WO2023075029A1 - System and method for infant eyesight restoration and presbyopia relief through smart glasses, smartphones, and smartwatches - Google Patents

Abstract

The present invention relates to a system for infants eyesight restoration and presbyopia relief through smart glasses, smartphones, and smartwatches. In the system for infant eyesight restoration and presbyopia relief through smart glasses, smartphones, and smartwatches, personal terminals (1-1 to 1-N), hospital (or traditional Korean medicine hospital) computers (2-1 to 2-N), and an operator computer server (3) are connected to each other through a wired/wireless communication network, a smartwatch (430 or 530) capable of communicating with the personal terminals (1-1 to 1-N) through Bluetooth is provided, smart glasses (or eyesight correction glasses or lensless glasses) having a QR code and a Bluetooth function and the smartwatch (430 or 530) can communicate with each other through Bluetooth, the hospital computers (2-1 to 2-N) have an eyesight restoration program storage unit (330), the eyesight restoration program storage unit (330) is provided in an application (APP) form so as to be downloadable and installable in the personal terminals (1-1 to 1-N), and can also be downloaded from the operator server (3) and installed, and while an individual wears the smart glasses and the smart glasses, the smartphone, and the smartwatch are connected to each other through Bluetooth, the eyesight restoration program is executed through the smartphone (or the smartwatch) to which the eyesight restoration program has been downloaded, so that an individual's eyesight restoration movement is performed for a predetermined time according to the voice and display guidance of the eyesight restoration program, and thus eyesight can be restored.

Description

System and method for vision recovery and presbyopia recovery in children through smart glasses, smart phones and smart watches

The present invention relates to a system and method for vision recovery and presbyopia recovery in children through smart glasses, smartphones and smart watches, and more specifically, a Bluetooth data communication function, a QR code identification function, a partial replacement and assembly function, and a vision correction function. While wearing smart glasses with a Bluetooth device (wearing polarized glasses with a QR code or wearing glasses without lenses, respectively), run a vision recovery program through a smart watch and smartphone to recover vision for a certain period of time By performing vision recovery exercises through the program, children's eyesight is restored to corrected vision in children (referring to a visual acuity of 0.5 to 0.8 measured through an optometry device without glasses), presbyopia is prevented, and presbyopia is converted to corrected eyesight. It relates to a pediatric vision recovery and presbyopia recovery system and method through a new type of smart glasses, a smart phone, and a smart watch that can restore and improve the visual acuity of the eye to uncorrected vision.

In today's era where interest in health monitoring is increasing and early detection and prevention of various medical diseases, disorders and diseases is important, people are often required to visit medical professionals for various tests and examinations. In general, people regularly consult specialists (e.g., For example, once a year, once every two years, etc.) is recommended.

One of these areas requiring regular visits by a medical professional relates to the examination of the human eye. Generally, an examination of a person's eye is one or more for diagnosing and monitoring eye health, such as detecting glaucoma and retinal disorders, examining pupils, and measuring corneal sensitivity. tests, and/or one or more tests to assess visual ability and visual acuity, such as determining refractive errors and detecting color blindness.

Receiving regular and repeated eye health examinations and eye examinations has many important advantages. For example, as with many other types of medical examinations, a person's periodic visits and examinations allow a professional to monitor and track the health of an individual's eyes and determine any disturbances in the patient's eyes and/or vision. diseases, diseases and other changes can be detected and diagnosed. Importantly, this allows rapid detection, diagnosis and treatment of many diseases, which in turn often increases the likelihood that treatment will be successful. Indeed, many disorders and diseases are generally treatable or even preventable if detected and diagnosed quickly and accurately. It is also well known that changes in visual acuity, for example, at certain periods of a person's life, often occur more or less abruptly, and that visual acuity may persist over a long period of time. Accordingly, another important advantage of a regular eye examination is that it enables an up to date and as accurate vision supplementation prescription for an individual.

However, although the conventional optometry technology as described above is absolutely necessary for measuring eyesight, there is a limit to suggesting an appropriate method of restoring eyesight to those who are weakened or have abnormal eyesight.

[Prior art literature]

Republic of Korea Patent Registration No. 10-2032896 (registered on October 10, 2019) (Title of Invention: System and method for customer's vision and eye health examination)

The present invention was created in view of the above circumstances, and is not limited to a place, and it is possible to restore vision by performing a vision recovery exercise along a vision recovery program in a state where smart devices are connected to each other, so that it is more improved than the first measured eyesight. It is to provide a pediatric vision recovery and presbyopia recovery system and method through smart glasses, smart phones and smart watches that can restore vision.

Another object of the present invention is to record and manage the vision recovery process of a number of individuals who have continuously performed vision recovery exercises in a remote place, guide them to appropriately perform vision recovery exercises, guide them to maintain their eyesight, and are related to vision recovery. It is to provide a system and method for pediatric vision recovery and presbyopia recovery through smart glasses, smartphones and smart watches that can manage big data to monitor the entire process.

Another object of the present invention is to provide a new type of smart glasses that can assemble smart glasses having different colors and shapes by purchasing parts since the smart glasses have parts replacement and assembly functions.

According to a preferred embodiment of the present invention for achieving the above object,

In the pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches,

personal terminal (1-1,...,1-N),

Hospital (or oriental medicine hospital included) computer (2-1,...,2-N), and

The operator computer server 3 is connected to each other through a wired or wireless communication network,

Smart glasses (or vision correction glasses or Glasses without lenses) and the smart watch (430 or 530) can communicate with each other via Bluetooth,

The hospital computers 2-1, ..., 2-N have a vision recovery program storage unit 330,

The eyesight recovery program storage unit 330 is provided in the form of an application (APP) and can be downloaded and installed in personal terminals (1-1, ..., 1-N), and can also be downloaded from the operator server (3). and can be installed

While an individual wears smart glasses and the smart glasses, smart phone and smart watch are connected to each other via Bluetooth, the vision recovery program is activated through the smartphone (or smart watch) on which the vision recovery program is downloaded to perform an individual vision recovery exercise. Provided is a pediatric vision recovery and presbyopia recovery system through smart glasses, smart phones, and smart watches that allow vision recovery to be performed for a predetermined time according to the voice and display guidance of the vision recovery program.

In addition, the vision recovery program storage unit 330

A vision recovery DATA collection unit 331 that collects vision recovery data in the course of the vision recovery program;

A vision recovery time management unit 332 that manages the overall time for performing the vision recovery program.

A breathing guidance signal generating unit 333 for guiding breathing during vision recovery program execution;

A motion detection signal generator 334 for detecting body motion and generating a detection signal during the vision recovery program to guide the breathing process and pupil position in the vision recovery process accordingly.

A vision recovery information display unit 335 for displaying vision recovery information after the vision recovery program process;

A result information graph and numerical value transmission unit 336 for transmitting graphs and numerical values of results after the vision recovery program process;

A process input information display and transmission unit 337 for displaying various data information including input drugs or input natural drug information input in the course of the vision recovery program;

Including a smart watch linkage management unit 338 and a database management unit 340 that control the signal processing process while connected to the smart watch 430 or 530,

The database management unit 340

A member database (341) for storing/managing treatment information related to members, such as member names;

A treatment frequency database (342) for storing/managing the number of treatments (running a vision recovery program) of members;

A vision database (343) for storing/managing member's vision data;

A graph database 344 displaying information on the results of execution of the vision recovery program in graphs and bar graphs, and

It is characterized in that it includes a big data database 345 for managing and storing vision recovery program execution result information as big data.

also,

The user selects the past vision inquiry before starting the vision recovery exercise to query the past eyesight to view the previous eye examination chart, and it is characterized in that the previous eye examination chart can be transmitted to a mobile phone.

In addition, a digital diabetes monitor 120 for measuring diabetes, a digital blood pressure monitor 130 for measuring blood pressure, and a digital body fat meter for measuring body fat ( 140) is characterized in that it is managed together in association with the measured diabetes level, blood pressure level, and body fat level.

In addition, it is connected to the hospital computer, and the refractor 370 for measuring the pupil (pupil) refractive index (diopter) before and after the operation of the user's (or the subject or patient's) vision recovery program, and the tonometer (350) for measuring intraocular pressure ), and a visual acuity diagnostic device 360 for measuring visual acuity, which is interlocked with each measured data so that it can be managed in conjunction with measurement data, which is performance data of a vision recovery program, and can be managed for prevention and prescription management. to be characterized

According to another aspect of the present invention, in the pediatric vision recovery and presbyopia recovery method through smart glasses, smart phones and smart watches,

It is assumed that the user has previously performed potential vision measurement, uncorrected vision measurement, and corrected vision measurement process through the optometry device (not limited thereto), and selecting to start a vision recovery exercise.

Determining whether a vision recovery exercise signal is input;

When a signal to start the vision recovery exercise is input by the user, after checking the connection status of the smart glasses, smart watch, and smartphone, and if connected, a message that outputs and displays a vision recovery exercise guide message through the vision recovery program. sending a

Step of determining whether the vision recovery exercise has started,

After that, if the vision recovery exercise is started, the vision recovery exercise program is started,

The step of performing a step 1 voice message output process and guiding the pupil position and breathing method (eye closing and opening eyes);

Then, after a predetermined time has elapsed, a two-step voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

Thereafter, after a predetermined time has elapsed, a three-step voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

Thereafter, after a predetermined time has elapsed, a 4-step voice message output process is performed, and the pupil position and breathing method (closed and opened eyes) are guided;

Thereafter, it is determined whether a vision recovery exercise end signal is input, and if the eyesight recovery exercise end signal is input by the user, the number and time of the exercise related to the vision recovery exercise performed up to that time are recorded and stored, and then the stored data is stored. Provided is a pediatric vision recovery and presbyopia recovery method through smart glasses, a smart phone and a smart watch, including the step of transmitting to an operator's computer server or a hospital computer server.

In addition, after a predetermined time has elapsed after the fourth step, the step 5 voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

Thereafter, after a predetermined time has elapsed, a step 6 voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

Then, after a predetermined time has elapsed, a 7-step voice message output process is performed, and the pupil position and breathing method (closed and opened eyes) are guided, and

Thereafter, after a predetermined time has elapsed, an eight-step voice message output process is performed, and a step of guiding the position of the pupil and the breathing method (closed eyes and open eyes) is additionally performed.

In addition, in steps 1 to 4 in the vision recovery program, the position of the pupil moves clockwise from the first 12 o'clock to 3 o'clock, 6 o'clock, and 9 o'clock, and an operation to return to the original is performed, and then counterclockwise to 12 o'clock. To guide the process of breathing by opening the eyes wide and opening the mouth wide by changing the position of the pupils in each direction. It is characterized by being

also,

In steps 5 to 8 in the vision recovery program, the position of the pupil starts at an initial angle of 45 degrees in a clockwise direction, moves in directions of 90 degrees, 135 degrees, and 235 degrees, and returns to the original state. To guide the process of breathing by opening the eyes wide and opening the mouth wide by changing the position of the pupils in each direction It is characterized by being

also,

The process of steps 1 to 4 in the vision recovery program is an eye breathing exercise process,

A step of guiding to prepare for the start of the eye breathing exercise by outputting a voice message saying "Think of K-lens in your mind" as a message;

Then, the step of synchronizing eye blinking and breathing,

Thereafter, exhaling as much as possible while closing the eyes firmly, and

After that, it is characterized in that it includes a step of taking a breath as much as possible while opening the eyes.

In addition, the sound-seeing eye breathing therapy is performed in parallel,

It is characterized in that the potential vision of my eyes is considered to be 0.8, which is much higher than the current 0.3 vision, and the contents of 'My name is Kim (surname) Jeompal' are made aloud.

In addition, the smart glasses are provided with earring parts 11a and 11b and lens frame parts 12a and 12b, a speaker (with a microphone) part 36 and a Bluetooth module part 34 are installed, and a QR code (cover) ) 32 is installed, and includes an antenna unit (which may be embedded in the intenna frame) 31, a charging means 33, and a GPS means 37.

In addition, the smart glasses include a glasses control unit 530 that is connected to a smartphone terminal, operator computer server, or hospital computer server through wireless communication to enable operation, and a power supply unit 532 that provides a chargeable function for supplying power to the entire device , a Bluetooth connection unit 542 for Bluetooth communication, a speaker connection unit 544 that provides a speaker function (and / or a microphone function may be added) through a connection with the wireless earphone microphone 60, and an antenna 31 Provides a wireless signal connector 546 that provides a wireless signal connection (to enable communication with other devices), and a location signal of the wearer of the current smart glasses 100-2 (also for preventing lost children) It is characterized in that it includes a location signal connection unit 548 for

In addition, when the location cannot be confirmed through the location signal connection unit, a call signal is transmitted to the smartphone of the parent or guardian of the owner or user of the corresponding smartphone glasses 100-2 or a pre-designated person or a text signal in an emergency situation occurs It is characterized in that is transmitted.

According to another aspect of the present invention, as smart glasses used in pediatric vision recovery and presbyopia recovery systems,

Earring parts 11a-1 and 11b-1 and lens frame parts 12a-1 and 12b-1 are provided, and a speaker (with a microphone) part 36-1 and a Bluetooth module part 34-1 are installed. QR code (mark) 32-1 is installed, antenna unit (can be embedded in the intena butte) 31-1, charging means (wireless charging chip, charging chip It can be a lithium ion battery, but is not limited thereto) (33-1), including a GPS means (37-1) (for location tracking),

Insertion connectors 40a-1 and 40b-1 are provided in the spectacle frame front mounting portion 12 or 13, and earring portions 11a-1 and 11b-1 are provided in the insertion connectors 40a-1 and 40b-1. There are provided smart glasses, characterized in that the inserted installation by changing the.

In addition, the insertion connection portions 40a-1 and 40b-1 have holding portions 42a and 42b coupled to the front mounting portion of the spectacle frame on one side and coupled to the earring portions 11a-1 and 11b-1 on the other side. Equipped with inner seating parts 44a and 44b to become,

The antenna 31-1 is provided at the upper end,

The shape of the inner seating parts 44a and 44b is a state in which one or more curved parts are formed on the inside so as to engage and engage with the earring parts 11a-1 and 11b-1,

The insert connection portions 40a-1 and 40b-1 wrap around the protrusions 12b or 13b protruding from the front mounting portion 12 or 13 of the spectacle frame through the holding portions 42a and 42b, respectively, and are coupled to each other through screws. characterized by

In addition, the earring parts 11a-1 and 11b-1 are coupled to the inner seating parts 44a and 44b of the insertion connection parts 40a-1 and 40b-1, and the insertion part is the primary insertion part 111 and A secondary insertion portion 112 having elasticity is provided, and an end of the secondary insertion portion 112 is formed of an elastic body and is provided with a side-extending protrusion 112a,

The method in which the earring parts 11a-1 and 11b-1 are coupled with the insertion connection parts 40a-1 and 40b-1 is the secondary insertion part 112 of the earring parts 11a-1 and 11b-1 It is characterized in that the side extension protrusion (112a) of the insertion connection (40a-1, 40b-1) is in contact with the curved portion of the pushed while reaching the last curved portion to be seated.

According to the pediatric vision recovery and presbyopia recovery system and method through smart glasses, smartphones and smart watches according to the present invention having the above configuration, vision recovery is performed according to the vision recovery program in a state where smart devices are connected to each other without being limited to a place It is possible to recover vision by exercising, so that it has the effect of recovering more improved vision than the initially measured eyesight.

In addition, according to the present invention, the vision recovery process of a number of individuals who have continuously performed vision recovery exercises in a remote place is recorded and managed, guided to appropriately perform vision recovery exercises, guided to maintain vision, and related to vision recovery. There is an effect that can manage big data so that the entire process can be monitored.

In addition, according to the present invention, since the smart glasses have parts replacement and assembly functions, there is an effect of assembling smart glasses having different colors and shapes by purchasing parts (DIY method DIY).

1 to 3 are diagrams showing an example of smart glasses, FIG. 1 is a view showing smart glasses without lenses, FIG. 2 shows smart glasses in the form of a toy, and FIG. 3 is glasses equipped with lenses for vision correction. is a drawing showing

4 is a schematic system configuration diagram of a pediatric vision recovery and presbyopia recovery system through smart glasses, a smart phone and a smart watch according to the present invention.

Figure 5 shows a specific block configuration diagram of a hospital computer equipped with a vision recovery program of the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG.

6 is a diagram showing an example of an interface screen shown on a hospital computer display device or a smartphone display screen of a pediatric vision recovery and presbyopia recovery system through smart glasses, a smart phone and a smart watch of FIG. 4 .

7 and 8 are flowcharts showing an example of a specific operation of the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG. 4 .

9 is a diagram showing a detailed block configuration of a smart watch in the pediatric vision recovery and presbyopia recovery system through smart glasses, a smart phone, and a smart watch of FIG. 4 .

10 and 11 are views showing examples of specific operations in the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG. 4 .

12 is a view showing a lensless type smart glasses according to another example of the present invention.

FIG. 13 is a diagram showing a configuration of an electronic type installed inside the lensless smart glasses 100-2 of FIG. 12 .

14 is a flowchart showing an example of an operation process of a vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

Figure 15 is a perspective view showing another example of smart glasses used in the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG.

16 is an exploded perspective view of FIG. 15;

FIG. 17 is a partially enlarged exploded perspective view of FIG. 15 and a partial cross-sectional view added thereto.

18 is a diagram showing an example of a user display screen in the eyesight recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

19 is a view showing an example of a user result display screen in the eyesight recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

20 is an explanatory view schematically explaining the principle of the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

21 is an explanatory diagram analyzing the final effect in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

22 is a view showing the contents of syllables displayed in the eyesight recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

23 is a table showing differential effects in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

24 is a screen schematically illustrating types of robot language in the eyesight recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

25 is a view showing an example of a display screen schematically showing the robot transformation contents and ripple effects in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention.

According to a preferred embodiment of the present invention for achieving the above object,

In the pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches,

personal terminal (1-1,...,1-N),

Hospital (or oriental medicine hospital included) computer (2-1,...,2-N), and

The operator computer server 3 is connected to each other through a wired or wireless communication network,

Smart glasses (or vision correction glasses or Glasses without lenses) and the smart watch (430 or 530) can communicate with each other via Bluetooth,

The hospital computers 2-1, ..., 2-N have a vision recovery program storage unit 330,

The eyesight recovery program storage unit 330 is provided in the form of an application (APP) and can be downloaded and installed in personal terminals (1-1, ..., 1-N), and can also be downloaded from the operator server (3). and can be installed

While an individual wears smart glasses and the smart glasses, smart phone and smart watch are connected to each other via Bluetooth, the vision recovery program is activated through the smartphone (or smart watch) on which the vision recovery program is downloaded to perform an individual vision recovery exercise. Provided is a pediatric vision recovery and presbyopia recovery system through smart glasses, smart phones and smart watches that allow vision recovery by performing a predetermined number of times for a predetermined time according to the guidance of the voice and display screen of the vision recovery program.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail.

However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "comprise" or "having" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

1 to 3 are diagrams showing an example of smart glasses, FIG. 1 is a view showing smart glasses without lenses, FIG. 2 shows smart glasses in the form of a toy, and FIG. 3 is glasses equipped with lenses for vision correction. Figure 4 is a schematic system configuration diagram of a pediatric vision recovery and presbyopia recovery system through smart glasses, a smartphone and a smart watch according to the present invention, and Figure 5 is a smart glasses, smartphone and smart watch of FIG. It shows a specific block configuration diagram of a hospital computer equipped with a vision recovery program of a pediatric vision recovery and presbyopia recovery system through a watch, and FIG. 6 is a pediatric vision recovery and presbyopia recovery through smart glasses, a smartphone and a smart watch in FIG. It is a diagram showing an example of an interface screen shown on a hospital computer display device or a smartphone display screen of the system, and FIGS. It is a flow chart showing an example of a specific operation, and FIG. 9 is a diagram showing a detailed block configuration of a smart watch in the pediatric vision recovery and presbyopia recovery system through smart glasses, a smartphone, and a smart watch in FIG. 4, FIGS. 10 and 11 is a diagram showing an example of a specific operation in the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG.

Looking at the five characteristics of the present invention,

First, it is possible to network with the computer network of oriental medical clinics nationwide (including but not limited to, hospitals and other hospital facilities),

Second, it is linked through a smart phone, a smart watch, and a Bluetooth device,

Third, a vision recovery program can be performed in conjunction with a smart phone and a Bluetooth device,

Fourth, through the present invention, it is possible to remove the glasses of children around the world, restore the eyesight of glasses wearers, including children and adolescents, and alleviate or treat symptoms of dementia, including pediatric glaucoma and adult glaucoma, to a large extent. will be).

Fifth, presbyopia magnifying glasses worn by elderly people or presbyopic people around the world can be removed.

1 is a general type of lensless smart glasses 100-1, in which there are no lenses in the earring parts 11a and 11b and the lens rim parts 12a and 12b, and a speaker (with a microphone) part and a Bluetooth module part. (34) is installed, and QR code (sign) 32 is installed. Reference numeral 21 denotes a space portion without a lens.

2 and 3 are diagrams illustrating an example of smart glasses.

Figure 2 shows an example of glasses as entertainment items that children like. Glasses with a pinhole are presented as an example, but glasses without a pinhole can also be used by installing a Bluetooth module 34, a QR code (a cover) 32, and a speaker (combined microphone).

3 is a smart glasses 100 in a general form, in which a lens 21 having a pinhole 20a is mounted in the earrings 11a and 11b and the lens rims 12a and 12b, and a speaker (combines a microphone) and a Bluetooth module unit 34 are installed, and a QR code (mark) 32 is installed.

Referring to Figure 4, Figure 4 is a schematic system configuration diagram of the pediatric vision recovery and presbyopia recovery system through smart glasses, smart phones and smart watches according to the present invention, personal terminals (1-1, ..., 1 -N), the hospital (or oriental medicine hospital included) computers (2-1, ..., 2-N), and the operator's computer server (3) are connected to each other through a wired or wireless communication network. The individual user has a smart watch (430 or 530) capable of Bluetooth communication with the personal terminal (1-1, ..., 1-N), and also has a QR code and has a bluest function, smart glasses (100, Alternatively, the vision correction glasses or lensless glasses 100-1) and the smart watch 430 or 530 can communicate with each other via Bluetooth.

In addition, the hospital computers 2-1, ..., 2-N transmit personal terminals 1-1, ..., 1-N through a wireless communication device (eg, Bluetooth, but not limited thereto). connected through

The hospital computers 2-1, ..., 2-N have a vision recovery program storage unit 330 to be described later. The eyesight recovery program storage unit 330 is provided in the form of an application (APP) and can be downloaded and installed in personal terminals (1-1, ..., 1-N), and can also be downloaded from the operator server (3). and can be installed.

Referring to FIG. 5, in the hospital computers 2-1, ..., 2-N (or medical facility computers), the vision recovery program storage unit 330 is a communication module (under the control of the control unit 310) 320) to perform wired/wireless communication. The vision recovery program storage unit 330 can be installed in the personal terminals 1-1, ..., 1-N, and at this time is controlled by the control unit of the personal terminals 1-, ..., 10N, It can also be downloaded from the operator computer server 3.

The vision recovery program storage unit 330

A vision recovery DATA collection unit 331 that collects vision recovery data in the course of the vision recovery program;

A vision recovery time management unit 332 that manages the overall time for performing the vision recovery program.

A breathing guidance signal generating unit 333 for guiding breathing during vision recovery program execution;

A motion detection signal generator 334 for detecting body motion and generating a detection signal during the vision recovery program to guide the breathing process and pupil position in the vision recovery process accordingly.

A vision recovery information display unit 335 for displaying vision recovery information after the vision recovery program process;

A result information graph and numerical value transmission unit 336 for transmitting graphs and numerical values of results after the vision recovery program process;

A process input information display and transmission unit 337 for displaying various data information including input drugs or input natural drug information input in the course of the vision recovery program;

It includes a smart watch linkage management unit 338 and a database management unit 340 that control a signal processing process while connected to the smart watch 430 or 530.

The database management unit 340

A member database (341) for storing/managing treatment information related to members, such as member names;

A treatment frequency database (342) for storing/managing the number of treatments (running a vision recovery program) of members;

A vision database 343 for storing/managing member's vision data, and

A graph database 344 displaying information on the results of execution of the vision recovery program in graphs and bar graphs;

It includes a big data database 345 that manages and stores vision recovery program execution result information as big data.

Referring to FIG. 6, an example of a result screen displayed on a monitor screen of a hospital computer (2-1, ..., 2-N) or a personal terminal is shown,

Personal photos and names, the date of execution of the vision recovery program, and result data are displayed.

In addition, the result screen displays the change in visual acuity on the 1st, 2nd, and 3rd days of the vision recovery program.

The vision recovery program may be performed in units of 5 to 10 minutes or 30 minutes per day, and the number of times is not limited and can be set separately. The results after 1 day, 3 days, 1 week, 1 month, 2 months, 6 months or 1 year of the vision recovery program can be recorded and managed, and the results can be output.

For example, in a table divided into 3 major vision prescriptions of oriental medicine and 3 major visual acuity graphs of oriental medicine, a 1-step program, a 2-step program, and a 3-step program may be executed.

In the 3 major vision prescriptions of oriental medicine, in the first stage program item, visual acuity can be measured from 0.02 to 0.1 at 0.01 intervals, after 0.1, from 0.15, 0.2, 0.3 to 1.0 at 0.1 intervals, and then at 1.2, 1.5 steps. can be measured up to Measurements can be divided into initial uncorrected visual acuity (0.15), oriental uncorrected visual acuity (0.3), oriental uncorrected visual acuity (0.5), oriental corrected visual acuity (0.8), or one oriental corrected visual acuity (1.2).

Even in the second-level program item, visual acuity can be measured from 0.02 to 0.1 at 0.01 intervals, after 0.1, from 0.15, 0.2, 0.3 to 1.0 at 0.1 intervals, and then from 1.2 to 1.5. Measurements can be divided into initial uncorrected visual acuity (0.15), oriental uncorrected visual acuity (0.5), oriental uncorrected visual acuity (0.5), oriental corrected visual acuity (0.7), oriental corrected visual acuity (0.8), and oriental corrected visual acuity (1.2).

Even in the three-step program item, visual acuity can be measured from 0.02 to 0.1 at 0.01 intervals, after 0.1, from 0.15, 0.2, 0.3 to 1.0 at 0.1 intervals, and then from 1.2 to 1.5. Measurements can be divided into initial uncorrected visual acuity (0.15), oriental uncorrected visual acuity (0.7), oriental uncorrected visual acuity (0.7), oriental corrected visual acuity (1.0), oriental corrected visual acuity (0.8), and oriental corrected visual acuity (1.2).

Hereinafter, the three major visual acuity graphs of oriental medicine are graphs of the visual acuity displayed in the three major oriental vision prescriptions above. Latent visual acuity and oriental corrected visual acuity are displayed in a graph.

In the diagram above, the contact visual acuity [0.8] where the uncorrected visual acuity and the corrected visual acuity of the traditional Chinese medicine meet can also be expressed as the normal visual acuity of the traditional Chinese medicine.

As a result, as can be seen from the table above, it can be seen that the potential vision (oriental medicine) was restored to (1.0) as the vision recovery program of the present invention was operated and the 1st, 2nd, and 3rd steps were performed. there is. When the above vision recovery program is performed after wearing the lensless glasses (100-1) or vision correction glasses (100), which are components of the present invention, and wearing a smart watch and a smartphone, the measurement result data is 1 Second, it is automatically stored in a smartphone at home (if the measurement location is a hospital, it is stored and managed in the hospital computer), and then managed separately for each individual along with data from other peripheral devices.

In the above table, the term oriental medicine is used for convenience and may be deleted.

On the other hand, at home, for example, in FIG. 4, the diabetes value and blood pressure value measured through the digital diabetes monitor 120, the digital blood pressure monitor 130, and the digital body fat monitor 140 connected to the PC 100-2. And it is managed together in association with body fat level. At this time, the user (or the person to be measured or the patient) will be able to compare the diabetes level, blood pressure level, and body fat level with his/her potential visual acuity measurement value to determine the relationship. Through this, it is possible to manage vision in terms of diabetes vision, blood sugar vision, and body fat vision, and in the case of children, the first measurement record is kept and compared with eyesight measurement data even after becoming an adult to manage eye health as well as other body data. It will also be possible to provide health management services to the elderly, but in particular, provide and manage eye health-related data with high relevance to other body-related data. For example, in terms of diabetic vision and artificial dialysis vision, physical health through lensless smart glasses according to the present invention is managed through eye health data, in particular, to prevent diabetic feet and artificial dialysis that may occur in the elderly in advance. is possible and preventable.

In addition, in the hospital, it is interlocked with the data measured through the refractor 370, the intraocular pressure device 350, and the vision diagnosis device 360 before and after the operation of the user's (or measurement subject's or patient's) vision recovery program according to the present invention. It is possible to manage in conjunction with the measurement data of FIG. 3, which is the performance data of the vision recovery program, and preventive and prescription management is possible.

On the other hand, any user can perform the vision recovery program as described above, and the user can change the vision to 1.0 by modifying his or her name (Hong Gil-dong) to suit the potential vision. In other words, leave the last name as it is, and call out the latent vision as one point zero. For example, shout "Hong Gil-dong! My eyesight is 1.0 (one point zero) hahaha!". This process is optional. It is possible. In addition, the eye breathing therapy is performed as shown in Figs. 10 and 11. A step-by-step explanation of the process will be continued later. Then, the result screen (smartphone or PC terminal display monitor screen) is displayed [Name: Hong Gil-dong (9 years old), initial uncorrected visual acuity (right: 0.3/left 0.6), first corrected visual acuity (right 0.7/left 0.9), first diopter (refractive index) (right: 1.25/left -1.50) , (oriental medicine) potential vision (right: 0.9/left 1.0), (oriental medicine) naked eyesight (right: 0.6/left 0.9), prescription date: October 00, 2022] are displayed, and at the same time, the user's appearance and glasses before taking off the glasses The naked user's figure can be displayed side by side for comparison on the left and right sides The eye breathing therapy of Figs.

In the case of a child, while performing the vision recovery program according to the present invention, the initial corrected visual acuity, the initial uncorrected vision, the oriental medicine potential vision, and the oriental medicine unconventional vision can be measured, and through this, the lifetime oriental medicine potential vision and the lifetime oriental medicine unconventional vision can be measured and maintained. You will be able to. Through this, it is possible to manage the eyes and prevent diseases related to the eyes.

Referring to FIG. 7 , the user starts a vision recovery program in the pediatric vision recovery and presbyopia recovery system through smart glasses, a smart phone and a smart watch according to the present invention.

The user may download, install, and use the vision recovery program, or may use it in a hospital. In each case, a member log-in process is performed (S2). If the user is not a member, a member registration process (S3) is performed. In this process, the name of the individual who wants to use the vision recovery program and other information are entered.

Thereafter, smart glasses (optional), smart watch, and personal terminal (also referred to as a smart phone) may be connected via Bluetooth, and a necessary vision recovery program or app 330 may be operated.

After the login process (S2), after checking the connection status of the smart glasses, smart watch and smart phone, if connected, the vision recovery program can be operated on the smart phone or smart watch (this process is performed later in step S8 may be).

It is assumed that the user has previously performed potential vision measurement, uncorrected vision measurement, and corrected vision measurement process through the optometry device (not limited thereto), and selects to start a vision recovery exercise.

When the user inputs the signal to start the vision recovery exercise (S6), after checking the connection status of the smart glasses, smart watch, and smartphone (S8), if connected, guides the vision recovery exercise through the vision recovery program. The message is output as a voice and the displayed message is transmitted (S10).

Then, it is determined whether the vision recovery exercise has started (S12), and the vision recovery exercise program is started.

A step 1 voice message output process is performed (S14). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, a step 2 voice message output process is performed (S16). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, a step 3 voice message output process is performed (S18). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, a step 4 voice message output process is performed (S20). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, a step 5 voice message output process is performed (S22). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, a step 6 voice message output process is performed (S24). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, a step 7 voice message output process is performed (S26). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, after a predetermined time has elapsed, the step 8 voice message output process is performed (S28). At this time, the position of the pupil and breathing method (closed eyes and open eyes) are guided.

Thereafter, it is determined whether a vision recovery exercise end signal is input (S30), and if the eyesight recovery exercise end signal is input by the user, the number and time of the exercise related to the vision recovery exercise performed up to that time are recorded and stored, and then stored. The data is transmitted to the operator's computer server or hospital computer server (S32).

In the vision recovery program, the position of the pupil changes from step 1 to step 8, respectively, to guide the process of respiration, and the number of steps is not limited thereto.

In step S6, the user selects past vision inquiry before starting the vision recovery exercise to inquire and view the past vision, that is, the previous vision test chart is displayed, it is determined whether to transmit it to the mobile phone, and the previous eye examination chart is also displayed on the mobile phone. can transmit

At home, the app 330 is downloaded and operated on personal terminals (1-1, ..., 1-N), and then the vision recovery program downloaded to the home is operated, and the personal terminals (1-1, ..., 1-N) and wireless communication connection.

Referring to FIG. 9, the smart watch 430 is

A motion detection sensor 431 mounted on the smart watch 430 to measure movement of the body (eg, arm movement);

A control unit 432 that controls the operation of the smart watch, the operation of the vision recovery program, the body motion sensing process, and the overall;

A storage unit 433 for storing data generated when the smart watch 430 operates;

A communication module 434 for controlling wired/wireless communication between the smart watch 430 and other devices;

A display unit 435 for displaying a measured or sensed body motion, breathing process, or voice signal together with a message when the smart watch 430 operates;

It includes a vision recovery program storage unit 436 and an output unit 437 that perform a vision recovery program process for a patient or individual by wearing the smart watch 430 .

The vision recovery program storage unit 436

A message transmission unit that transmits pre-measured (measured at a place where vision can be measured, such as a hospital or optician) to a parent terminal, nurse terminal, or hospital computer server,

A function button display unit for displaying function buttons providing various functions on the liquid crystal display unit of the smart watch 430;

The vision recovery program measured through the smart watch 430 is divided into steps 1 to 8 (steps are not limited), and an alarm signal (an audio signal may be output in addition to the alarm signal) is different each time it is displayed. An alarm generating unit that controls output through an output unit;

A message display unit that displays the process as the vision recovery process progresses through the smart watch 430 and displays a corresponding message each time the vision recovery process is divided into steps 1 to 8 and displayed;

In the vision recovery program performed through the smart watch 430, it is divided into steps 1 to 8, and each time it is displayed, it is displayed in a different color, and a message indicating the state at each step is displayed, along with a message indicating the position of the eye pupil at a predetermined angle. A window color display unit that displays a message guiding to maintain the window while changing the color of the window through the display of the pupil;

A message transmission unit for transmitting the vision recovery exercise record data performed through the smart watch 430 to a parent terminal, nurse terminal, or hospital computer server, and also transmitting a message corresponding to the vision recovery exercise performance result.

10 and 11 are views showing examples of specific operations in the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG. 4 .

Referring to FIG. 10, the user can initially perform vision recovery exercise as instructed by the vision recovery program. In FIGS. ), 6 o'clock direction (a), and 9 o'clock direction (a), showing the pupils moving, and at this time, it shows the state of breathing as much as possible while opening the mouth and widening the eyes.

Referring to FIG. 11, as a view similar to FIG. 10, the user can initially perform vision recovery exercise as instructed by the vision recovery program, in FIGS. ), 135-degree direction (a), 225-degree direction (a), and 315-degree direction (a).

The user can separately perform the eye exercise in the state shown in FIG. 10 and the eye exercise in the state shown in FIG. 11, or in combination. In addition, the eye breathing motion of FIGS. 10 and 11 can be executed by alternating clockwise and counterclockwise directions. The number of executions can be repeated,

The user can perform eye breathing exercises while sitting in a chair, eye breathing exercises while walking, eye breathing exercises while standing, eye breathing exercises while lying down, and eye breathing exercises when standing up. can do.

The eye breathing exercise process is performed schematically through the following process.

First, wear the glasses (100) or (100-1) glasses according to the present invention, (of course, at this time, it is assumed that the vision recovery exercise program is operated on the smart phone, and the smart watch is also installed with the vision recovery exercise program It works in conjunction with a smartphone and operates in an operating state.

Of course, even without wearing the glasses 100, 100-1, in the present invention, you can start eye breathing exercise after thinking about K-lens (oriental potential vision) in your mind (At this time, the program voices

As a message, a voice message saying "Think K-Lens in your mind" can be output to guide you to prepare for the start of eye breathing exercise. That is, the vision recovery exercise program of the present invention is operated in a state in which only the smart phone and the smart watch are operated without actually wearing the glasses (100 or 100-1).

Then, synchronize eye blinking with breathing.

Then, close your eyes tightly and exhale as deeply as possible.

After that, take a deep breath as much as possible while opening your eyes. This process is as shown in FIGS. 10 and 11 .

After that, sound-seeing eye breathing therapy can be performed. This method is a therapy that improves vision up to the oriental potential vision through sound. If eye breathing therapy is performed with improved vision than the initial vision, the effect of improving eyesight can be seen, and sound viewing eye breathing therapy is used to improve vision. will perform For example, think of my one-shot potential vision as 0.8, much higher than the current 0.3, and have them say out loud, "My name is Kim (surname) Jeompal." This process is carried out through a vision recovery program. A voice message (and a screen) may be provided so that the guide can be followed. By performing this sound-seeing eye breathing therapy independently and integrating the eye position as shown in Figs. 10 and 11, vision can be restored. In performing the above process, it is performed step by step by the vision recovery program, and the directions of the faces and pupils displayed on the screens that vary for each screen, especially Figs. 10 and 11, may be displayed on the user's smartphone screen (voice or continuously output at regular intervals during the time the screen is displayed), it may be displayed on the screen of the smart watch (it may be implemented in a programming method).

12 is a diagram showing another example of smart glasses according to the present invention. The same reference numerals will be used to describe the same parts shown in FIGS. 1 to 3 .

Referring to FIG. 12, as a lensless type of smart glasses 100-2 (referred to as "K-lens smart glasses"). Earring parts 11a and 11b and lens frame parts 12a and 12b are provided, a speaker (with a microphone) part 36 and a Bluetooth module part 34 are installed, and a QR code (cover) 32 is installed. do. In addition, an antenna unit (which may be embedded in the antenna butte) 31, a charging means (a wireless charging chip, the charging chip may be a lithium ion battery, but is not limited thereto) (33) , GPS means 37 (for location tracking).

In addition, insert connection parts 40a and 40b may be particularly provided in the spectacle frame front mounting part 12, and earrings parts 11a and 11b may be inserted and installed in different shapes in the insertion connection parts 40a and 40b.

Referring to FIG. 13, an electronic configuration installed inside the lensless smart glasses 100-2 of FIG. 12 (assuming that it is implemented circuitically on a printed circuit board) is shown. That is, a (glasses) control unit 530 that is connected to a smartphone terminal or operator computer server or hospital computer server through wireless communication to enable operation, a power unit 532 that provides a chargeable function that supplies power to the entire device, and Bluetooth Connected to a Bluetooth connection unit 542 for Bluetooth communication, a speaker connection unit 544 that is connected to a speaker and provides a speaker function (and / or a microphone function may be added) through a connection with a wireless earphone microphone 60 , a wireless signal connector 546 that provides a wireless signal connection including the antenna 31 (to enable communication connection with other devices), and a GSP, and is connected to the current position of the wearer of the smart glasses 100-2. A location signal connector 548 may be provided to provide a signal (also for preventing lost children).

Referring to FIG. 14 , it is assumed that a user wears lensless smart glasses 100-2 and a wireless earphone 60 and operates a vision recovery program through a smart phone terminal. Bluetooth communication is possible between each device (in the concept of master-slave, the smartphone terminal becomes the master, and smart glasses and wireless earphones can be slaves, but it is not limited thereto, and the master may be a hospital computer or PC terminal) is of course possible).

First, the controller of the smartphone terminal serving as the master determines whether the K-lens smart glasses 100-2 and other devices are connected (S42).

Then, in the step S42, if connected, the control unit of the smart phone terminal determines whether the eyesight recovery program has started (S44).

Subsequently, when the vision recovery program starts, the location of the smart glasses user is checked (S46).

After that, if the location cannot be confirmed, a call signal is transmitted to the smartphone of the parent or guardian of the owner or user of the smartphone glasses 100-2, or a pre-designated person, or an emergency text signal is transmitted (S50). .

Then, when the location is confirmed, the location information is transmitted to the smartphone terminal as the master device (S48).

Through this, it is possible to prevent lost children or to know the location confirmation information of the user.

Meanwhile, in the step S44, before the vision recovery program starts, it is determined whether the speaker input has been confirmed (S46). This is for the smooth operation of the vision recovery program, and is a pre-process necessary for the vision recovery process of synthesizing sex and vision and making a sound as part of the process for audio output of corrected vision, which is a feature of the present invention. That is, when the speaker input is confirmed, it is determined that the voice input from the user is assured, and the eyesight recovery program can be smoothly operated. This process will of course be selectively configurable. Presets will also be possible. Regardless of the other steps, it will be possible to check the speaker input separately. As the audio output (S54), the speaker input confirmation process is completed.

15 is a perspective view showing another example of smart glasses used in the pediatric vision recovery and presbyopia recovery system through the smart glasses, smart phone and smart watch of FIG. 4, FIG. 16 is an exploded perspective view of FIG. 15, and FIG. The exploded perspective view of 15 is partially enlarged and shown with some cross-sectional views added.

Referring to FIGS. 15 to 17 , as a whole, the smart glasses 100-3 are detachable and assembleable glasses.

That is, as the lensless type smart glasses 100-3 (also referred to as "K-lens smart glasses"). Earring parts 11a-1 and 11b-1 and lens frame parts 12a-1 and 12b-1 are provided, and a speaker (with a microphone) part 36-1 and a Bluetooth module part 34-1 are installed. and a QR code (marker) 32-1 is installed. In addition, an antenna unit (which may be embedded in the antenna butte) 31-1, a charging means (a wireless concept charging chip, the charging chip may be a lithium ion battery, but is not limited thereto) ( 33-1), and GPS means 37-1 (for location tracking).

In addition, the insertion connection portion 40a-1, 40b-1 may be particularly provided in the front mounting portion 12 or 13 of the spectacle frame, and the earring portions 11a-1, 11b may be provided in the insertion connection portion 40a-1, 40b-1. -1) can be inserted and installed by changing the shape.

One side of the insertion connection portion 40a-1, 40b-1 has a holding portion 42a, 42b coupled to the front mounting portion of the spectacle frame, and the other side is for coupling with the earring portion 11a-1, 11b-1. Inner mounting portions 44a and 44b are provided. The antenna 31-1 is provided at the upper end. The shape of the inner seating parts 44a and 44b is a state in which one or more curved parts are formed on the inside so as to engage and engage with the earring parts 11a-1 and 11b-1.

The insertion connection portions 40a-1 and 40b-1 surround the protrusions 12b or 13b protruding from the front mounting portion 12 or 13 of the spectacle frame through the holding portions 42a and 42b, respectively, and are coupled to each other through screws. . Users will be able to assemble this process by themselves.

The earring parts 11a-1 and 11b-1 are combined with the inner seating parts 44a and 44b of the insert connection parts 40a-1 and 40b-1 (the left and right sides have been described at the same time). An insertion part 111 and a secondary insertion part 112 having elasticity are provided, and an end of the secondary insertion part 112 is formed of an elastic body and is provided with a side extension protrusion 112a.

The way in which the earring parts 11a-1 and 11b-1 are combined with the insertion connection parts 40a-1 and 40b-1 is, referring to FIG. 17, the second part of the earring parts 11a-1 and 11b-1 It is a method in which the side extension protrusion 112a of the car insertion portion 112 is pushed while contacting the curved portion of the insert connection portion 40a-1, 40b-1 to reach the last curved portion and be seated. It may be provided in various ways. Users will be able to assemble this process themselves.

It is assumed that internal electronic components in the prefabricated smart glasses are electrically connected to the (glasses) control unit, such as an antenna, a GPS, a charging means, and the like.

18 is a view showing an example of a user display screen in the eyesight recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention, and FIG. It is a view showing an example of a user result display screen in the vision recovery program after wearing the smart glasses 100-2 and the wireless earphone 60, and FIG. 20 is a lensless smart glasses 100-2 according to the present invention and It is an explanatory diagram schematically explaining the principle in the vision recovery program after wearing the wireless earphone 60, and FIG. 21 is a view after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention. It is an explanatory diagram analyzing the final effect in the recovery program, and FIG. 22 is a view showing the syllable display contents in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention. 23 is a table showing the contents of the differential effect in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention, and FIG. A screen schematically explaining the types of robot language in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60, and FIG. 25 is the lensless smart glasses 100-2 according to the present invention. ) and a view showing an example of a display screen schematically showing the robot transformation contents and ripple effects in the eyesight recovery program after wearing the wireless earphone 60.

Referring to FIG. 18, this is a diagram showing an example of a user display screen in a vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention. For example, I " K-Lens can take off glasses" is displayed, and K-Lens therapy is displayed on the right side (refer to the description of FIG. 7).

The user can exercise the eye movement in a clockwise or counterclockwise direction. It can be seen that steps 1 to 8 are displayed on the screen, and the shape of the pupil at that time is displayed as a picture. Although it is indicated as oriental artificial vision, it is not limited thereto, and is specifically indicated as potential vision, unaided vision, and corrected vision, and the final goal is to improve eyesight with corrected eyesight.

Referring to FIG. 19, it is a view showing an example of a user result display screen in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention, wearing glasses on the left side. The image of the user (Kim Ji-hye), and on the right is the user who took off his glasses (Kim Il-gong, here Il-gong has also changed his name with the goal of improving his eyesight to 1.0, so that the user can do eye exercises according to the vision recovery program while making a sound. action) is displayed.

Initial visual acuity [right eye: 0.3, left eye: 0.6] (acuity measured through an optometry) is displayed, K-lens energy is emitted (assumed to be energy emitted while performing a vision recovery program), [1.2 or higher ] Energy is released so that the eyesight is restored, and the improved eyesight is trained to become [Right Eye: 0.8, Left Eye: 1.0].

The initial diopter [right eye: -1.25, left eye: -1.50] is the visual acuity measured through the diopter device, and the improved diopter [right eye: -1.25, left eye: -1.00] shows the improved condition.

The content displayed at the bottom is named [2nd stage robot language (sound viewing therapy)], "I am 1.2. Hahaha!" According to the vision recovery program, sounds are emitted and eye exercises are performed at the same time.

Referring to FIG. 20, it is an explanatory diagram schematically explaining the principle in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention, K-lens artificial knowledge (AK ) The principle of the robot vision recovery program is

You will be able to manage your eyesight from elementary, middle and high school to adulthood [now] with the same principle. In other words, if the visual acuity of the naked eye was 1.2 in elementary, middle and high school, and the visual acuity deteriorated (in progress) to 0.2 of the adult (current) visual acuity, R-diopter therapy (based on visual acuity measured with a diopter machine, vision recovery program) Progress), K-lens therapy (with vision recovery program), and R-lens therapy (with vision recovery program), the uncorrected visual acuity of one eye is corrected from 0.3 to 0.8, and the potential visual acuity of one oriental medicine is corrected from 0.5 to 0.8. Visual acuity improves from 0.8 to 1.0, resulting in improved corrected visual acuity to 1.5.

Referring to Figure 21, as an explanatory diagram analyzing the final effect in the vision recovery program after wearing the lensless smart glasses (100-2) and the wireless earphone (60) according to the present invention, elementary school 1 year / 6 years old The results of three children (two months of treatment: that is, undergoing the vision recovery program of the present invention) are shown in a table.

The initial uncorrected vision [right eye: 0.7, left eye: 0.7], left eye amblyopia and left eye hyperopia were severe (right eye: 0.3, left eye: 0.3), and K-lens therapy was performed (eye exercise, sound therapy, vision recovery program). ,

It was improved with oriental vision [right eye: 1.0, left eye: 1.0],

As the first diopter [right eye: +0.25, left eye: +2.75], (right eye: +0.25, left eye: -0.75), R-diopter therapy was performed (i.e., eye exercise, sound therapy, vision recovery program),

It was improved with a one-way diopter [right eye: +0.50, left eye: +2.00]. As a result, a surprising R-diopter occurred, and the left eye farsightedness was greatly reduced. Through the K-lens therapy and R-diopter therapy, K-lens energy was created (resulting in visual acuity improvement effect), and amblyopia in the left eye was treated without drugs.

As the initial corrected visual acuity [right eye: 0.7, left eye: 0.7], a prescription to take off glasses at the time of the first visit, R-lens therapy was performed (i.e., eye exercise, sound therapy, vision recovery program), oriental corrected visual acuity [right eye: 0.7 , left eye: 0.7]. In other words, R-lens therapy corresponds to brain science therapy.

Referring to FIG. 22, this is a view showing the syllable display contents in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention, and the K-lens is 0.1 to 0.1 units Each syllable is divided up to 1.5, and the meaning of one syllable can be pronounced from dot-il, dot, dot-sam, to 15, and as one syllable, standard language (English pronunciation notation) is JUM-IL, JUM-LEE, JUM-SAM~ Marked as IL-0.

Referring to FIG. 23, it is a table showing the contents of the differential effect in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention in a table. Classification and differential effect contents If are displayed respectively, normal myopia enables the use of K-lens robot language for left and right high potential vision, and high myopia enables use of K-lens robot language for left and right high potential vision, but treatment (or training) rather than normal myopia ) requires more time,

Strabismus and astigmatism make it possible to speak K-lens robot language with high potential vision on both sides, but also to make K-lens eye breathing therapy stronger and longer,

Hyperopia should be able to speak K-lens robot language with high left and right potential vision, but in the case of farsightedness with diopter, treatment (or training) is performed by making the K-lens with a high +diopter absolute number.

It is possible to speak the language of K-lens robot with potential vision for paired eyes, but trains to improve binocular vision and diopter together.

Referring to FIG. 24, looking at the classification and the type of K-lens (AK) robot language, the main character (child) is the K-lens (AK) robot language (1) with the mother [questioner: mother / answerer: child] , The main character [mother] is K-lens (AK) robot language with children (2) [questioner: mother / answerer: mother], the protagonist [adult] is K-lens (AK) robot language for adults [3] It is divided into [Questioner: K-Lens (AK) robot / Answerer: The person].

Referring to FIG. 25, an example of a display screen schematically showing the robot transformation contents and ripple effects in the vision recovery program after wearing the lensless smart glasses 100-2 and the wireless earphone 60 according to the present invention is shown. As a drawing, if you explain the K-lens robot transformation contents and ripple effects by dividing them,

The image transforming robot [1] transforms the child's face so cool that the child himself is surprised [creating the largest K-lens energy (especially female children) brain stimulation effect],

The glasses-free transforming robot [2] does exhilarating exercise (eye exercise) because children do not have glasses on their faces [brain stimulation effect generating K-energy that is abominable for children who enjoy exercising],

The name transformation robot [3] transforms children's names in stages in a fun way (can be provided as a voice program), [brain stimulation effect possible through the provision of K-lens robot growth characters],

Lifetime Confidence in Sight Transformation Robot [4] gives children confidence in their vision for life by taking off their glasses [possible lifelong vision management and brain stimulation effect through provision of a character taking off glasses (which can be provided to the user's smartphone programmatically)] ,

K-lens energy emitting robot [5] emits K-lens energy from children's eyes [brain stimulation effect to improve eyesight],

The transforming robot [6] with low lens power provides [optical nerve brain stimulation relief effect] in the case of high myopia in children's eyesight.

The term robot is a virtual concept, and when using the vision recovery program of the present invention, the vision recovery program is performed according to the voice heard through the earphone connected to the smartphone while wearing glasses, sound therapy from 1 to 8 steps (eg, I am Kim Il-il) If you continue to train for a certain period of time while simultaneously using the ball), you will get the same effect as above.

According to the pediatric vision recovery and presbyopia recovery system and method through smart glasses, smartphones and smart watches according to the present invention, vision recovery exercises are performed along the vision recovery program in a state where smart devices are connected to each other without being limited to places. By enabling recovery, it is possible to restore a more improved visual acuity than the initially measured visual acuity.

In addition, according to the present invention, the vision recovery process of a number of individuals who have continuously performed vision recovery exercises in a remote place is recorded and managed, guided to appropriately perform vision recovery exercises, guided to maintain vision, and related to vision recovery. It is possible to manage big data so that the entire process can be monitored.

In addition, according to the present invention, since the smart glasses have parts replacement and assembly functions, it is possible to assemble smart glasses having different colors and shapes by purchasing parts.

As described above, the optimal embodiment has been disclosed in the drawings and specifications. Although specific terms are used herein, they are only used for the purpose of describing the present invention and are not used to limit the scope of the present invention described in the claims or defining the meaning. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

Claims (17)

1. In the pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches,

   personal terminal (1-1,...,1-N),

   Hospital (or oriental medicine hospital included) computer (2-1,...,2-N), and

   The operator computer server 3 is connected to each other through a wired or wireless communication network,

   Smart glasses (or vision correction glasses or Glasses without lenses) and the smart watch (430 or 530) can communicate with each other via Bluetooth,

   The hospital computers 2-1, ..., 2-N have a vision recovery program storage unit 330,

   The eyesight recovery program storage unit 330 is provided in the form of an application (APP) and can be downloaded and installed in personal terminals (1-1, ..., 1-N), and can also be downloaded from the operator server (3). and can be installed

   While an individual wears smart glasses and the smart glasses, smart phone and smart watch are connected to each other via Bluetooth, the vision recovery program is activated through the smartphone (or smart watch) on which the vision recovery program is downloaded to perform an individual vision recovery exercise. A pediatric vision recovery and presbyopia recovery system through smart glasses, smart phones and smart watches that allow vision recovery by performing a predetermined number of times for a predetermined time according to the guidance of the voice and display screen of the vision recovery program.
2. According to claim 1,

   The vision recovery program storage unit 330

   A vision recovery DATA collection unit 331 that collects vision recovery data in the course of the vision recovery program;

   A vision recovery time management unit 332 that manages the overall time for performing the vision recovery program.

   A breathing guidance signal generating unit 333 for guiding breathing during the vision recovery program;

   A motion detection signal generator 334 for detecting body motion and generating a detection signal during the vision recovery program to guide the breathing process and pupil position in the vision recovery process accordingly.

   A vision recovery information display unit 335 for displaying vision recovery information after the vision recovery program process;

   A result information graph and numerical value transmission unit 336 for transmitting graphs and numerical values of results after the vision recovery program process;

   A process input information display and transmission unit 337 for displaying various data information including input drugs or input natural drug information input in the course of the vision recovery program;

   Including a smart watch linkage management unit 338 and a database management unit 340 that control the signal processing process while connected to the smart watch 430 or 530,

   The database management unit 340

   A member database (341) for storing/managing treatment information related to members, such as member names;

   A treatment frequency database (342) for storing/managing the number of treatments (running a vision recovery program) of members;

   A vision database (343) for storing/managing member's vision data;

   A graph database 344 displaying information on the results of execution of the vision recovery program in graphs and bar graphs, and

   Pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches, characterized in that it includes a big data database (345) for managing and storing vision recovery program performance result information as big data.
3. According to claim 1,

   Before starting the vision recovery exercise, the user can view the previous eye test chart by selecting the past vision query to query the past vision, and through smart glasses, smartphones and smart watches, which can transmit the previous eye test chart to the mobile phone. Pediatric vision recovery and presbyopia recovery system.
4. The method of claim 1, wherein a vision recovery program is stored and connected to a PC (100-2) installed at home to measure diabetes, a digital blood pressure monitor (120), a digital blood pressure monitor (130) to measure blood pressure, and a blood pressure monitor (130) to measure body fat. Pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches, characterized in that they are managed together in association with diabetes levels, blood pressure levels and body fat levels measured through the digital body fat meter (140).
5. According to claim 1, connected to the hospital computer, the refractor 370 for measuring the pupil (pupil) refractive index (diopter) before and after the operation of the user's (or measurement subject's or patient's) vision recovery program, and for measuring intraocular pressure A tonometer 350 and a visual acuity diagnostic device 360 for measuring visual acuity are further provided, and are interlocked with each measured data to enable management to be compared with measurement data, which is performance data of a vision recovery program, for prevention and prescription. Pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches, characterized in that they can be managed.
6. In the pediatric vision recovery and presbyopia recovery method through smart glasses, smartphones and smart watches,

   It is assumed that the user has previously performed potential vision measurement, uncorrected vision measurement, and corrected vision measurement process through the optometry device (not limited thereto), and selecting to start a vision recovery exercise.

   Determining whether a vision recovery exercise signal is input;

   When a signal to start the vision recovery exercise is input by the user, after checking the connection status of the smart glasses, smart watch, and smartphone, and if connected, a message that outputs and displays a vision recovery exercise guide message through the vision recovery program. sending a

   Step of determining whether the vision recovery exercise has started,

   After that, if the vision recovery exercise is started, the vision recovery exercise program is started,

   The step of performing a step 1 voice message output process and guiding the pupil position and breathing method (eye closing and opening eyes);

   Then, after a predetermined time has elapsed, a two-step voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

   Thereafter, after a predetermined time has elapsed, a three-step voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

   Thereafter, after a predetermined time has elapsed, a 4-step voice message output process is performed, and the pupil position and breathing method (closed and opened eyes) are guided;

   Thereafter, it is determined whether a vision recovery exercise end signal is input, and if the eyesight recovery exercise end signal is input by the user, the number and time of the exercise related to the vision recovery exercise performed up to that time are recorded and stored, and then the stored data is stored. Pediatric vision recovery and presbyopia recovery method through smart glasses, smart phones and smart watches, including the step of transmitting to an operator's computer server or hospital computer server.
7. According to claim 6,

   A step of performing a step 5 voice message output process after a predetermined time elapses after the step 4, and guiding the position of the pupil and the breathing method (closing and opening the eyes);

   Thereafter, after a predetermined time has elapsed, a step 6 voice message output process is performed, and the pupil position and breathing method (eye closing and eye opening) are guided;

   Then, after a predetermined time has elapsed, a 7-step voice message output process is performed, and the pupil position and breathing method (closed and opened eyes) are guided, and

   Thereafter, after a predetermined time has elapsed, an 8-step voice message output process is performed, and a step of guiding the pupil position and breathing method (eye closing and eye opening) is additionally performed. Smart glasses, smartphones and smart watches, characterized in that A method for restoring vision and presbyopia in children through
8. According to claim 6,

   In the vision recovery program, in steps 1 to 4, the position of the pupil moves clockwise from the first 12 o'clock to 3 o'clock, 6 o'clock, and 9 o'clock directions, and an operation to return to the original is performed, and then counterclockwise from 12 o'clock , 9 o'clock, 6 o'clock, and 3 o'clock directions, and a return operation is performed, and the position of the pupils is changed in each direction to guide the process of breathing by opening the eyes wide and opening the mouth wide. Pediatric vision recovery and presbyopia recovery method through smart glasses, smart phones and smart watches.
9. According to claim 7,

   In steps 5 to 8 in the vision recovery program, the position of the pupil starts at an initial angle of 45 degrees in a clockwise direction, moves in directions of 90 degrees, 135 degrees, and 235 degrees, and returns to the original state. To guide the process of breathing by opening the eyes wide and opening the mouth wide by changing the position of the pupils in each direction Pediatric vision recovery and presbyopia recovery method through smart glasses, smartphones and smart watches, characterized in that.
10. According to claim 6,

    The process of steps 1 to 4 in the vision recovery program is an eye breathing exercise process,

    A step of guiding to prepare for the start of the eye breathing exercise by outputting a voice message saying "Think of K-lens in your mind" as a message;

    Then, the step of synchronizing eye blinking and breathing,

    Thereafter, exhaling as much as possible while closing the eyes firmly, and

    Thereafter, the step of breathing as wide as possible while opening the eyes, a pediatric vision recovery and presbyopia recovery method through smart glasses, smartphones and smart watches, comprising:
11. According to claim 10,

    Perform sound-seeing eye breathing therapy in parallel,

    Think of the potential vision of my eyes as 0.8, which is much higher than the current 0.3 vision, and say 'My name is Kim (last name) Jeompal' out loud through smart glasses, smartphones and smart watches. Methods for restoring eyesight and presbyopia in children.
12. According to claim 1,

    The smart glasses are provided with earring parts 11a and 11b and lens rim parts 12a and 12b, a speaker (with a microphone) part 36 and a Bluetooth module part 34 are installed, and a QR code (cover) ( 32) is installed, and the antenna unit (which can be embedded in the antenna butte) 31, the charging means 33, the GPS means 37, characterized in that it includes smart glasses, smartphones, and Pediatric vision recovery and presbyopia recovery system through smart watch.
13. According to claim 1,

    The smart glasses include a glasses control unit 530 that is connected to a smartphone terminal or operator computer server or hospital computer server through wireless communication to enable operation, a power supply unit 532 that provides a chargeable function to supply power to the entire device, and Bluetooth. A Bluetooth connection unit 542 for communication, a speaker connection unit 544 that provides a speaker function (and/or a microphone function may be added) through connection with the wireless earphone microphone 60, and a wireless antenna 31. A wireless signal connection unit 546 that provides signal connection (enables communication connection with other devices), and a location signal of the wearer of the current smart glasses 100-2 (also for preventing lost children) Pediatric vision recovery and presbyopia recovery system through smart glasses, smart phones and smart watches, characterized in that it includes a location signal connection unit 548.
14. According to claim 13,

    If the location cannot be confirmed through the location signal connection unit, a call signal is transmitted to the smartphone of the parent or guardian of the owner or user of the corresponding smartphone glasses (100-2) or a pre-designated person, or an emergency text signal is transmitted. Pediatric vision recovery and presbyopia recovery system through smart glasses, smartphones and smart watches, characterized in that being.
15. As smart glasses used for pediatric vision recovery and presbyopia recovery system,

    Earring parts 11a-1 and 11b-1 and lens frame parts 12a-1 and 12b-1 are provided, and a speaker (with a microphone) part 36-1 and a Bluetooth module part 34-1 are installed. QR code (mark) 32-1 is installed, antenna unit (can be embedded in the intena butte) 31-1, charging means (wireless charging chip, charging chip It can be a lithium ion battery, but is not limited thereto) (33-1), including a GPS means (37-1) (for location tracking),

    Insertion connectors 40a-1 and 40b-1 are provided in the spectacle frame front mounting portion 12 or 13, and earring portions 11a-1 and 11b-1 are provided in the insertion connectors 40a-1 and 40b-1. Smart glasses, characterized in that the inserted installation by changing the.
16. [Claim 16] The method of claim 15, wherein one side of the insertion connection portion (40a-1, 40b-1) has a holding portion (42a, 42b) coupled to the front portion of the spectacle frame, and the other side is provided with an earring portion (11a-1, 11b-1). 1) is provided with inner seating parts 44a and 44b to be coupled with;

    The antenna 31-1 is provided at the upper end,

    The shape of the inner seating parts 44a and 44b is a state in which one or more curved parts are formed on the inside so as to engage and engage with the earring parts 11a-1 and 11b-1,

    The insert connection portions 40a-1 and 40b-1 wrap around the protrusions 12b or 13b protruding from the front mounting portion 12 or 13 of the spectacle frame through the holding portions 42a and 42b, respectively, and are coupled to each other through screws. Smart glasses characterized in that.
17. 17. The method of claim 16.

    The earring parts 11a-1 and 11b-1 are coupled to the inner seating parts 44a and 44b of the insertion connection parts 40a-1 and 40b-1, and the insertion part provides elasticity to the primary insertion part 111. A secondary insertion portion 112 is provided, and an end of the secondary insertion portion 112 is formed of an elastic body and is provided with a side-extending protrusion 112a,

    The method in which the earring parts 11a-1 and 11b-1 are coupled with the insertion connection parts 40a-1 and 40b-1 is the secondary insertion part 112 of the earring parts 11a-1 and 11b-1 Smart glasses, characterized in that the side extension protrusion (112a) of the insertion connection portion (40a-1, 40b-1) is pushed while in contact with the curved portion to reach the last curved portion and be seated.

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