KR20220166895A - Calorie monitoring weight target tracking device and method for basic immunity enhancement - Google Patents

Abstract

According to the present invention, a health care system using a smart scale comprises: a smart scale which recognizes the user's bio-signals and measures the body fat for each part of the user's body; an electronic device which is interlocked with the smart scale and allows the user to check the result value measured from the smart scale; and a server which exchanges data with the smart scale and the electronic device and stores records related to the user's health management. The server includes a recommendation mode for suggesting a health management program to the user by analyzing the user's current health condition. The user can easily check data related to his or her health through a smartphone.

Description

Calorie monitoring weight target tracking device and method for basic immunity enhancement}

The present invention relates to a health care system for tracking and investigating the health history of a person using a smart scale and providing an appropriate health program. and a health care system using a smart weight scale that recommends a diet plan, exercise method, etc. for efficient health management to a user based on the similar history.

BACKGROUND ART As dietary life is advanced in modern society, western-type diseases such as obesity are gradually increasing. Accordingly, in various public facilities such as gymnasiums and hospitals, weight scales having various functions are widely used to check one's health condition. However, since analog weight scales are inconvenient due to low precision, most institutions use digital weight scales using load cells.

In a conventional digital scale, analysis information for health management is displayed when a user inputs his/her information, and data such as user information and body composition analysis results are stored in a server, enabling health history management for each individual. .

This data could be checked by the user through an electronic device such as a smartphone. Specifically, whenever a user uses a digital scale, his or her smartphone and digital scale are connected to each other through a method such as Bluetooth, and then the user's own data can be read and the corresponding data checked. As such, conventionally, whenever a user wants to check his or her own data through a smartphone, the scale and his or her smartphone must be interlocked, so it is cumbersome to utilize the corresponding system.

In addition, as disclosed in Registered Patent No. 10-1950555, conventionally, an application capable of managing a user's weight information through a smartphone and measuring bio-signals to identify various diseases has been developed and released. However, such a health management system using a conventional smart phone is only at the level of simply checking the user's weight information or disease, and has not been able to suggest an active solution to solve this problem.

Therefore, in order to still systematically manage health, it was necessary to receive individual training while going to a health club or the like, or to perform separate management through diet, medical means, and the like. Due to this, there is a problem in that too much time and money are consumed in health management, and furthermore, when a certain time elapses, a problem such as failure of continuous health management due to a decrease in the user's will occurs.

An object of the present invention is to enable a user to easily check data related to his/her own health through a smartphone, and to search similar histories to be compared based on the user's eating habits, activity level, etc., to provide customized health care services for each individual. It is to provide a healthcare system using a smart scale that can recommend.

The present invention provides the following technical means as a means for solving the above problems.

A health care system using a smart scale according to the present invention is a smart scale capable of recognizing a user's bio-signal and measuring body fat for each body part of the user, and a result value measured by the smart scale and interlocked with the smart scale. It includes an electronic device capable of checking the health of the user and a server that exchanges data with the smart weight scale and the electronic device and stores records related to the user's health management, wherein the server analyzes the user's current health condition and provides the user with a health management program. It includes a recommendation mode that suggests

According to the proposed present invention, it is enough for the user to exchange data by interlocking the scale and his or her smartphone in a method such as Bluetooth only at the beginning of use to use this system, and when such initial registration is completed, interworking such as Bluetooth is no longer necessary. Even without this, the user can easily check the data measured by the weight scale and the data processed by the server through his or her smartphone, so the convenience of use can be greatly improved.

In addition, according to this system, the user's self-history measured through the smart scale and the similar history to be compared are searched, and based on the similar history, the user is recommended for success cases, future diet, exercise amount, exercise method, etc. There is an advantage in that efficient personalized health care can be achieved because recommendations are made for each patient. In addition, since the information of each user stored in the server becomes basic health management data, and the data can be combined with other solutions, the reliability of the system can be gradually improved as the usage of the system increases.

The accompanying drawings are intended to explain the contents of the present invention in more detail to those skilled in the art, but the technical spirit of the present invention is not limited thereto.
1 is a block diagram showing the overall configuration of a healthcare system according to an embodiment of the present invention.
2 is a perspective view showing a smart scale in the health care system.
3 is a block diagram for explaining detailed functions of a server in the healthcare system.
4 is a flowchart illustrating a process of executing a similarity history search mode and a recommendation mode among functions of the server.
5 is a block diagram illustrating an example of execution of the recommendation mode.
6 is a flowchart illustrating a process of executing a compensation mode among functions of the server.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be interpreted in a conventional or dictionary sense, and the inventor may properly define the concept of the term in order to describe his/her invention in the best way. Based on the principle that it can be, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, so at the time of this application, various alternatives for them are possible. It should be understood that there may be equivalents and variations.

1 is a block diagram showing the overall configuration of a healthcare system according to an embodiment of the present invention. And, Figure 2 is a perspective view showing a smart scale in the health care system. 1 and 2, the healthcare system according to the present invention interlocks with a smart scale 10 capable of measuring a user's weight, obesity, body fat, etc. It includes a smartphone 200 to be. In addition, the information stored and inputted in the smart scale 10 and the smartphone 200 is transmitted to the server 100, and the server 100 analyzes and processes this information and returns to the smart scale 10. Alternatively, it may be transmitted to the smart phone 200. The smart phone 200 presents an example of an electronic device mainly used by a user, and a PDA capable of exchanging information with the smart scale 10 and the server 100 instead of the smart phone 200, Other electronic devices such as laptops may also be used.

A method for a user to utilize the healthcare system is as follows. First, after the user executes the application of the smart phone 200, the smart scale 10 and the smart phone 200 are interlocked with each other in a Bluetooth manner. When the Bluetooth linkage between the two devices is completed, the user recognizes his or her biosignal through the smart scale 10. Accordingly, information about the biosignal is transmitted to the smart phone 200 . Next, the user inputs personal information such as age, height, and gender into the smart phone 200, and information about the user's personal information is transmitted to the smart scale 10. That is, the information on the user's bio-signal and the user's personal information are shared between the smart scale 10 and the smartphone 200, respectively.

The user's bio-signal measured by the smart weight scale 10 may be, for example, the user's foot. Specifically, when the user places the sole of the foot on the stepping plate 20 of the smart scale 10, the foot foot is recognized among the user's bio-signals, and information about this may be input as the user's personal information. As another example, the bio-signal may be used for vein recognition that can determine whether or not the user is a person using a vein flowing in the user's palm or finger. Volume pulse wave recognition may also be used.

However, in order to increase the recognition rate for the user, in the present invention, a method according to complex biorecognition in which two or more methods of foot leg recognition, vein recognition, and photoplethysmogram recognition are used together may be used. For example, the bio-signal of the user measured by the smart scale 10 may be a complex bio-recognition in which vein recognition and foot leg recognition are used together, or a complex bio-recognition in which vein recognition and photoplethysmography are used together. Alternatively, it may be complex biorecognition in which foot foot recognition and photoplethysmography recognition are used together, or complex biometric recognition in which foot foot recognition, vein recognition, and photoplethysmography recognition are all used. In this way, the smartphone 200 The information about the bio-signals transmitted to and personal information of the user input through the smart phone 200 are transmitted to the server 100 and converted into basic data. That is, the server 100 receives various types of information from the smartphone 200, converts them into user basic data, and stores them. Through this process, the initial registration of the user is completed (see FIG. 1(a)).

After the initial registration process is completed, the user can utilize the health care system even if the smart phone 200 and the scale 10 are not interlocked in a method such as Bluetooth. Specifically, when the smart scale 10 is connected to the Internet network 300 such as a router, the user's current body weight, obesity degree, and body fat measured by the smart scale 10 through the Internet network 300 Information is transmitted to the server 100 . The server 100 processes the user's basic data converted at the time of initial registration and information about the current body information together. This processed data is displayed as information about the user's body information history to the user when the user automatically logs in to the platform of the smart phone 200 (see FIG. 1(b)). As such, according to the present invention, it is sufficient that the smart weight scale 10 and the smart phone 200 are interlocked in the Bluetooth method only at the beginning of use, and when the initial registration is completed, even if there is no further interlocking such as Bluetooth, the user can use the smart phone Since the processed information can be checked through 200, the convenience of use can be greatly improved. The smart weight scale 10 includes a handle 30 serving as a handle that can be gripped by a user, a stepping plate 20 serving as a footrest in contact with the user's feet, and connecting the handle 30 and the stepping plate 20. It consists of a support 40 to. A total of four sensing units 25 that suggest contact points with the user's sole are formed on the stepping plate 20, and similarly, a total of four sensing units that suggest contact points with the user's palm are formed on the handle 30. A portion 35 is formed. A total of eight sensing units 25 and 35 are electrode parts through which electricity flows through the human body so as to measure the user's body composition. A method capable of analyzing a user's body composition through the sensing units 25 and 35 through which electricity flows in this way is referred to as a touch electrode measurement method.

This touch-type electrode measuring method refers to a method of analyzing body composition by measuring a resistance value of how much electricity passes when electricity is passed through the user's body. In the present invention, among the touch electrode measurement methods, a direct impedance measurement method (DSM-BIA) for each part of the body capable of analyzing body components such as body fat is used. The direct impedance measurement method for each part is a method of measuring the impedance of both arms, legs, and trunk of the human body. way to do it As can be seen in Figure 2, the smart weight scale 10 according to the present invention uses an 8-point touch electrode method. As the 8-point touch electrode method is used, more accurate measurement of body composition such as body fat can be performed for each part, and reliability of the measurement result can be increased. As another example, the smart scale 10 has many A four-point touch electrode method, which is the method used, may also be used. According to the four-point touch electrode method, the four sensing units 35 installed on the handle 30 are excluded from the configuration shown in FIG. 2 can be made with That is, the body composition may be measured by measuring the body composition of the user's lower body through the four detectors 25 formed on the stepping plate 20 and estimating the body composition of the user's upper body based on the body composition of the lower body.

The user can check the measurement result through the monitor 50 formed on the central front portion of the handle 30 . The monitor 50 is an LCD monitor, and is a device that displays body composition analysis results for each body part of the user. That is, the user can check the body composition analysis result in real time through the monitor 50 . In addition, in the present invention, a heart rate monitor may be additionally installed to measure not only the user's body composition, but also the user's heart rate condition. The heart rate monitor may be installed in the handle 30 of the smart scale 10 in the form of a sensor, or may be configured in a wristwatch type separately from the smart scale 10 as another example. A heart rate sensor for measuring a user's heart rate is installed in the heart rate monitor. That is, the number of times the user's heart beats per minute can be checked through the heart rate sensor and the corresponding number can be displayed on the monitor 50 or a display of a separate watch. According to this process, the user's body composition and heart rate When the measurement of the state is completed, the corresponding data is transmitted to the user's smartphone and server, and information on the user's current health state is delivered. Hereinafter, the server 100 exchanging information with the smart scale 10 and the smart phone 200 will be described. 3 is a block diagram for explaining detailed functions of a server in the healthcare system.

Referring to FIG. 3 , the server 100 tracks and manages the user's health history, analyzes and processes various information to provide the user with better health management services. Specifically, when the user uses the smart scale 10 for a certain period of time, the self history measurement mode 110 of the server 100 is executed, and information on the use history of the smart scale 10 is stored and edited. . The self-hysteresis measurement mode 110 may function in various ways according to the period of use of the smart weight scale 10 and the number of times. If the user intends to use the smart scale 10 at a predetermined time, such as a predetermined time, for example, 1 day, every other day, 1 week, or a specific day of the week, the regular measurement mode among the self history measurement modes 110 is activated. do. According to the regular measurement mode, since the user regularly uses the smart weight scale 10, more reliable information about the use history can be obtained, and accordingly, accurate analysis results can be derived. At this time, an alarm unit may be additionally installed in the smart scale 10 to inform the user that a predetermined time has arrived. This alarm unit may be a visual alarm or an audible alarm.

In contrast, if the user sets only the whole body composition measuring period and wants to randomly use the smart scale 10 within the whole period, the non-regular measurement mode among the self history measurement modes 110 is activated. In the non-regular measurement mode, the minimum number of times of using the smart scale 10 and measurement timing must be presented in order to accurately analyze the body composition within a specific period. The regular measurement mode or the non-regular measurement mode may be selected by the user or may be automatically set by the server 100 according to the frequency of use of the smart scale 10 by the user. When the self-hysteresis measurement mode 110 is terminated, the server 100 executes the analysis mode 120 for synthesizing results during the measurement period of the self-hysteresis measurement mode 110 . The analysis mode 120 can be largely divided into analysis by time, which is an analysis result according to the time the user uses the smart scale 10, and analysis by location, which is an analysis result according to the place where the user uses the smart scale 10.

The hourly analysis may produce results such as daily analysis divided into morning, afternoon, and evening time zones, analysis by day of the week classified from Monday to Sunday, analysis by holiday dividing weekdays and weekends, other weekly analysis, monthly analysis, etc. there is. In addition, the space-specific analysis may divide the smart scale 10 into places where the smart scale 10 is used, for example, gym, work, home, etc., and results about where the body composition state is maintained excellently can be derived. According to the result of the analysis mode 120, the user's body composition increase/decrease pattern analysis may be performed in various ways.

When the user's body composition increase/decrease pattern is identified through the analysis mode 120, the server 100 may execute a similar history search mode 130 that can be compared with the analysis result of the user's body composition pattern, etc. . When the similar history search mode 130 is executed in the server 100, the current user's history is matched with similar success or failure cases of others, and accordingly, the user can be alerted to health management. That is, as the similar history search mode 130 is executed, the server 100 provides the user with the exercise amount, exercise method, diet menu, etc. of the other person while proposing success stories of others similar to the current user's history. If the current user's history is close to the failure case, the risk index for this can be calculated to make the user realize the need for body care. In this way, the user's history, that is, self-history The similarity history can be searched based on the degree of correspondence between the self-history and the similarity history and the weights of factors determining the degree of correspondence.

Factors determining the degree of agreement between histories may be composed of various conditions. For example, the more similar the ages between the self-history and the similar history, the higher the degree of concordance, and the longer the measurement period and the greater the number of measurements, the higher the degree of agreement between the histories. That is, in the pattern of history change of oneself and others, the accuracy of the change pattern compared and analyzed for one week will be higher than that of the change pattern that is compared and analyzed only for one day. would mean rising.

In addition, the more similar the usage frequency and usage time of the smart scale 10 between oneself and another person are, the higher the matching accuracy between the histories will be. In addition, body fat similarity will have higher accuracy than weight similarity between both histories, and obesity similarity will have higher accuracy than body fat similarity. In addition, if one's and others' living areas are similar, work in similar industries, and have similar meal times, the matching accuracy between the two histories will increase. A plurality of factors that determine the degree of agreement between these histories may be weighted according to their importance. For example, since the information factor of age has a greater importance than other factors, a large weight may be assigned to . In addition, since the information factor for the measurement period and frequency has a higher importance than other factors other than the information factor for age, the second largest weight is assigned, and the weight is sequentially applied according to the frequency of use, the degree of obesity, and the living environment. can be granted

In this way, in the similarity history search mode 130 of the server 100, an appropriate similarity history can be searched according to a result calculated based on the degree of matching between one's own history and another person's history and the weights of factors determining the corresponding degree of matching. there is. Only one similarity history may be searched, or each success case and failure case may be searched as needed. When similar histories to be compared are derived according to the execution of the similarity history search mode 130, the server 100 examines which direction the current self-history pattern approaches among success cases and failure cases to provide the current user with necessary information. A recommendation mode 140 for suggesting an amount of exercise, a diet, and the like is performed.

First, when the recommendation mode 140 is executed, the server 100 reviews the user's history pattern and compares it with success cases. Calculate the probability of success. In addition, the server 100 proposes a future specific health management schedule to the user based on the corresponding success probability. For example, the server 100 recommends information about other people's exercise amount, exercise method, diet menu, etc. based on success cases, and in particular, the diet menu can be linked to ordering and payment if necessary. Processes of the similarity history search mode 130 and the recommendation mode 140 are shown in more detail in FIGS. 4 and 5 .

Referring to the drawing, the server 100 performs a detailed analysis of the self-hysteresis through a self-hysteresis measurement mode 110 and an analysis mode 120 (S10). Then, the server 100 compares and analyzes the other person's history and the self-history to analyze the degree of agreement between the corresponding histories. In addition, weights are assigned to factors that determine the degree of agreement between the two histories, and similar histories that can be compared with the self-history are searched (S20). In order to find out whether the similar history derived through this process matches the self-history, a review is conducted by comparing the similar history with the self-history for a certain period of time (S30). After going through the corresponding review process, the server 100 determines whether or not the comparison result between histories falls within the error range (S40). If it is outside the error range, after resetting the degree of agreement between the two histories and the weight between the factors determining this degree of agreement, a process of re-searching similar histories is performed by returning to step S20.

If it is determined that the server 100 has searched for an appropriate similarity history to be compared with the self-history, the current self-history pattern is compared with the similarity history to calculate the user's goal achievement success probability (S50). Then, the server 100 activates the recommendation mode 140 to present a future health management schedule to increase the success rate (S60).

For example, the server 100 may implement a similar history recommendation mode 141 corresponding to a successful case. The similar history recommendation mode 141 may be a recommendation for another person's exercise method 142 or a diet plan 143. In addition, the server 100 may implement an appropriate lifestyle recommendation mode 145 based on the user's living environment. For example, in the case of an office worker or a salesperson who travels frequently, the lifestyle recommendation mode 145 includes activity 146 for each region suggesting the user's exercise program or a specific menu of each region restaurant suggesting the user's diet program ( 147) may be recommended.

The recommendation regarding the diet menu 143 may be made based on the user's current health condition by combining the user's body composition analysis result and the user's heart rate analysis result through the heart rate monitor. Specifically, when information on the current health status of the user is transmitted to the server 100 through the smart scale 10 and the heart rate monitor, the server 100 analyzes the data and recommends the most effective diet lunch box menu to the user. do. For example, if the body composition result is normal but the heartbeat is irregular, a diet lunchbox menu containing a lot of fiber required for heartbeat management may be recommended to the user.

When such a health care schedule recommendation is completed, the server 100 may link payment information in collaboration with a pre-affiliated company so that the user can immediately search for and pay for the diet menu 143, etc. (S70). In this way, as the server 100 recommends a menu to the user and links payment information for purchasing the corresponding menu, user convenience can be greatly improved.

When the use of the smart scale 10 is completed for a period set by the user according to the above process, the server 100 evaluates the user's history during the period, and if the user initially sets a health management goal A reward mode 150 providing an appropriate reward to the user according to whether the target is reached is activated.

The compensation mode 150 is a mode that is displayed when the user inputs an appropriate goal at the beginning of use of the smart scale 10, and the degree of compensation is determined according to the degree of achievement of the user's goal. This compensation mode 150 can increase the user's participation by providing motivation for health management to the user.

The progress of the compensation mode 150 is illustrated in detail in FIG. 6 . Referring to the figure, first, when a user generates a self-history using the smart scale 10 for a certain period of time, the server 100 searches for similar histories that can be compared with the self-history. Then, the server 100 calculates the user's health care target value through review of comparison between the self-history and the similar history (S100).

When the health management target value is calculated, the user sets a period for reaching the target value (S200). The target value reaching period may be arbitrarily selected by the user, but the server 100 may recommend a period that is not burdensome to the user's health. When this process is completed, the server 100 determines whether the goal provided to the user has been properly calculated (S300). To determine whether or not to calculate an appropriate goal, factors such as user's body composition analysis, heart rate analysis, environment analysis, similar history analysis, and goal achievement period analysis should be reviewed from various angles. If it is determined that the target value given to the user is not appropriate, the server 100 completely re-examines the similarity history and the target value reaching setting period (S310), returns to step S100, and calculates a new target value again based on the reviewed content. do.

On the other hand, if it is determined that the user is given an appropriate target value, the user inputs the self-hysteresis measurement time and measurement method through the smart scale 10 (S400), and the server 100 proceeds to the target during the target achievement period. It is always reviewed whether or not it is being processed (S500).

When the measurement period ends through such a process, the server 100 derives and analyzes the result value measured through the smart scale 10 and notifies the user of the result (S600). When the user's confirmation of the result is completed, the server 100 determines the degree of compensation according to the result value (S700). For example, if the calculated result achieves 50% of the initial target value, only 50% of the initial reward value is paid to the user. These rewards may be provided to users in various forms. For example, the user may be rewarded with a meal ticket for a linked diet meal in the recommendation mode 140, an activity voucher may be provided as another example, or a gym voucher may be provided as another example. When the awarding of these rewards is completed, all of the corresponding materials are converted into data and stored in the server 100 (S800). The stored data may be used as similar histories of others in the future.

As described above, according to the present invention, the user's health management can be performed more efficiently, and the user's participation and satisfaction can be greatly improved as appropriate motivation is provided to the user using the system. The above description of the present application is for illustrative purposes, and those skilled in the art will understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present application. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present application is indicated by the following claims rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof should be construed as being included in the scope of the present application.

Claims (1)

a smart scale 10 capable of recognizing a user's bio-signal and measuring body fat for each body part of the user;
An electronic device 200 that is interlocked with the smart scale 10 and allows a user to check the result value measured from the smart scale 10; and
It includes a server 100 that exchanges data with the smart scale 10 and the electronic device 200 and stores records related to the user's health management,
The server 100 includes a recommendation mode 140 for suggesting a health management program to the user by analyzing the user's current health condition,
The smart weight scale 10,
a handle 30 that can be gripped by a user;
a stepping plate 20 providing a foothold to recognize a user's bio-signal; and
A support 40 connecting the handle 30 and the step plate 20 to each other,
Sensing units 25 and 35 to which electrical stimulation is applied are formed on each of the handle 30 and the stepping plate 20 so as to measure the user's body fat using a bio-electrode impedance method.
The smart weight scale 10,
An 8-point touch electrode type weight scale in which four sensing parts 25 are formed on the handle 30 and four sensing parts 35 are formed on the stepping plate 20,
When the smart scale 10 is initially used, the smart scale 10 and the electronic device 200 are interlocked in a Bluetooth manner,
The server 100 converts the information about the user's bio-signal recognized by the smart scale 10 and the user's information input to the electronic device 200 into basic data and stores it,
After the initial use registration of the smart scale 10 is completed, when the smart scale 10 is connected to the Internet, new data newly measured by the smart scale 10 is transmitted to the server 100,
The server 100 converts the pre-stored basic data and the new data together and transmits them to the electronic device 200,
The server 100,
Self history measurement mode 110 for tracking and managing changes in the user's body when the user uses the smart weight scale 10 during a predetermined measurement period; and
Further comprising an analysis mode 120 for confirming a change pattern of the user's body based on the result value calculated in the self-hysteresis measurement mode 110,
The self-hysteresis measurement mode 110 is divided into regular measurement for measuring changes in the user's body at regular intervals and non-regular measurement for randomly measuring changes in the user's body within the predetermined measurement period,
The analysis mode 120 is divided into hourly analysis in which the user's body change pattern is analyzed by period, and space-by-space analysis in which the body change pattern is classified and analyzed by place.
The server 100,
A similarity history search mode for deriving a similarity history to be compared with the magnetic history based on the degree of matching with the magnetic hysteresis calculated in the self-hysteresis measuring mode 110 and the weight of the factor determining the degree of matching (130) and further
The factor considered in the similarity history search mode 130 is,
Information on the user's age, information on the measurement period of the smart scale 10, information on the frequency of use of the smart scale 10, information on the method for measuring changes in the user's body, and information on the user's living environment contain information about
The recommendation mode 140 uses the similarity history derived through the similarity history search mode 130 and the self-history measurement mode 110.
In preparation for the self-history of the current user measured through
The success story of the other person includes information about the diet menu 143 of the other person corresponding to the similar history,
The server 100,
After calculating the target value by comparing and reviewing the information on the current self-history and the information on the similarity history derived through the similarity history search mode 130, it is characterized in that it is determined whether the target value is reached during a certain period of time Healthcare system using smart scale.

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