KR101200061B1 - Exercise management system and exercise management method in the system - Google Patents

Abstract

The present invention relates to a sensor-integrated exercise management system and a method for managing exercise in the system. The present invention relates to a sensor-integrated exercise management system. Receive the measurement data according to the exercise result measured in the terminal in real time, save and process the received real-time measurement data as a file by date, perform the function of each mode for exercise management, and exercise history management program in the server By connecting with the terminal through, and receiving the terminal data characterized in that the data management and presenting the user's exercise target value, according to the present invention improves the accuracy and reliability of the measurement, reflecting the user's fitness and exercise effect Customize your workout by providing a set HR zone It is capable of providing effective.

Description

Sensor integrated exercise management system and exercise management method in system {Exercise management system and exercise management method in the system}

The present invention relates to a sensor-integrated exercise management system and a method for managing exercise in the system, and in particular, a sensor-integrated exercise for measuring exercise results using a sensor-integrated module and managing exercise history by estimating oxygen intake (VO2). A management system and a method for managing exercise in the system.

In recent years, interest in health has increased significantly for the happiness and joyful life along with the well-being fever, and accordingly, the importance of exercise for physical and mental health promotion and longevity has been highlighted.

In addition, in modern society, abnormal signals on health due to obesity, diabetes, cardiovascular disease and metabolic syndrome due to various food and exercise insufficiency are increasing. Therefore, modern people are striving to improve their health so that no abnormality occurs in their health through regular exercise.

As the interest in health increases, various scientific exercise management methods have recently been developed to improve health.

However, conventional exercise management methods are difficult to measure the results of exercise due to the expensive inspection equipment, there is a problem that the reliability is low due to the low risk or exercise measurement despite the high price. In addition, in the case of the existing commercial terminal, there is a problem of increasing the purchase price and the hassle of using an external additional sensor to measure the amount of exercise other than the heart rate. The exercise management method using a commercial terminal also does not use the oxygen intake used in the actual exercise prescription as an indicator of an individual's fitness or training effect and thus does not effectively reflect this, and thus does not provide a proper exercise management for an individual.

In order to solve the above problems, the present invention improves reliability by measuring the exercise result of the user through monitoring of the oxygen intake (VO2) and heart rate measurement, and integrates a sensor for performing exercise management through an exercise history management program. The present invention provides a management system and a method for managing exercise in the system.

In addition, the present invention provides a sensor-based exercise management system and exercise in the system for presenting the exercise target value by providing a heart rate (HR) zone set by reflecting the user's fitness and exercise effects for individual customized exercise management In providing a management method.

Sensor integrated exercise management system for achieving the object of the present invention, by measuring the biomarker and the amount of exercise through a single integrated sensor as a result of the exercise according to the user's exercise, and measure the exercise result every time A measurement device for transmitting the real-time measurement data according to the; A terminal configured to receive the real-time measurement data from the measuring device every predetermined time, estimate oxygen intake using the received real-time measurement data, and calculate energy consumption using the estimated oxygen intake; And analyzing and analyzing the real-time measurement data, the estimated oxygen intake, and the calculated energy consumption received from the terminal, displaying and storing the analyzed result, executing exercise prescription using the setting data and the analyzed result, and prescribing the exercise. It characterized in that it comprises a server for transmitting a result for the terminal.

In addition, the terminal of the sensor-integrated exercise management system for achieving the objects of the present invention, the transceiver comprising: a transceiver for receiving the real-time measurement data from the measurement device, and exchanges data for exercise management with the server; And a controller configured to process the received real-time measurement data, estimate the oxygen intake, calculate the energy consumption, and perform a mode-specific function for exercise management. And a storage unit for storing the data for the exercise management, wherein the information input unit receives the setting data and the information on the mode selection for the exercise management from the user who starts the exercise. And displaying a real-time parameter, a lap-specific parameter, a memory (storage space) remaining amount and a warning message of the storage unit, and a display unit for monitoring for exercise management.

In addition, the exercise management method in a sensor-integrated exercise management system for achieving the objects of the present invention, connecting the exercise history management program to perform a set mode function and exercise mode function; When the user starts the exercise, receiving real-time measurement data measured according to the exercise result of the user every predetermined time; Estimating a real-time oxygen intake amount using the real-time measurement data; Calculating energy consumption using the estimated oxygen intake; And displaying and storing the estimated oxygen intake and the calculated energy consumption.

In addition, the exercise management method in the sensor-integrated exercise management system for achieving the objects of the present invention, the automatic heart rate zone and each lap exercise time setting according to the exercise prescription result, and storing the result of the automatic setting ; Performing a test mode function of testing Rest heart rate, maximum oxygen uptake (VO2max) and anoxic threshold (AT), and automatically displaying and storing the results obtained through the test; Performing a file management mode function of selecting a corresponding file from a list of files by date stored and summarizing deletion or exercise information; Processing the real-time measurement data and storing the processed data and the real-time measurement data in a file for each date; And displaying a real-time parameter, a lap-specific parameter and a memory (storage space) remaining amount, and a warning message, and performing a new member registration of the user through the exercise history management program. The method may further include testing the user through a test using a prescription algorithm.

The present invention estimates the oxygen intake of the measurement data according to the exercise result of the user and calculates the energy consumption by unit conversion of the oxygen intake, thereby improving the accuracy and reliability of the exercise result measurement, and through the on-offline linked content It is effective to provide various additional functions.

In addition, the present invention can reduce the cost by applying an integrated sensor module to simplify the measurement device, and has the effect of providing a customized exercise management to the user by presenting the exercise target value reflecting the user's fitness and exercise effect .

1 is a view showing the structure of a sensor integrated exercise management system according to an embodiment of the present invention,
2 is a view showing a specific structure of a measuring device in a sensor integrated exercise management system according to an embodiment of the present invention,
3 is a diagram illustrating a new member registration procedure in a sensor-integrated exercise management system according to an embodiment of the present invention;
4 is a diagram illustrating a method for exercise management in a sensor integrated exercise management system according to an embodiment of the present invention;
5 is a diagram illustrating a terminal and a server connection procedure according to an embodiment of the present invention;
6 is a diagram illustrating performance of a set mode function in a terminal according to an embodiment of the present invention;
7 is a view showing an exercise mode function performed in a terminal according to an embodiment of the present invention;
8 is a diagram illustrating file management mode function execution in a terminal according to an embodiment of the present invention;
9 illustrates a data management procedure in a server according to an embodiment of the present invention;
10 is a diagram illustrating an exercise goal presentation procedure in a server according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In describing the present invention in detail with reference to the accompanying drawings, preferred embodiments of the present invention, when it is determined that the detailed description of the related known functions or configurations may unnecessarily obscure the subject matter of the present invention Omit the description.

The same reference numerals are used for portions having similar functions and functions throughout the drawings.

In addition, throughout the specification, when a part is 'connected' to another part, it is not only 'directly connected' but also 'indirectly connected' with another element in between. Include. In addition, the term 'comprising' a certain component means that the component may be further included, without excluding the other component unless specifically stated otherwise.

Next, a structure of a sensor-integrated exercise management system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the structure of a sensor integrated exercise management system according to an embodiment of the present invention.

Referring to FIG. 1, the sensor-integrated exercise management system may be largely configured as a measuring device 110, a terminal 120, and a server 130.

The measuring device 110 is an integrated sensor module of an HRM sensor and an SDM sensor that can be attached to a user's body. For example, the measuring device may be configured as a chest belt type sensor module as shown in FIG. 2. The chest belt type sensor module includes sensors 111 to be attached to the left and right chests, an amplifier 112, a band stop filter (Notch Fiter (60Hz)) 113, and a low-pass filter. 114, Reference Voltage 115, Analog Comparator 116, Microcontroller 117 and 2.4CHz RF Transceiver 118 and Battery Charger / Power Supply) 119 can be configured. The chest belt type sensor module may further include a GPS and a temperature sensor. Functions of the respective components of the chest belt type sensor module are generally well known, and a detailed description thereof will be omitted.

The measuring device 110 measures the user's exercise result and transmits the measurement data according to the measured exercise result to the terminal 120 at a predetermined period (for example, every second). The measurement data may include heart rate (HR), exercise speed, exercise distance, exercise time, body temperature, and the like.

As shown in FIG. 1, the terminal 120 includes a transceiver 121, an information input unit 122, a controller 123, a storage unit 124, a display unit 125, a power supply unit 126, and a real time clock. (Real Time Clock) 127 can be configured, and can be configured by applying a mobile device and a clock.

The transmitter / receiver 121 receives measurement data such as heart rate, exercise speed, exercise distance, exercise time, and the like from the measuring device 110 at a predetermined time unit (for example, every second), and sets the server 130 from the server 130. The data is received, and the processed measurement data, setting data, test result data, and the like are transmitted to the server 130. The transceiver 121 may use a 2.4CHz RF transceiver.

The information input unit 122 receives user setting data from a user. Here, the setting data includes user information such as name, age, gender, height, and weight, heart rate (HR) zone, lap, and watch function related information. The information input unit 122 may apply a keypad, a touch pad, a USB, or the like.

The controller 123 estimates the oxygen intake VO2 using the received measurement data and calculates the energy consumption in real time by converting the estimated oxygen intake unit (using a 1 L / min ≒ 5 kcal / min formula). Here, the VO2 estimation estimates the oxygen intake (VO2 (t)) over time by measuring the heart rate that changes with the exercise load and the amount of exercise, and uses the linear proportional relationship between the HR and the oxygen intake (VO2). Alternatively, it is possible to estimate in real time during the exercise by using the heart rate measured during the exercise and the user's body information and physical fitness information.

The controller 124 presets each mode function (test mode, exercise mode, file management mode, setting mode, server connection mode, etc.) necessary for exercise management to perform functions for each mode. Perform the configured additional service function. The additional service functions here include automatic / manual HR zone setting, maximum heart rate (HRmax) calculation, maximum heart rate (% HRmax) calculation, target HR zone alarm, exercise lap designation, and metronome function (constant speed with beep in the field). Function for road control), Functions such as body surface area (hereinafter referred to as BSA) calculation and body mass index (hereinafter referred to as BMI) calculation. In addition, the control unit 123 provides a clock button locking function to prevent malfunction due to movement during the exercise, and performing the function and the additional service function for each mode will be described in detail in the exercise management method.

The controller 123 generates the average data or the display data for each lap by processing the received measurement data, stores the generated data in the generated data storage unit 124, and connects to the server 130 to exchange data.

The controller 123 generates a warning message and a warning alarm when the storage space reaches 90% or more after the last exercise type, measures an exercise time, and performs an information display function and illumination through a clock measurement. Here, the information display function displays the current time, date, day of the week, and battery capacity, and the illumination function is a function of turning on the LCD light for about 20 seconds when the illumination button next to the clock is pressed.

The storage unit 124 stores data for exercise management, such as measured data, calculated energy consumption, configuration data, BMI / BSA data, processed data, additional service data, configuration data, and test result data.

The display unit 125 displays real-time parameters (measured data such as heart rate, exercise distance, exercise speed, exercise time, and energy consumption), and displays parameters per lap and the memo (storage space) remaining amount and warning message of the storage unit 124. do. Here, the real-time parameters display the heart rate and the exercise speed once per second, the data for the measurement at the moment, the exercise distance and the exercise time once per second, and the accumulated data since the start of the exercise. do. In addition, the display unit 125 displays the current time, date, day of the week, and the battery capacity of the terminal 120 before the start of the exercise.

The server 130 provides an exercise history management program, and connects the terminal 120 with the exercise history management program to exchange data, display and store real-time measurement data, analyze data by date, and display the analyzed data. It stores and provides a screen for new member registration and a screen for suggesting exercise target values. Data exchanged here will be described in detail later in the exercise management method description.

The server 130 may display and analyze and store a result of performing the test mode function, and receive user setting data, which is user information, from the user as in the terminal 120. 120), set a manual exercise plan and save the set data. In addition, the server 130 provides a professional exercise-related data / expert Q & A / recommended diet and exercise information sharing community between members through a web linkage, and can do lifestyle questionnaire and data storage.

The exercise management method through VO2 monitoring in the sensor integrated exercise management system according to the embodiment of the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, as shown in the accompanying FIG. 3, the user registers as a new member through the exercise history management program preset in the server 130 for his exercise management. At this time, the user inputs his user information, name, ID (ID), password (PW), age, gender, height and weight, and clicks Register and confirms the input contents in the next screen. Then click Finish to complete the membership process. This member information can be modified from time to time, age / height / weight is updated on the program is transmitted to the terminal 120. Accordingly, the terminal 120 updates the user information stored therein through the received data.

When the user starts exercising after the membership is completed, the user measures the exercise result through the measuring device 110 of the sensor-integrated exercise management system, and manages the exercise using the measurement data of the exercise result measured by the terminal 120. Will be performed. The method for such exercise management will be described in more detail as follows.

4 is a diagram illustrating a method for exercise management in a sensor integrated exercise management system according to an embodiment of the present invention.

Referring to FIG. 4, in step 201, the terminal 120 connects a workout history management program preset to the server 130. Here, looking at the process (connection UI) for connecting the terminal 120 and the server 130, as shown in Figure 5, the user's ID and password to enter the exercise history management program, the user connects the terminal When the button is clicked, the terminal 120 and the server 130 are connected after confirmation on the user confirmation screen so that the terminal 120 can receive data from the server 130.

In step 202, the terminal 120 receives user setting data, which is user information, and performs a setting mode function as shown in FIG. 6, that is, user information setting, lap designation, and clock setting through a manual setting function. Perform. At this time, the terminal 120 stores the set data (user information (age, height, weight), manual HR zone range (start and end), heart rate data (beat / min), each lap exercise time) The setting data is stored in the unit 124 and the setting data is updated by exchanging setting data with the server 130. Here, the clock setting sets the date, the day of the week, and the time, and the heart rate zone setting may be divided into automatic or manual heart rate zone (HR Zone 1, 2, 3) settings.

In step 203, it is checked whether there is an input for selecting a workout mode by a user. If there is a selection result as a result of the check, in step 204, the terminal 120 performs the exercise mode function as shown in FIG. That is, the user selects an exercise (treadmill, bicycle, field, or other exercise), selects whether to use a metronome, a free exercise or a heart rate zone exercise, and then decides whether to set a lap. Then, the terminal 120 sets the heart rate zone and the lap setting according to the user's selection, and stores the set data in the storage unit 124. On the other hand, if there is no selection input, step 203 is performed again.

After determining the exercise mode selection, when the user starts the exercise, the exercise time is measured and stored in step 205, and in step 206, the terminal 120 receives real-time measurement data every predetermined time (for example, every 1 second). The received real-time measurement data is displayed and stored, and stored as a file for each date or processed into display data for each average / lap and the processed data is stored in the storage unit 125. In step 207, the terminal 120 transmits the measured exercise time, real-time measurement data, and processed data to the server 130 every second.

 Estimating oxygen intake (VO2) every minute using the measured data (HR and user information (age / key / weight)) received in step 208, and calculating energy consumption in real time using the estimated VO2, and estimating The calculated VO2 and the calculated energy consumption data are stored in the storage unit 124. In step 209, the terminal 120 transmits information of the estimated VO 2 and the calculated energy consumption to the server 130. Information of the estimated VO2 and the calculated energy consumption is transmitted every time (eg every minute). Accordingly, the server 130 analyzes the received measurement data and the estimated VO2 and the calculated energy consumption, displays and stores the analyzed measurement data, and displays and analyzes the measured time and the total exercise time data for each measurement data. do. In addition, the server 130 presents the exercise target value of the user (exercise prescription) using the analyzed data, and transmits the exercise prescription result according to the exercise target value to the terminal 120.

In step 210, the terminal 120 receives the exercise prescription result from the server 130 and executes automatic setting execution and sets data (auto HR zone / Lap) by the exercise prescription.

Thereafter, in step 211, the terminal 120 checks whether the test mode function is selected by the user, and if there is a selection, performs the step 212, and if not, performs the step 205 again.

In step 212, the terminal 120 performs a test mode function, that is, a rest HR test, a maximum oxygen intake (VO2max) test, and an anaerobic threshold (AT) measurement test, and stores a test mode function execution result and a server. Send to 130. Accordingly, the server 130 analyzes the received test result and displays and stores the analyzed result. If the user selects the resting heart rate test, the terminal 120 checks the resting heart rate measurement posture (sitting in a chair or standing in a calm position), measures the heart rate for 1 minute, and then averages the resting heart rate for 1 minute. The data is stored in the storage unit 124 as data. Next, when the user selects the VO2max test, the terminal 120 performs the designated exercise protocol, and estimates VO2max using the measured heart rate and user information (body information). That is, the terminal 120 estimates the height, weight and age, and the BMI and HRmax (220-age) obtained by the calculation equation, using the constant speed / lower-level sub-maximal exercise protocol. After walking / running / biking of the program, convert the measured heart rate, calculate the VO2max using the converted heart rate (HRR, Steady-State HR,% HRR), and display the result. And store. Here, VO2max can be obtained by using a regression equation with height, weight, BMI, HRmax, HRR, Steady-State HR, and% HRR as variables. Finally, if the user selects the AT measurement test, the terminal 120 performs the designated exercise protocol using the sub-maximal exercise protocol, and estimates the AT using the measured heart rate and the user information (body information). That is, the terminal 120 is a VO2max obtained through a simple fitness test, directly input height and weight, BMI (weight (kg) / height (m ² ) and BSA ((Height (cm) * Weight (kg)) by the formula / 3600) ^1/2 ) as input, select the exercise mode, convert HR, calculate AT using the converted HR (HRR, Steady-State HR,% HRR), and display and save the result. Here, AT can be obtained by using a regression equation with height, weight, BMI, BSA, VO2max, HRR, Steady-State HR, and% HRR as variables, and the test mode displays the date, day, and test results on the screen.

Thereafter, in step 213, the terminal 120 checks whether there is a file management mode selection, and if there is a mode selection, performs step 214; otherwise, performs step 213 again.

As illustrated in FIG. 9, the terminal 120 performs a file management mode function such as selecting a file from a file list by date and deleting the file or viewing a summary of exercise information.

In operation 215, the terminal 120 transmits terminal data according to the file management mode function to the server 130. In this case, the terminal data includes test result data (test specific date / day, test measurement data by date (Rest HR, VO2max, AT), exercise data by date, setting data (manual HR zone 1/2/3 range, user setting data) Age / height / weight, etc. The date-based exercise data includes real-time measurement data (HR, exercise time, exercise speed, body temperature, total exercise distance, energy consumption) and average data per lap (average HR) measured during the exercise. , Average exercise speed, average body temperature, total exercise time, total energy consumption), HR zone exercise time / excess time, user setting information, etc. HR zone exercise time / time under time is configured on the terminal 120. It is not displayed but is used for a target alarm, but stores the time when the alarm sounds and transmits the data to the server 130 to calculate the time to visualize the data.

Accordingly, the server 130 uses real-time measurement data among the received server data for displaying a graph, and as shown in FIG. 9, when a user clicks a data management function, a program execution date is displayed on the first screen. The brief data list of 'Month' corresponding to is displayed first, and if you click the list by each date, the screen is composed so that you can see the data graph by time / date of each relevant date in detail. If you press the button next to the graph, you can check the data related graph.

In addition, the server 130 may configure an exercise prescription algorithm in consideration of the user's fitness and exercise effect stored in the DB (not shown), and may provide the exercise target value to the user as a result. For example, as shown in FIG. 10, when the user clicks on the exercise prescription on the screen of the exercise history management program displayed on the server 130, the server 130 may set a goal-based exercise prescription, recommended diet, and recommended life. Provides a screen showing habits and the like. When the user clicks on the exercise prescription for each target on the screen, the server 130 provides a screen for the exercise purpose, and when the user clicks the exercise purpose menu, the server 130 provides an exercise prescription result screen. Thereafter, the server 130 transmits data for the HR zone (manual HR zone 1/2/3 and automatic HR zone) to the terminal 120. In addition, the server 130 transmits user setting data when the terminal 120 performs the setting mode function.

In addition to such functions, the server 130 may provide expert coaching and community functions. For example, a simple coaching memo may provide a coaching memo through analysis such as fitness improvement / decrease rate by using a result of VO2max / AT in data management. In addition, it is possible to provide exercise coaching function through exercise prescription, and to provide exercise information sharing community among members through exercise related material, expert Q & A, recommendation diet, and web linking of other experts.

On the other hand, in the detailed description of the present invention has been described with respect to specific embodiments, various modifications are possible without departing from the scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

110: measuring device 120: terminal
121: transceiver 122: information input unit
123: control unit 124: storage unit
125: display unit 126: power supply unit
127: real time clock 130: server

Claims (26)

A measurement device for measuring a biomarker and an exercise amount through a single integrated sensor as a result of exercise according to a user's exercise, and transmitting real-time measurement data according to the exercise result measured at a predetermined time;
A terminal configured to receive the real-time measurement data from the measuring device every predetermined time, estimate oxygen intake using the received real-time measurement data, and calculate energy consumption using the estimated oxygen intake; And
Analyzes real-time measured data received from the terminal, estimated oxygen intake and calculated energy consumption, and displays and stores the analyzed result, executes exercise prescription using setting data and the analyzed result, and executes the exercise prescription. It includes a server for transmitting a result for the terminal,
The terminal receives the real-time measurement data from the measurement device, and a transceiver for exchanging data for exercise management with the server, processing the received real-time measurement data, estimates the oxygen intake and the energy consumption amount Comprising a control unit for performing a mode-specific function for exercise management and a storage for storing the data for the exercise management,
The controller performs a function of a test mode, an exercise mode, a file management mode, a setting mode, and a server connection mode as a mode for managing the exercise.
The control unit, in the test mode, performs a rest heart rate test, a maximum oxygen intake (VO2max) test and an anaerobic threshold (AT) test, and controls to automatically display and store the results obtained through the test,
The control unit may provide a maximum heart rate (HRmax) and body mass index (BMI) calculated by setting data, an additional service function, and a constant speed / sub-maximal exercise protocol during the maximum oxygen intake test. The maximum oxygen uptake test is performed by calculating the maximum oxygen uptake by displaying the heart rate measured during the exercise as a variable and displaying the result, and the maximum oxygen uptake and body mass index (BMI) calculated as an additional service function when the anaerobic threshold test is performed. And an anaerobic threshold (AT) test using a variable body surface area (BSA), and heart rate measured during exercise performed by providing setting data and submaximal exercise protocol.
delete The terminal according to claim 1,
An information input unit configured to receive setting data and information on mode selection for exercise management from a user who starts an exercise; And
And a display unit configured to display the real-time measurement data, the oxygen intake amount, the energy consumption amount, the remaining amount of memory (storage space) and a warning message, and to monitor for exercise management. Management system.
The method of claim 1,
The control unit
Sensor integrated exercise management system, characterized in that for estimating the oxygen intake using the user information included in the heart rate and the setting data included in the real-time measurement data.
delete delete The method of claim 1,
The controller may perform the resting heart rate test by storing an average resting heart rate obtained by measuring a heart rate for a predetermined time according to a resting heart rate measurement posture, when the resting heart rate test is performed.
delete delete The method of claim 1,
The control unit
The exercise mode function, the sensor integrated exercise management system, characterized in that the user performs a function for selecting the exercise type, heart rate zone (HR zone), Lap setting before the start of exercise.
The method of claim 1,
The control unit
Sensor setting integrated motion management system characterized in that the setting mode function to perform the clock setting including the date, day, time, manual and automatic heart rate zone (HR zone) setting, the user setting using the user setting data input from the user.
The method of claim 1,
The data for exercise management include the real time measurement data, the setting data, processed data, the estimated oxygen intake, the calculated energy consumption, the measured exercise time, and the test result data performed in the test mode. Sensor integrated exercise management system.
The method of claim 10,
The real-time measurement data includes the measured heart rate, distance traveled, exercise speed and body temperature. delete delete delete delete delete delete delete delete delete delete delete delete delete

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