KR20200074683A - Smart healthcare system and method for decomposing body fat based on metabolism monitoring - Google Patents

Abstract

The present invention provides a body fat decomposition apparatus based on metabolism monitoring, a wearing apparatus for decomposition of body fat, and a method thereof. The body fat decomposition apparatus detects metabolism such as thickness of subcutaneous fat, body composition and fat cell size for each body part where visceral fat and abdominal subcutaneous fat are positioned by metabolism measurement, and irradiates each body part according to the thickness of the subcutaneous fat and a change rate of the metabolism by changing the lights for decomposing the body fat with different intensities and wavelengths to selectively and efficiently decompose the visceral fat and the abdominal subcutaneous fat, thereby remarkably enhancing efficiency in reducing the fat.

Description

SMART HEALTHCARE SYSTEM AND METHOD FOR DECOMPOSING BODY FAT BASED ON METABOLISM MONITORING}

The present invention relates to a technique and monitoring for body fat reduction using light that decomposes body fat, and more specifically, it measures the thickness and metabolism of the abdominal subcutaneous fat using light in the NIR-VIS (Near Infrared-Visible) band. Then, the body fat is decomposed by irradiating light for body fat decomposition of different wavelengths and intensities according to the subcutaneous fat thickness and metabolism, and the body fat is decomposed while the fat thickness and metabolism are measured again to calculate the change. It relates to a smart health care system and method for metabolism-based body metabolism monitoring that efficiently removes fat and abdomen by selecting it.

In addition, the present invention analyzes an individual's health state based on big data by transmitting the measured metabolic data to a cloud server through a mobile app, and sets the treatment laser wavelength, power, and irradiation time of the wearable device according to the analysis result It is a metabolic monitoring-based smart health care system and method for body fat decomposition that provides a variety of personalized information such as exercise, target amount, and healthy diet suitable for the current state of the database.

In addition, the present invention is a technology that combines a smart healthcare platform and blockchain technology to set a number of common goals grouped together, so that everyone can achieve various goals, such as a given product, through data mining Providing a method to promote the motivation with the enjoyment of health care by ultimately aging by providing a benefit as many people work together to achieve the target values for health management such as diet and by completing common goals The present invention relates to a smart healthcare system and method for metabolism-based body metabolism monitoring that can reduce the social cost required for management of chronic diseases that increase with the entry into society.

Obesity is an important factor that increases the risk of developing high blood pressure, brain hemorrhage, heart disease, dyspnea, and cancer. With the industrialization, the obesity population is increasing worldwide. Accordingly, many people are performing various exercises for the prevention or treatment of obesity, but when it is not possible to spend exercise time, efforts to decompose body fat by taking supplementary foods or wearing supplementary devices are being conducted in parallel.

As an example of an auxiliary mechanism for removing body fat, exercise is performed by promoting the decomposition of body fat decomposed by the light source by applying vibration while irradiating a body part with a light source that decomposes the body fat of Korea Patent No. 10-1744195. Disclosed is a wearable device for removing body fat that allows body fat to be removed simply by wearing without performing.

However, in the case of the above-described prior art, it is a structure in which two light sources having different wavelengths are disposed and used to measure the body fat of a user, but the operation of the device is adjusted or the intensity of light is adjusted by reflecting the measured body fat information. Since there is no function such as, in the case of a user with thick subcutaneous fat, light has a problem of not reaching deep subcutaneous fat or visceral fat. In addition, it is impossible to adjust even if it is necessary to manage visceral fat rather than subcutaneous fat.

According to a recent study, it has been reported that uncontrolled light intensity may cause problems such as increasing metabolism of the human body, thereby reducing visceral fat, but increasing in the case of lower abdominal fat.

That is, the wavelength of the light source mainly used for low-level laser therapy (LLLT) is 635nm and 830nm, which irradiates low-power light to bring about circulation effects, metabolism enhancement, and vasodilation through thermal effect. The pain or wound treatment is performed, and at this time, the thickness of the abdominal subcutaneous fat increases through activation of collagen in the subcutaneous fat.

In addition, with the entry of an aging society, as social costs are increasing for the management and treatment of various chronic diseases, and as interest in reducing them increases, various mobile healthcare devices (eg. Apple Watch, Samsung Gear, Fitbut, Nike Fuel, etc.) ) Is being released. Contrary to expectations, however, complaints were made that commercially available mimetic healthcare devices simply monitor the wearer's activity against the price (activity trackint), and do not provide medical-level health information, which is impossible for an expensive pedometer. It is becoming. Therefore, in the age of aging, there is a need for a new type of healthcare device capable of practically personalized health care by improving the quality of life and providing medical-level health information. There is an unmet need for a new form of health care platform that can motivate individuals with enjoyment and constant motivation to manage lasting health.

Republic of Korea Registered Patent No. 10-1744195

The present invention is to solve the above-mentioned problems of the prior art, using multi-distance diffused light spectroscopy to measure the subcutaneous fat thickness and metabolism for each body part, and a light source for decomposing body fat according to the reduction target of subcutaneous fat or visceral fat. Metabolic monitoring-based body fat decomposition wearing device to efficiently select and remove visceral fat and abdominal subcutaneous by varying the intensity, wavelength, and irradiation time of the body and utilize it to personalize health through cloud service It aims to provide a smart healthcare system and method for body fat decomposition based on metabolic monitoring that can be managed.

In addition, the present invention is not a simple activity record, but the physiological information of the human body, that is, the amount of oxygen-bound hemoglobin (HbO2), the amount of unbound oxygen hemoglobin (HbR), body water, lipids, etc. Not only can measurement data be provided and transmitted to a cloud server to enable more professional and personalized health management through big data analysis, but also people who have a common goal of accessing the smart healthcare platform can work together. It aims to provide a smart healthcare system and method for metabolism-based body metabolism monitoring that can provide the ability to induce steady health management through motivation along with the pleasure of achieving the goal.

The metabolic monitoring-based smart health care system for body fat decomposition of the present invention for achieving the above object,

The body fat decomposition device 1 based on metabolic monitoring is configured to be connected to each other, is composed of a plurality of sections, is configured to be wearable, and generates metabolic measurement data that monitors the wearer's metabolism while worn, and the metabolism A wear device for decomposing body fat based on metabolic monitoring that emits light to the body odor side of the wearer according to the measurement data to decompose body fat;

A terminal 10 capable of transmitting and receiving data to and from the body fat decomposition wearing device p, receiving the metabolic measurement data and transmitting the wearing device setting and control information;

The terminal (10) receives the metabolic measurement data from the terminal (10), operates a block compensation system using big data analysis and blockchain technology according to the metabolic measurement data, and generates personalized data according to the operation to generate the terminal (10). ) Can be configured to include. The body fat decomposition device (1),

After irradiating multi-wavelength body composition measurement light for monitoring the thickness of the subcutaneous fat and metabolism in a part of the body through the light source part 110 for body composition measurement, the diffused light diffused while passing through the internal tissues of the body is transmitted to the light detection unit 120 A body composition measuring unit 100 for detecting and outputting the thickness of the subcutaneous fat and a body composition measurement signal;

Body fat decomposition light source unit 200 for emitting body fat decomposition light;

A body fat-decomposing light power control unit 400 outputting multi-wavelength light source driving power sources for outputting light of body fat-decomposing multi-wavelength light sources 210 for individual body fat-decomposition according to the light control signal for body fat-decomposition input from the controller 500;

A body fat decomposition signal switching unit 300 transmitting multi-wavelength light source driving power output from the body fat decomposition light power control unit 400 to the multiwavelength light sources 210 for body fat decomposition;

Outputs a light control signal for body composition measurement to adjust the output wavelength and intensity of the body composition measurement light to the body composition measurement light source unit 110 of the body composition measurement unit 100, the light detection unit 120 of the body composition measurement unit 100 After performing the analysis of the thickness and body composition of the subcutaneous fat using the diffused light signal received by the control, the metabolic measurement data generated by generating metabolic specific data is transmitted to the terminal 10, and the metabolism is controlled. A control unit 500 that receives a set value for adjusting the light source for decomposing body fat and adjusts the intensity and irradiation time for each wavelength of the body fat decomposition light source 200 according to the analysis result based on the big data according to the measured data;

A power supply unit 600 for supplying power required for the body fat decomposition apparatus 1 and charging a battery;

A communication unit 700 transmitting the metabolic measurement data from the control unit 500 to the terminal 10; And

When the body fat decomposition apparatus 1 is composed of a plurality of sections, a connector 800 required for connection may be included.

The metabolic monitoring-based body fat decomposition wear device (p),

The metabolic monitoring-based body fat decomposition device 1 may be connected to each other to be composed of a plurality of sections, and may be configured to vary in section configuration according to body parts, and the metabolic monitoring-based body fat decomposition wearing device It may be configured to include a belt (b) that is connected to both ends of the (p), is coupled to be worn on the waist or body parts.

An application is installed in the terminal 10, and the application includes:

It is installed on a computer or a portable device, transmits the metabolic measurement data received from the metabolic monitoring-based body fat decomposition wearing device (p) to the cloud server, and analyzes individuals based on big data in the cloud server Receives information such as the adjustment of the light source for body fat decomposition, personalized exercise coaching, and diet, which is transmitted according to the health condition, and shows it through the computer or portable device, and the information and common goals of the group connected through the blockchain and It may be configured to receive and show the achievement through the cloud server.

The body composition measuring unit 100,

A body composition measurement light source unit 110 including a multi-wavelength diode array light source chip that outputs body composition measurement lights having respective wavelengths and intensities;

An optical driver unit 140 for outputting a multi-wavelength light source driving power to respective diodes of the multi-wavelength diode array light source chip constituting the light source unit 110 for measuring body composition;

A measurement light source switching unit 150 for switching the multi-wavelength light source driving power to be input to respective diodes of the multi-wavelength diode array light source chip;

In order to add a modulated signal to the multi-wavelength light source driving power, a modulated signal of a specific frequency is output to the optical driver unit 140, and a body composition measurement signal output through the optical detector 120 and the body composition measurement signal amplification unit 160 A filtering and amplifying unit 130 that outputs the intensity of the body composition measurement signal to the control unit 500 after removing the noise so as to detect only the signal matching the frequency of the modulated signal;

A light detection unit 120 including a plurality of light sensors spaced at predetermined intervals to detect diffused light that is irradiated from the body composition measurement light source unit 110 and diffuses as it passes through the internal tissue of the body and outputs the body composition measurement signal. ;

A body composition measurement signal amplification unit 160 for amplifying and outputting the body composition measurement signal output from the photodetector 120; And

It may be configured to include; body composition measurement signal switching unit 170 for outputting each body composition measurement signal output from the body composition measurement signal amplification unit 160 to the filtering and amplification unit 130.

The metabolic measurement data,

Fat layer thickness, oxygen-bound hemoglobin amount (HbO2), oxygen-unbound hemoglobin amount (HbR), body water content, fat %, size change amount of fat cells, and relationship between each measured component and body mass index (BMI) It may be configured to include one or more of the phosphorus R value.

The body fat decomposition light source unit 200,

Light of 635-680nm wavelength that promotes absorption by activating lipolysis, light of 920-930nm wavelength that alleviates cellulite, light of 930-980nm wavelength that is absorbed much by fat and water, and 805-830nm which reduces skin aging It includes an array of multi-wavelength light sources for body fat decomposition 210 that can be configured to irradiate light of a wavelength by selecting a wavelength or a number of wavelengths according to a function,

The control unit 500 drives the multi-wavelength light source output by the optical power control unit 400 for body fat decomposition according to the light control setting value for body fat decomposition generated through big data analysis according to the fat layer thickness and metabolism information for each body part. The body fat decomposition light source unit 200 may be configured to irradiate light having different intensity and irradiation time according to a wavelength by a power source.

The control unit 500

The body composition measurement light is irradiated to the body parts subject to body fat decomposition,

After the multi-distance diffused light is detected for each location, diffused light diffused from the internal tissue of the body part to be decomposed is converted into a body composition measurement signal and output.

Analyze the body composition measurement signal to calculate the subcutaneous fat thickness for each body part,

The absorption coefficient and scattering coefficient are calculated by applying the body composition measurement signal to a diffuse light spectroscopy method,

Using the calculated absorption coefficient, body composition analysis information including oxygen-bound hemoglobin (HbO2), oxygen-unbound hemoglobin (HbR), body water content, and lipid content is generated,

Calculate the size of adipocytes using the calculated scattering coefficient,

Obesity (Fat %) and R values are calculated using the calculated subcutaneous fat thickness and size information of fat cells to analyze obesity and generate metabolic measurement data according to the analyzed results.

It may be configured to transmit the measured metabolic measurement data to the cloud server 20.

The metabolic monitoring-based smart health care method for decomposing body fat of the present invention for achieving the above object,

Generating an initial metabolic measurement data by irradiating light for multi-wavelength body composition monitoring for metabolic monitoring to a part of the body and detecting diffused light diffused through tissues inside the body at multiple distances;

Decomposing body fat by irradiating the body of the wearer with body fat decomposition light according to the wavelength and intensity of light and irradiation time using the metabolic monitoring database;

It may be configured to include; a step of transmitting the metabolic measurement data generated by monitoring the metabolism again to the terminal (10).

The metabolic monitoring database may be obtained to include information on a wavelength, intensity, and irradiation time, respectively, set according to a light source control set value for body fat decomposition.

After the transmitting step of transmitting the metabolic measurement data to the terminal 10, the cloud server 20 receives the metabolic measurement data from the terminal 10;

The cloud server 20 is to generate personalized data including metabolic measurement data through diagnosis, exercise coaching, and dietary information through big data analysis;

Changing the light source adjustment setting value for body fat decomposition according to the personalized data generation;

Transmitting the modified body fat decomposition light source adjustment setting value and big data analysis data to the terminal 10;

The terminal may be configured to include; a display step of displaying the received set data for adjusting the changed body fat decomposition and big data analysis data.

The display step receives the light source adjustment value for body fat decomposition, personalized exercise coaching, and dietary information transmitted according to the health status of the individual analyzed based on the big data and collaborate with information of the group connected through the blockchain. It may be configured to receive and show the goals and achievements through the cloud server.

After the step of transmitting the metabolic measurement data to the cloud server,

The cloud server, receiving the metabolic measurement data of the individual from the mobile app;

Database the received metabolic measurement data of the individual;

Analyzing the database, analyzing the light source adjustment setting values for body fat decomposition suitable for an individual, personalized exercise coaching, and diet and transmitting the analyzed information to the terminal 10; And

Setting a personal health goal and applying a block compensation system utilizing blockchain technology through the mobile app when the metabolic measurement data received afterwards achieves the set health goal;

Setting a common goal by grouping people with similar health level information according to a predetermined number of people through the block compensation system; female,

When the set common goal is achieved, providing a reward group according to the level of achievement of each individual's health and providing an opportunity to participate in a block group consisting of more people as the next step of the block compensation system.

In the present invention having the above-described configuration, when body fat is reduced by irradiating light for body fat decomposition, the metabolic fat is measured, such as the thickness of the subcutaneous fat, body composition, and the size of fat cells for each body part where the visceral fat and abdominal subcutaneous fat are located. After detecting the metabolic rate, it is possible to selectively decompose visceral fat and abdominal subcutaneous fat by efficiently varying the body fat decomposition light of different wavelengths and intensities according to the subcutaneous fat thickness and the calculated metabolic rate. By providing the effect of significantly improving the efficiency of fat reduction.

In addition, the smart healthcare platform based on medical-level measurement data enables personalized health management, and through the integration of blockchain technology, users of multiple platforms set a common goal and have the pleasure of achieving it together. By providing, it will provide an effect to inspire motivation for steady health care without giving up.

1 is a block diagram of a body fat decomposition apparatus 1 based on metabolic monitoring according to an embodiment of the present invention.
Figure 2 is a functional block configuration diagram including the circuit function of the metabolic monitoring-based body fat decomposition device 1 of Figure 1;
FIG. 3 is a diagram illustrating a body fat decomposition wear apparatus p designed to be worn on the waist after the body fat decomposition apparatus 1 of FIG. 1 is composed of a plurality of sections.
4 is a graph showing the relationship between the intensity of light for decomposing body fat and the pulse width of light.
5 is a configuration diagram showing the configuration and data flow of a smart healthcare platform using the metabolic monitoring-based body fat decomposition wear apparatus and the present invention.
6 is a flowchart illustrating a process for processing mutual data of a wear device, a mobile app, and a cloud server based on metabolic monitoring based on metabolic monitoring according to an embodiment of the present invention.
7 is a flow chart illustrating a process of performing block compensation in a cloud server according to an embodiment of the present invention.

In the following description of the present invention, when it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

Embodiments according to the concept of the present invention can be applied to various changes and may have various forms, so specific embodiments will be illustrated in the drawings and described in detail in the present specification or application. However, this is not intended to limit the embodiment according to the concept of the present invention to a specific disclosure form, and the present invention should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Also, in this specification, the word "exemplary" is used to mean "serves as an example, as an example, or as an illustration." Any aspects described herein as “exemplary” are not necessarily to be construed as being preferred or advantageous over other aspects.

When an element is said to be "connected" or "connected" to another component, it is understood that other components may be directly connected or connected to the other component, but other components may exist in the middle. It should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle. Other expressions that describe the relationship between the components, such as "between" and "immediately between" or "adjacent to" and "directly neighboring to," should be interpreted similarly.

The terms used herein 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 indicates otherwise. In this specification, terms such as “include” or “have” are intended to indicate that a feature, number, step, action, component, part, or combination thereof described is present, and one or more other features or numbers. It should be understood that it does not preclude the presence or addition possibilities of, steps, actions, components, parts or combinations thereof.

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

1 is a block diagram of a body fat decomposition apparatus 1 based on metabolic monitoring according to an embodiment of the present invention, and FIG. 2 is a functional block diagram of the body fat decomposition apparatus 1 including circuit functions, and a control unit 500 It may be configured to include and further comprises a short-range wireless communication unit 700, the power supply unit 600, the body fat decomposition optical power control unit 400.

1, the metabolic monitoring-based body fat decomposition apparatus 1 (hereinafter referred to as'body fat decomposition apparatus 1)' is largely for body fat decomposition of the body composition measuring unit 100 and the body fat decomposition light source unit 200 It may be configured to include a multi-wavelength light source 210 and a connection connector 800 required for configuration in multiple sections.

As shown in FIG. 2, the body composition measuring unit 100 includes a filtering and amplifying unit 130, an optical driver unit 140, a measuring light source switching unit 150, a body composition measuring light source unit 110, a light detecting unit 120, and It includes a body composition measurement signal amplification unit 160, and after the light source unit 110 for measuring body composition is irradiated with a multi-wavelength body composition measurement light for metabolic monitoring to a part of the body, and diffuses through the internal tissues of the body. It is configured to perform the function of detecting light and outputting it as a body composition measurement signal.

The filtering and amplifying unit 130 outputs a modulated signal of a specific frequency according to the body composition measurement start signal applied from the control unit 500 and transmits the modulated signal to the optical driver unit 140, and is detected by the photodetector unit 120 After receiving the body composition measurement signal amplified through the measurement signal amplification unit 160, it is configured to select only the same signal as the modulation frequency, remove noise and amplify it, and output it to the control unit 500. The filtering and amplifying unit 130 performing the above-described functions may be configured as a lock-in amplifier.

The optical driver unit 140 is amplified by the filtering and amplifying unit 110, and each of the diodes of the multi-wavelength diode array light source constituting the light source unit 110 for measuring body composition according to the input light control signal for body composition measurement. It is configured to output wavelength diode driving power supplies.

The measurement light source switching unit 150 is configured to perform switching such that a plurality of multi-wavelength diode driving power sources input from the optical driver unit 140 are applied to desired diodes. The measurement light source switching unit 150 having the above-described configuration may be configured as a switch having a switch element such as a multiplexer (MUX) or a plurality of transistors.

The body composition measurement light source unit 110 is configured to include a multi-wavelength diode array light source that outputs light for body composition measurement having a wavelength and intensity selected according to the multi-wavelength diode driving power sources. At this time, the body composition measurement light output through the multi-wavelength diode array light source includes a plurality of wavelength-specific light in the NIR-VIS (Near Infrared-Visible) band.

The multi-wavelength diode array light source chip that outputs the multi-wavelength light as described above includes a plurality of multi-wavelength diodes in the form of FP (Fabry-Perot), VCSEL (Vertical Cavity Surface Emitting Laser), DFB (Distributed Feedback), and LED. It can be configured to be packaged to emit, and a light source for each wavelength in the form of a die, such as a vertical cavity surface emitting laser (VCSEL) or LED, may be composed of a surface mount type packaging chip.

The photodetector 120 is a plurality of optical sensors that are spaced apart at predetermined intervals to detect the diffused light that is irradiated from the body composition measuring light source unit 110 and passes through the internal tissues of the body and converts it into a body composition measurement signal and outputs it. It comprises a field (121, 122, 123).

The body composition measurement signal amplification unit 160 is composed of amplifiers (Amplifiers) for amplifying the body composition measurement signal output from the photodetector 120 and outputting it to the body composition measurement signal switching unit 170.

The body fat decomposition light power control unit 400 is configured to output multi-wavelength light source driving power sources for outputting light for body fat decomposition of the body fat decomposition light source unit 200 according to the light control signal for body fat decomposition input from the control unit 500. . The multi-wavelength light source driving power sources are outputted to the multi-wavelength light sources 210 for body fat decomposition through the body fat decomposition signal switching unit 300.

The body fat decomposition light source unit 200 is composed of an array of body fat decomposition multi-wavelength light sources 210, and when the body fat decomposition apparatuses 1 are composed of a plurality of sections, the multi-wavelength light source driving power sources are used for body fat decomposition light source unit ( 200) is selectively output for each body part, and is configured to irradiate light for body fat decomposition having different wavelengths and intensities for each body part. Specifically, the body fat decomposition light source unit 200 activates lipolysis to promote absorption, 635-680nm wavelength light, 920-930nm wavelength light to alleviate cellulite, 930-980nm absorbed a lot in fat and water It includes an array of multi-wavelength light sources 210 for body fat decomposition that can be configured to irradiate light at wavelengths of 805 to 830 nm to reduce skin aging by selecting a wavelength or a number of wavelengths according to function. The body fat decomposition light source unit 200 having the above-described configuration is the body fat decomposition light power control unit 400 according to the light control signal for body fat decomposition generated by the body part according to the fat layer thickness and metabolism information for each body part. The light source parts 200 for body fat decomposition are configured to irradiate light having different wavelengths, intensity and irradiation time for each body part by driving power of the multi-wavelength light source output from the body.

The body fat decomposition light source unit 200 may also be configured by packaging FP (Fabry-Perot), VCSEL (Vertical Cavity Surface Emitting Laser), DFB (Distributed Feedback), and LED-type diodes so as to emit a number of multiple wavelengths. In addition, a light source for each wavelength in the form of a die such as a vertical cavity surface emitting laser (VCSEL) or an LED may be formed of a surface-mount type packaging chip.

The above-described light source unit 110 for measuring body composition and the light source unit 200 for decomposing body fat are configured to selectively output multi-wavelength light having a plurality of wavelengths and different intensities.

In order to control the metabolic measurement using the body composition measurement unit 100 and the performance of body fat decomposition by the body fat decomposition light source unit 200, the control unit 500 is a light source unit for measuring the body composition of the body composition measurement unit 100 ( 110) outputs a light control signal for body composition measurement to adjust the output wavelength and intensity of the light for body composition measurement, performs body composition analysis using the body composition measurement signal received from the body composition measurement unit 100, and then metabolism measurement data The body fat decomposition light power to control the body fat decomposition light control signals for adjusting the wavelength and intensity of the body fat decomposition multi-wavelength light sources 310 constituting the body fat decomposition light source unit 200 according to the generated metabolic measurement data. It is configured to output to the control unit 400.

Here, the light control signal for body fat decomposition is 635 to 680 nm wavelength that promotes the absorption of visceral fat according to the thickness of body fat and the size of fat cells in the abdominal subcutaneous region, and is activated by fat decomposition by absorbing in the abdominal subcutaneous fat. It is a signal that outputs light of wavelength 920~930nm that promotes and has a size suitable for lipolysis for each body part.

And the metabolic measurement data includes subcutaneous fat thickness, fat cell size, oxygen-bound hemoglobin (HbO2), oxygen-unbound hemoglobin (HbR), body water content, lipid (lipid), fat %, and R values. It contains one or more.

3 is a view showing a body fat decomposition wear apparatus (p) designed to be worn on the waist after the body fat decomposition apparatus 1 of FIG. 1 is composed of a plurality of sections.

3, the body fat decomposition apparatus 1 of the present invention, when removing body fat by irradiating a light source, detects the subcutaneous fat thickness and the size of fat cells for each body part, and monitors changes in metabolism to illuminate. The pads to which the body fat decomposition apparatuses 1 are attached in a plurality of sections so that the visceral fat and the abdominal subcutaneous fat can be efficiently removed by irradiating by varying the intensity and wavelength of the visceral fat or the abdominal subcutaneous fat. ) And connected to both ends of the metabolic monitoring body fat decomposition device 1 may be made of a body fat decomposition wearing device (p) including a belt (b) coupled to be worn on the waist.

4 is a graph showing the relationship between the intensity of light for decomposing body fat and the pulse width of light. When the intensity of the body fat-decomposing light is described with reference to FIG. 4, FIG. 4(a) continuously outputs low-intensity light, and FIG. 4(b) outputs light of a higher intensity in pulse form for T hours. Repeating the output for a short period of time as tp1 time, FIG. 4(c) is a graph showing output of higher intensity while emitting light for a shorter time than the pulse of FIG. 7(b). As an example, when the subcutaneous fat is thin and the decomposition of the subcutaneous fat is performed, it is preferable to output light for decomposing body fat as shown in FIG. 4(a), and the thicker the subcutaneous fat or the decomposition of visceral fat. In the case of performing, it is good to output light for body fat decomposition as shown in FIG. 4(c) so that the light can reach the depth. When the pulse width of the body fat-decomposing light is narrowed, high intensity light is output to reach the deep part of the abdomen, while the average light intensity can be maintained the same as in Fig. 4(a). Can be removed.

5 is a diagram of a smart healthcare system that can provide a more professional personalized health care function based on metabolic information measured through a body fat decomposition wearing device.

The system consists of a body fat decomposition wearing device (p), a terminal 10, and a cloud server 20.

As described above, in the system of the present invention, physiological information measured through the body composition measuring unit 100 of the body fat decomposition wear apparatus, and parameters set as the currently operating wavelength and output power are transmitted to the mobile software, and then clouded again. It is transmitted to the server and stored, and through the analysis of big data information based on medical-level physiological measurement information, the current health condition and the corresponding health management information and the setting optimization correction value of the wearing device are transmitted back to the mobile software, It is a personalized smart healthcare platform that enables users to check their health information and management information, and automatically corrects the optimal set value of the body fat decomposition wear device when the body fat decomposition wear device is used again.

In addition, a group of people with similar health conditions can be grouped and all members of the group can provide products through data mining in a way that achieves a common goal. It is a health-K platform that also incorporates blockchain technology that can provide.

The metabolic monitoring-based wear device for decomposing body fat (p) is composed of the above-described metabolic monitoring-based body fat decomposition device (1) connected to each other, is composed of a plurality of sections, is configured to be wearable, and worn by a wearer Generates metabolic measurement data that monitors the metabolism of the body and decomposes body fat by emitting light to the body odor side of the wearer according to the metabolic measurement data.

The terminal 10 can transmit and receive data to and from the body fat decomposition wearing device p, receive the metabolic measurement data, and transmit the wearing device setting and control information. In addition, the terminal 10 transmits metabolic measurement data to the cloud server 20. Then, personalized data is received from the cloud server 20.

The cloud server 20 receives the metabolic measurement data from the terminal 10 and operates a big data analysis and block compensation system using blockchain technology according to the metabolic measurement data and generates personalized data according to the operation. To the terminal 10.

6 is a flowchart illustrating a process of processing mutual data of a wear device for dissolving body fat, a mobile app, and a cloud server based on metabolic monitoring. The body fat decomposition wearable device (p) and the mobile app first go through a wireless connection process via Bluetooth (S100), and then perform a process of applying the set value of the body fat decomposition wearable device (S110) previously stored in the mobile app. . Here, the set value means a set value for adjusting the light source for decomposing body fat, and is a set value for adjusting the received light source for decomposing body fat according to the analyzed result based on big data.

Thereafter, the controller 500 controls the body composition measuring unit 100 to measure metabolic information, and controls the body fat-decomposing optical power control unit 400 to decompose body fat and measure metabolic information again (S120). After that, the process of transmitting and storing the metabolic measurement data to the mobile app proceeds (S130).

The mobile app transmits and stores metabolic measurement data stored in a mobile device to a cloud server (S140), and the cloud server diagnoses the stored database through big data analysis to generate personalized information such as exercise coaching or diet. Then, a process (S150) of changing the light source adjustment value for body fat decomposition to a value suitable for the analysis result is performed. The light source adjustment set values for body fat decomposition may be intensity according to wavelengths of light for body fat decomposition, light irradiation pulse width as shown in FIG. 4, and total irradiation time.

Next, the cloud server includes the process of displaying and analyzing the analyzed data in the mobile app (S170) after passing the changed light control settings for body fat decomposition and big data analysis result data to the mobile app (S160). do.

7 is a flowchart illustrating a process of performing block compensation in a cloud server according to an embodiment of the present invention.

Referring to FIG. 7, an individual who does not belong to a block group starts with a process of setting an individual's goal (S200), and has achieved a set goal while executing a steady metabolic measurement, body fat decomposition, and big data analysis process (S210). If it is determined (S220) and the goal is successfully achieved, a block group is formed with N people having similar health levels and a common goal is set (S240).

It is determined whether the individuals belonging to each group have achieved the common goals of the set group while performing the metabolic measurement, body fat decomposition, and big data analysis process (S240) (S250), and if the common goals are achieved, the level of individual achievement In accordance with the rewards through the product and a group of people with similar health level, a group of blocks is formed again, and a process of setting a common goal again (S260) is performed. At this time, it is desirable to increase the difficulty of achieving the goal by making the number of people in the block group larger than the number of people in the previous block group, N.

Subsequent processes (S270, S280, and S290) may be continued as rewards and new block groups are formed according to the goal achievement.

The above description of the present invention has been described with reference to the embodiment shown in the drawings, but this is only exemplary, and those skilled in the art can understand that various modifications and other equivalent embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims.

1: metabolic monitoring-based body fat decomposition device, 100: body composition measurement unit, 110: body composition measurement light source unit, 120: light detection unit, 121: the first optical sensor, 122: the second optical sensor, 123: the third optical sensor, 130 : Filtering and amplification unit, 140: optical driver unit, 150: measurement light source switching unit, 160: body composition measurement signal amplification unit, 170: body composition measurement signal switching unit 200: body fat decomposition light source unit, 210: body fat decomposition multi-wavelength light source, 300 : Body fat decomposition signal switching unit, 400: body fat decomposition optical power control unit, 500: control unit, 600: power supply unit, 700: short-range wireless communication unit, 800: connector, p: body fat decomposition wear device, b: belt

Claims (13)

The metabolic monitoring-based smart health care system for body fat decomposition of the present invention for achieving the above object,
The body fat decomposition device 1 based on metabolic monitoring is configured to be connected to each other, is composed of a plurality of sections, is configured to be wearable, and generates metabolic measurement data that monitors the wearer's metabolism while worn, and the metabolism A wear device for decomposing body fat based on metabolic monitoring that emits light to the body odor side of the wearer according to the measurement data to decompose body fat;
A terminal 10 capable of transmitting and receiving data to and from the body fat decomposition wearing device p, receiving the metabolic measurement data and transmitting the wearing device setting and control information;
The terminal (10) receives the metabolic measurement data from the terminal (10), operates a block compensation system using big data analysis and blockchain technology according to the metabolic measurement data, and generates personalized data according to the operation to generate the terminal (10). ), a cloud server that transmits a smart healthcare system for metabolism-based body metabolism monitoring. According to claim 1, The body fat decomposition device (1),
After irradiating multi-wavelength body composition measurement light for monitoring the thickness of the subcutaneous fat and metabolism in a part of the body through the light source unit 110 for body composition measurement, the diffused light diffused as it passes through the internal tissues of the body is transferred to the light detection unit 120 A body composition measuring unit 100 for detecting and outputting the thickness of the subcutaneous fat and a body composition measurement signal;
Body fat decomposition light source unit 200 for emitting body fat decomposition light;
A body fat-decomposing light power control unit 400 outputting multi-wavelength light source driving power sources for outputting light of body fat-decomposing multi-wavelength light sources 210 for individual body fat-decomposition according to the light control signal for body fat-decomposition input from the controller 500;
A body fat decomposition signal switching unit 300 transmitting multi-wavelength light source driving power output from the body fat decomposition light power control unit 400 to the multiwavelength light sources 210 for body fat decomposition;
Outputs a light control signal for body composition measurement to adjust the output wavelength and intensity of the body composition measurement light to the body composition measurement light source unit 110 of the body composition measurement unit 100, the light detection unit 120 of the body composition measurement unit 100 After performing the analysis of the thickness and body composition of the subcutaneous fat using the diffused light signal received by the control, the metabolic measurement data generated by generating metabolic specific data is transmitted to the terminal 10, and the metabolism is controlled. A control unit 500 that receives a set value for adjusting the light source for decomposing body fat and adjusts the intensity and irradiation time for each wavelength of the body fat decomposition light source 200 according to the analysis result based on the big data according to the measured data;
A power supply unit 600 for supplying power required for the body fat decomposition apparatus 1 and charging a battery;
A communication unit 700 transmitting the metabolic measurement data from the control unit 500 to the terminal 10; And
When the body fat breakdown device (1) is composed of a plurality of sections, a connector required for connection (800); Metabolic monitoring-based smart health care system for body fat breakdown. According to claim 2, The metabolic monitoring-based body fat decomposition wearing device (p),
The metabolic monitoring-based body fat decomposition device 1 may be connected to each other to be composed of a plurality of sections, and may be configured to vary in section configuration according to body parts, and the metabolic monitoring-based body fat decomposition wearing device Smart health care system for metabolic monitoring based on metabolic monitoring, which is connected to both ends of (p) and comprises a belt (b) that is coupled to be worn on a waist or body part. According to claim 2, The terminal 10, the application is installed and the application,
It is installed on a computer or a portable device, and transmits the metabolic measurement data received from the metabolic monitoring-based body fat decomposition wearing device (p) to the cloud server, and the cloud server analyzes the individual based on the big data. Receives information such as the adjustment of the light source for body fat decomposition, personalized exercise coaching, and diet, which is transmitted according to the health condition, and shows it through the computer or portable device, and the information and common goals of the group connected through the blockchain and Metabolic monitoring-based smart healthcare system for metabolic fat monitoring that is configured to receive and show achievement through the cloud server. According to claim 2, The body composition measuring unit 100,
A body composition measurement light source unit 110 including a multi-wavelength diode array light source chip that outputs body composition measurement lights having respective wavelengths and intensities;
An optical driver unit 140 for outputting a multi-wavelength light source driving power to respective diodes of the multi-wavelength diode array light source chip constituting the light source unit 110 for measuring body composition;
A measurement light source switching unit 150 for switching the multi-wavelength light source driving power to be input to respective diodes of the multi-wavelength diode array light source chip;
In order to add a modulated signal to the multi-wavelength light source driving power, a modulated signal of a specific frequency is output to the optical driver unit 140, and a body composition measurement signal output through the optical detector 120 and the body composition measurement signal amplification unit 160 A filtering and amplifying unit 130 that outputs the intensity of the body composition measurement signal to the control unit 500 after removing noise so as to detect only a signal that matches the frequency of the modulated signal;
A light detection unit 120 including a plurality of light sensors spaced at predetermined intervals to detect diffused light that is irradiated from the body composition measurement light source unit 110 and diffuses as it passes through the internal tissue of the body and outputs the body composition measurement signal. ;
A body composition measurement signal amplification unit 160 for amplifying and outputting the body composition measurement signal output from the photodetector 120; And
Includes; body composition measurement signal switching unit 170 for outputting each body composition measurement signal output from the body composition measurement signal amplification unit 160 to the filtering and amplification unit 130; Smart healthcare system. According to claim 1, The metabolic measurement data,
Fat layer thickness, oxygen-bound hemoglobin amount (HbO2), oxygen-unbound hemoglobin amount (HbR), body water content, fat %, size change of fat cells, and relationship between each measured component and body mass index (BMI) Metabolic monitoring-based smart health care system that includes one or more of phosphorus R values. According to claim 2, The body fat decomposition light source unit 200,
Light of 635-680nm wavelength that promotes absorption by activating lipolysis, light of 920-930nm wavelength that alleviates cellulite, light of 930-980nm wavelength that is absorbed much by fat and water, and 805-830nm which reduces skin aging It includes an array of multi-wavelength light sources for body fat decomposition 210 that can be configured to irradiate light of a wavelength by selecting a wavelength or a number of wavelengths according to a function,
The control unit 500 drives the multi-wavelength light source output by the optical power control unit 400 for body fat decomposition according to the light control setting value for body fat decomposition generated through big data analysis according to the fat layer thickness and metabolism information for each body part. Metabolic monitoring-based smart health care system based on metabolic monitoring, wherein the light source 200 for body fat decomposition is configured to irradiate light having different intensity and irradiation time according to wavelength. Irradiating light for body composition measurement to a body part to be decomposed into body fat;
Controlling the diffused light diffused from the internal tissue of the body fat decomposition body to be converted to a body composition measurement signal after performing multi-distance diffused light detection for each location;
Calculating the subcutaneous fat thickness for each body part by analyzing the body composition measurement signal;
Calculating an absorption coefficient and a scattering coefficient by applying the body composition measurement signal to a diffuse light spectroscopy method;
Generating body composition analysis information including an oxygen-bound hemoglobin amount (HbO2), an oxygen-unbound hemoglobin amount (HbR), body water content, and lipid amount using the calculated absorption coefficient;
Calculating the size of adipocytes using the calculated scattering coefficient;
Generating metabolic measurement data according to the analyzed results by calculating obesity (Fat %) and R values using the calculated subcutaneous fat thickness and size information of fat cells;
Transmitting the measured metabolic measurement data to the cloud server 20; Smart health care method for metabolism-based body metabolism monitoring comprising a. The method of claim 8, wherein irradiating multi-wavelength body composition measurement light for metabolic monitoring to a portion of the body and detecting diffused light diffused through the internal tissues at multiple distances to generate initial metabolic measurement data. ;
Decomposing body fat by irradiating the body of the wearer with body fat decomposition light according to the wavelength and intensity of light and irradiation time using the metabolic monitoring database;
A meta-monitoring-based smart health care method for body fat decomposition further comprising; a transmitting step of transmitting metabolic measurement data generated by monitoring metabolism again to the terminal 10. 10. The method of claim 9, wherein the metabolic monitoring database is configured to include information on the wavelength, intensity, and irradiation time, respectively, set according to the light source control setting values for body fat decomposition smart health care for body fat decomposition based on metabolic monitoring Way. 10. The method of claim 9, After the transmitting step of transmitting the metabolic measurement data to the terminal (10),
The cloud server 20 receiving metabolic measurement data from the terminal 10;
The cloud server 20 is to generate personalized data including metabolic measurement data through diagnosis, exercise coaching, and dietary information through big data analysis;
Changing the light source adjustment setting value for body fat decomposition according to the personalized data generation;
Transmitting the modified body fat decomposition light source adjustment setting value and big data analysis data to the terminal 10;
The terminal comprises a display step of displaying the received set data for the modified body fat decomposition and the big data analysis data; a smart healthcare method for metabolism based on metabolic monitoring. The method of claim 11, wherein the display step,
Receiving the light source adjustment value for body fat decomposition, personalized exercise coaching, and dietary information transmitted according to the health condition of the individual analyzed based on big data, and reminding of the information and joint goals and achievements of the group connected through the blockchain Metabolic monitoring based smart health care method for body fat decomposition that is configured to be received and shown through a cloud server. According to claim 8, After the step of transmitting the metabolic measurement data to the cloud server,
The cloud server, receiving the metabolic measurement data of the individual from the mobile app;
Database the received metabolic measurement data of the individual;
Analyzing the database, analyzing the light source adjustment setting values for body fat decomposition suitable for an individual, personalized exercise coaching, and diet and transmitting the analyzed information to the terminal 10; And
Setting a personal health goal and applying a block compensation system utilizing blockchain technology through the mobile app when the metabolic measurement data received afterwards achieves the set health goal;
Setting a common goal by grouping people with similar health level information according to a predetermined number of people through the block compensation system; And
When the set common goal is achieved, providing an opportunity to participate in a block group consisting of more people as a compensation benefit and a next step of the block compensation system according to the level of achievement of each individual's health. Smart health care method for body fat decomposition based on monitoring.

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