myopia. The determination result can be displayed on the monitor of the computer 43 or can be displayed by the color of the instruction lamp in the data receiving unit 42. For example, green indicates that there is no fear of myopia, yellow indicates that there is a possibility of myopia, and red indicates that there should be myopia. The present invention is not limited to the above-described embodiments and determination rules, and can be determined according to the actual eyeball surface temperature and different symptoms.

  The mobile question-and-answer unit 41, the data receiving unit 42, and the data analysis judgment (in this embodiment by the computer 43) can be coordinated with a reception analysis device, and the reception analysis device has a specific software. Or an application program installed computer, tablet PC, smartphone or smart watch, and the annular sensing circuit 411 may be coupled to the device or installed in the device.

  FIG. 5 is a reference diagram showing another embodiment of the eye temperature measurement and analysis system according to the present invention. The system 50 uses a mobile phone 51 or a desktop computer 52 as a reception analysis device, and the reception analysis device has at least a signal reception unit and an analysis unit. Upon receiving the signal, the analysis unit analyzes based on the wireless signal to determine whether the eyeball surface temperature is normal.

  FIG. 6 is a flow chart showing the eye temperature measurement and analysis method according to the present invention. The present invention includes a step 61 of measuring the surface temperature of the eyeball using a contact lens having a temperature measurement effect, a step 62 in which the surface temperature data is transmitted by a wireless signal, and a step 63 of receiving the wireless signal. And a step 64 of analyzing the temperature of the eyeball surface based on the wireless signal to determine whether the eyeball surface is normal or not.

  For the contact lens 20 of FIG. 3, FIG. 7 is a reference diagram showing another embodiment of the eyeball temperature measuring device according to the present invention. When the eyeball temperature measuring device 70 of this embodiment is provided on the eyeball surface, it is not covered with the pupil. The apparatus of this embodiment may also be applied to the above-described eyeball temperature measurement and analysis system, i.e., a wireless power supply that receives power supply from the mobile question and answer unit 41 and includes eyeball surface temperature data. A signal can be transmitted. The eyeball temperature measuring device 70 mainly includes a base material 71, a temperature sensing device (or temperature sensing circuit) 72, an antenna 73, and a signal transmission device 74. The material of the base material 71 in the present embodiment is a silicon hydrogel polyester or polyacrylamide, and may be a material that transmits, translucent, or does not transmit light. The base material 71 may be composed of another polymer material, and may be a soft or hard material (for example, polysiloxane, polymethyl methacrylate resin, need to be shaped according to the degree of curvature of the centerpiece). It is not restricted to an Example. The antenna 73 can transmit a wireless signal to the outside and can receive energy from the outside. For example, the antenna 73 performs an electromagnetic link (inductive link or inductive coupling) by a radio frequency signal or other electromagnetic waves. Occurrence provides power to the temperature sensing device 72 and the signal transmission device 74. In addition, by providing a micro-type battery on the surface of the base 71, power can be provided to the temperature sensing device 72 and the signal transmission device 74.

  Since the eyeball temperature measuring device 70 is provided in the bag (see FIG. 8), its area is limited, and the number of coils and the length of the antenna 73 are also limited. In order to compensate for the insufficient signal strength of the antenna 73, an external antenna can be attached around the eyes (for example, orbit). Therefore, the signal can be strengthened to be received by a signal receiving device at a far place.

  In order to monitor the eyeball temperature change during the daytime and / or at bedtime for a long time, a plurality of annular lines (that is, temperature sensing devices 72) capable of sensing the temperature are installed on the surface of the base material 71, It may be a plurality of circular ring lines, polygonal ring lines or irregular ring lines. The temperature sensing device 72 can measure changes in temperature and reaction temperature, and may be an application-specific IC (ASIC) or a micromachine (MEMS), or nano or pico (PICO). It may be a sensing device comprised of a level chemical material, metal material or biomaterial. The signal transmission device 74 can convert an electric signal (for example, a voltage signal or a current signal) generated from the temperature sensing device 72 into a radio frequency signal (RF) and transmit a wireless signal to the outside through the antenna 73. However, the present invention is not limited to the conversion from an electrical signal to a radio frequency signal (RF), but can also be converted to a signal such as Bluetooth or WiFi. The antenna 73 is provided on the surface of the base material 71 and is a plurality of annular lines located outside the temperature sensing device 72, so that the wireless signal corresponding to the communication agreement is transmitted. Can be sent to the outside.

  FIG. 8 is a reference diagram illustrating a state in which the eyeball temperature measuring device according to the present invention is mounted on the eyeball surface. As shown in FIG. 8, when the eyeball temperature measuring device 70 is installed on the surface of the eyeball 30 and the inner side of the eyelid (lower eyelid or upper eyelid), since it is not a visual light receiving area, the base material 71 can select an opaque material, That is, it is not necessary to consider the blocking state of the light rays entering the pupil. Moreover, it can be worn not only during activities until noon, but can also be worn at bedtime to measure temperature realistically. The shape of the base material 71 can be a half moon shape or a rectangle as shown in the figure for easy installation inside the bag.

20 contact lens 21 transparent substrate 22 temperature sensing device 23 antenna 24 signal transmission device 30 eyeball 40 system 41 mobile question and answer unit 42 data reception unit 43 computer 411 ring sensing circuit 50 system 51 mobile phone 52 desktop computer 61-64 Step 70 Eye temperature measuring device 71 Base material 72 Temperature sensing device 73 Antenna 74 Signal transmission device

Claims (17)

It has an eyeball temperature measuring device provided on the eyeball surface, and a reception analyzer,
The eyeball temperature measuring device includes a temperature sensing device that generates an electrical signal according to the temperature of the eyeball surface, and a signal transmission device that converts the electrical signal into a wireless signal.
The reception analysis apparatus includes: a signal receiving unit that receives the wireless signal; and an analysis unit that analyzes the temperature of the eyeball surface based on the wireless signal to determine whether the eyeball surface is normal. Temperature measurement and analysis system. The eyeball temperature measuring device further includes an antenna for transmitting the wireless signal to the outside,
The eyeball temperature measurement and analysis system according to claim 1, wherein the antenna provides power to the temperature sensing device and the signal transmission device by generating electromagnetic coupling power by an external electromagnetic wave. The eyeball temperature measurement and analysis system according to claim 2, further comprising an external antenna through which the wireless signal is transmitted. The analysis unit may determine whether or not there is an eyeball disease based on a temperature value of the eyeball surface, a temperature value difference between two time points, a temperature average value of a plurality of consecutive time points, or a change thereof. Item 1. The eye temperature measurement and analysis system according to Item 1. When the difference between the eyeball surface temperature at night and daytime is lower than the lower limit, it is determined that there is no myopia or pseudomyopia,
When the difference value is any numerical value between the lower limit value and the upper limit value, it is determined that there is a possibility of myopia or pseudomyopia,
The eyeball temperature measurement and analysis system according to claim 4, wherein when the difference value is larger than the upper limit value, it is determined that there is myopia or pseudomyopia. The eyeball temperature measurement and analysis system according to claim 4, wherein if the difference value between the eyeball temperatures measured at two time points is lower than the lower limit value, it is determined that there is xerophthalmia. The eyeball temperature values measured at the two time points are measured again at the eyeball surface temperature measured immediately after the eye winks and the eyelid is opened and at any time point between 6 seconds and 10 seconds after the measurement. The eyeball surface temperature, and the wrinkles remain open during the measurement,
When the difference value of the eyeball temperature measured at the two time points is 0.2 ° C. to 0.4 ° C., it is determined that there is a risk of xerophthalmia,
7. The eyeball temperature measurement according to claim 6, wherein if the difference value of the eyeball temperature measured at the two time points is greater than 0.4 ° C., it is determined that the possibility of xerophthalmia is low. Analysis system. The eyeball temperature measurement device is a contact lens having a temperature measurement effect,
The eyeball temperature measuring device according to claim 1, wherein the eyeball temperature measuring device is provided inside the eyeball surface and the inside of the eyelid to measure the eyeball temperature, and the size of the eyeball temperature measuring device is not covered by the pupil. Measurement and analysis system. A signal receiving unit for receiving a wireless signal including temperature data of the eyeball surface, and an analysis unit for analyzing and judging whether the eyeball is normal based on the wireless signal Temperature receiving analyzer. The analysis unit determines whether the eyeball is ill based on a temperature value of the eyeball surface, a temperature value difference between two time points, a temperature average value of a plurality of consecutive time points, or a change thereof. 9. The eye temperature receiving and analyzing apparatus according to 9. When the difference between the eyeball surface temperature at night and daytime is lower than the lower limit, it is determined that there is no myopia or pseudomyopia,
When the difference value is any numerical value between the lower limit value and the upper limit value, it is determined that there is a possibility of myopia or pseudomyopia,
The eye temperature receiving analysis apparatus according to claim 10, wherein if the difference value is larger than the upper limit value, it is determined that there is myopia or pseudomyopia. The eyeball temperature reception analysis device according to claim 10, wherein if the difference value of the eyeball temperature measured at two time points is lower than the lower limit value, it is determined that there is xerophthalmia. The eyeball temperature values measured at the two time points are measured again at the eyeball surface temperature measured immediately after the eye winks and the eyelid is opened and at any time point between 6 seconds and 10 seconds after the measurement. The eyeball surface temperature, and the wrinkles remain open during the measurement,
When the difference value of the eyeball temperature measured at the two time points is 0.2 ° C. to 0.4 ° C., it is determined that there is a risk of xerophthalmia,
The eyeball temperature reception analysis according to claim 12, wherein if the difference value of the eyeball temperature measured at the two time points is greater than 0.4 ° C, it is determined that the possibility of dry eye disease is low. apparatus. The signal receiving unit includes a mobile question and answer unit that receives the wireless signal and generates a radio frequency signal, and a data receiving unit that receives the radio frequency signal and converts it into temperature data of the eyeball surface. The eyeball temperature receiving and analyzing apparatus according to claim 9. Measuring the surface temperature of the eyeball with an eyeball temperature measuring device provided on the eyeball surface;
Transmitting the surface temperature data by a wireless signal;
Receiving the wireless signal;
Analyzing the temperature of the eyeball surface based on the wireless signal and determining whether the eyeball surface is normal or not. The step of analyzing and determining may further determine whether or not the eyeball is ill by the temperature value of the eyeball surface, the temperature value difference between two time points, the temperature average value of a plurality of consecutive time points, or a change thereof. The eyeball temperature measurement and analysis method according to claim 15, wherein the eyeball temperature measurement and analysis method is included. If the difference is less than or equal to the lower limit, determine that the eye should be sick or not sick,
If the difference is between the lower limit and the upper limit, determine that the eye may be ill;
The eyeball temperature measurement and analysis method according to claim 16, wherein if the difference is equal to or greater than an upper limit value, it is determined that the eye should be ill or should not be ill.