RU2733870C1 - Method of training process organization and system for its implementation - Google Patents

Abstract

FIELD: sports.

SUBSTANCE: group of inventions relates to sports equipment, namely to sports and medical systems with possibility of monitoring the functional state of a person during a training process. Disclosed invention can be used to solve tasks to provide control, selection of tactics and algorithm of training based on physical capabilities and physiological parameters of user, as well as for efficient and safe arrangement of training process for any categories of users. Method of training process organization includes user identification, preliminary measurement of static physiological parameters of user using measuring bench, collection and processing of obtained data, automatic generation of training algorithm based on results of processing obtained data, periodic measurement of dynamic physiological parameters of a user during execution of a training algorithm using at least one wearable device. Prior to automatic composition of training algorithm user selects training purpose. During the user's training algorithm execution by means of the portable device, the user's dynamic indicators are periodically analyzed and based on the analysis it is offered to the user to return to the measurement stand, and whether to proceed to the next task of the training algorithm, including on the next exercise machine, or stop the training algorithm execution, including due to automatic shutdown of the exercise machine in case of exceeding the threshold values of the user's dynamic physiological indices and notification of the user; according to the results of measurements and analysis of dynamic physiological parameters carried by the portable device, the training algorithm is automatically corrected. Also disclosed is a system for organizing a training process.

EFFECT: technical result consists in improvement of efficiency and safety of training process.

2 cl, 1 dwg

Description

The group of inventions relates to sports equipment, namely to sports and medical complexes with the ability to monitor the functional state of a person during the training process. The claimed inventions can be used to solve problems to ensure control, the choice of tactics and training algorithm based on the user's physical capabilities and physiological parameters, as well as for efficient and safe building of the training process for any categories of users.

A system for automatic regulation of sports loads is known from the prior art, which includes a sensor that captures quantitative indicators of the athlete's muscle fluctuation, a muscle fatigue detection unit and at least one exercise machine equipped with an electronic load control device associated with the muscle fatigue detection unit. Measurement information is transmitted wired or wirelessly to the information processing and storage unit. The block for processing and storing information uses the correlation between the parameters of the natural oscillations of the muscle and the state of its performance and has the ability to automatically generate and transmit a control command to the actuator for regulating the load of the simulator [Patent for utility model No. RU118869, publication date 10.08.2012].

Also known from the prior art is an interactive simulator with a monitoring system containing a bicycle ergometer, a personal computer, which includes an operator monitor and a system unit equipped with a program. Also, the interactive simulator is equipped with a user monitor and a program that can analyze user data and issue an opinion with an individual health program, recommendations for the training process and physiotherapy. The body of the bicycle ergometer is made in the form of a figured frame with a seat mounted on top, the lower part of the frame is indirectly connected to the bioimpedance plate for the legs and the base on which the bicycle ergometer loading mechanism is fixed, and on both sides of it with fixed connecting rods, each of the latter is connected to one of the pedals. In addition, a stand is fixed in the upper part of the body for attaching the user's monitor, while the simulator is equipped with a bioimpedance, pulse oximeter, tonometer, hypoxic generator equipped with a helmet or mask in which a hypoxic environment is created, a spirometer, a dynamometer, connected indirectly to the system unit [Patent for invention No. RU 2624874, publication date 10.08.2012].

The disadvantage of this invention is the lack of constructive capabilities of this system for the implementation of the complete training process.

The closest analogue of the claimed invention is a method and device for interactive monitoring of exercise, sports or fitness using a wearable device such as a watch, glasses or smart clothes. The device is equipped with or connected to a digital camera. Sensors built into or connected wirelessly to a wireless wearable Internet device record the user's physiological data during exercise and the amount of exercise performed. The data and visual images from the camera are transmitted to one or more Internet servers and can be transmitted to other mobile Internet devices. The system for monitoring exercise data from the patient includes a wireless exercise monitoring device, which includes an HMD connected to the server and the user device WID and encompassing not only devices with physiological data and exercise data, but also devices with keyboard, mouse , touch screen, pointer, pressure sensor, or other such inputs that the user can use to enter data or desired parameters. To obtain physiological data, HMD can be a heart rate or blood pressure meter, an outpatient ECG recorder, a respiration meter, a temperature meter, and so on [Application for invention No. US 2018207482, publication date 07/26/2018].

The disadvantage of the closest analogue is the lack of the possibility of building and adjusting the complete training process without the participation of a specialist, such as a trainer or medical worker.

The technical problem to be solved by the claimed group of inventions is the inability to automate the organization of the training process depending on the specific training goals, training algorithm tasks and dynamic parameters of the user without the participation of a specialist such as a trainer or a medical worker.

The technical result consists in increasing the efficiency and safety of the training process.

The essence of the proposed method of organizing the training process.

The method of organizing the training process includes user identification, preliminary measurement of the user's static physiological parameters using a measuring stand, collection and processing of the data obtained, automatic compilation of a training algorithm based on the results of processing the obtained data, periodic measurement of the user's dynamic physiological parameters during the execution of the training algorithm with using at least one wearable device. Unlike the closest analogue, before the automatic compilation of the training algorithm, the user selects the training goal, during the execution of the training algorithm by the wearable device, the user's dynamic indicators are periodically analyzed and, based on the analysis, the user is prompted to return to the measuring stand, or proceed to the next task of the training algorithm , including on the next simulator, or stop the execution of the training algorithm, including due to the automatic stop of the simulator in case of exceeding the threshold values of the user's dynamic physiological parameters and notifying the user about this. Based on the results of the measurements and the analysis of dynamic physiological indicators, the training algorithm is automatically adjusted.

A training algorithm means a set of exercises and tasks with a certain sequence. Additionally, in order to maximize the effectiveness of the training process, the method may include compiling a complete training process, which is a continuous training program, that is, a set of training algorithms aimed at achieving certain sports goals. After completing the execution of the training algorithm without forced automatic stop of the equipment, the user may be offered to undergo a study on the measuring stand. In this case, according to the results of the performed training algorithm, based on the measurements carried out on the measuring stand and the analysis of dynamic indicators in the process of performing the training algorithm, as well as taking into account the retrospective trends and indicators of previous training periods and measurements, the complete training process is automatically corrected.

The interaction of system units, user identification, transmission and processing of information can be controlled using a control unit capable of collecting, storing, processing and transmitting data from at least one wearable device, a measuring stand and training equipment. Synchronization of system units and collection, transmission and processing of data can be carried out using the mobile Internet, or an Internet connection via a WiFi access point, or a local network connection.

User identification can be carried out in any way known from the prior art, for example, by creating a user cabinet and subsequent authorization in it through the software of the measuring stand and training equipment. Authorization can be carried out by entering user data or through a wearable device with a wireless connection, for example, NFC, or through a smartphone with a wireless connection, for example, bluetooth, while data about the user and his training algorithm or complete information is transmitted to the measuring stand or training equipment. the training process.

The measuring stand can measure the following static physiological parameters of the user, namely: three-lead ECG, calculation of cardiography using the heart rate variability method, volume and composition of inhaled and exhaled air, heart rate, blood pressure, biomechanical indicators of symmetry of the musculoskeletal system, condition joints, assessment of the mobility of the main large joints, the level of the user's general metabolism, assessment of the activity of the body's regulatory systems at the MC-7 point, measurement of water and fat balance, body weight and height, analysis of the musculoskeletal system using machine vision technology, etc. The measurement results are saved in the database of the system control module and displayed in the user cabinet. The process of measuring static physiological parameters on a measuring stand may additionally include passing a questionnaire by the user to clarify the characteristics of the health status, gender, age of the user.

Automatic compilation of a training algorithm can be carried out using any mathematical and algorithmic methods known from the prior art, for example, methods created on the basis of biostatistics of physiological indicators and their correlation with the training process using an artificial neural network for differentiated diagnostics of states in the form of comparison with patterns ( patterns) of states and their changes. Based on the results of the studies carried out on the measuring stand, the permissible limits of dynamic physiological indicators for each user are also determined, based on which the implementation of the training algorithm is monitored, in addition, the recovery limits of the intervals for each user after loads can be determined.

Measurement of dynamic physiological indicators during the entire training process can be carried out using a wearable device with pulse oximetry and heart rate sensor functions. Additionally, during the training process, the analysis of the state of the cardio system can be carried out using a wearable cardio sensor.

The goal of the training algorithm or the complete training process is set in the following areas: building muscle mass, fat burning, functional and rehabilitation regimens, or special-purpose regimes such as regimens for various diseases, for example, diabetes or other diseases of the metabolism and endocrine system, or regimes training of professional athletes.

The automatic stop of the training equipment can be carried out by means of a command coming from the wearable device when the threshold values of the indicators are exceeded, with the prior notification of the user about this. Notification of the user can be carried out in any way known from the prior art, for example, by means of an audio or vibration signal or a pop-up notification on a wearable device.

The essence of the system for the implementation of the method of organizing the training process.

The system for organizing the training process contains a measuring stand with diagnostic modules for measuring static physiological indicators of the user, a system control module with the ability to store and process information, at least one wearable device containing a module for measuring dynamic physiological indicators of the user, and training equipment. Unlike the closest analogue, the training equipment is equipped with data synchronization and user identification modules, while the wearable device contains modules for analyzing periodically measured dynamic parameters of the user, synchronizing with the system control module, training equipment and measuring bench, controlling training equipment and notifying the user about the need to return to the measuring stand, or go to the next task of the training algorithm, including on the next simulator, or stop the training algorithm, while the training equipment is a cardio and / or strength training machine.

The system control module with the ability to store and process information provides data collection from a wearable device, training equipment and their processing for drawing up a training algorithm, as well as adjusting the training algorithm based on the results of the analysis of the user's dynamic physiological parameters measured by the wearable device. The system control module contains software that combines all the elements into a single system, as well as a database that contains information about the user. Access to user information in the database is provided through a measuring stand, wearable device, application on a mobile device, or training equipment. The database can be placed on a server in the local network or in cloud storage.

The measuring stand is a unified integration engineering analytical platform. An integrated analytical engineering platform means software that allows you to connect different platforms and applications through a single interface, in particular, various diagnostic modules with independent software. The measuring stand can include the following diagnostic modules: capnography module, pulse oximeter, non-invasive glucometer, spirometer, one-lead ECG module (heart rate variability method); a module for assessing the activity of the body's regulatory systems at the MC-7 point, a module for analyzing data on the biochemical composition of blood, a module for measuring water-fat balance, body weight and growth, a module for analyzing the musculoskeletal system using machine vision technology and any other diagnostic modules that provide the ability an objective assessment of the user's condition for drawing up a training algorithm or a complete training process.

A wearable device can be any known accessory or several accessories located on the user's body and providing data exchange with the Internet and other devices, for example, a smart watch, a fitness bracelet or a body sensor. The module for measuring the dynamic parameters of the user of the wearable device may contain any sensors known from the prior art, for example, a heart rate sensor and pulse oximetry. The analysis module allows the wearable device to automatically collect, store and process measurement data of the user's dynamic physiological parameters. The synchronization module makes it possible to identify the user on the training equipment and the measuring bench using any known from the prior art wireless technology, for example, bluetooth or NFC, and also provides data transmission and reception from the database of the system control module via a local or mobile network. The training equipment control module provides the ability to transmit a command to the training equipment to stop it when the threshold values of dynamic physiological indicators are exceeded. The user notification module makes it possible to automatically generate, based on the analysis of the performed measurements, the dynamic parameters of the physiological user and transmit to the user recommendations on the need to stop the training algorithm and return the user to the measuring stand for additional measurements, or proceed to the next stage of the training algorithm, including the next simulator. Notifications can be implemented in any manner known in the art, such as beeps or toast notifications. Additionally, the synchronization module of the wearable device can provide synchronization with a mobile application for connecting additional capabilities, for example, measuring and analyzing sleep indicators, generating dietary recommendations and monitoring their compliance, monitoring daily activity, etc.

The training equipment can be represented by a single simulator or a set of simulators, compiled depending on the complexity and purpose of the training algorithm, and it can be any cardio and / or strength training simulators known from the prior art, combined to perform a specific training algorithm. The data synchronization module provides transmission and reception of user data from the database of the system control module via a local or mobile network. The training equipment user identification module can be executed in any way known from the prior art, for example, in the form of a digital display for entering user data or an NFC module for automatic synchronization via wireless connection with a wearable device. The simulators can have automatic settings for the anatomical features of the user, taking into account ergonomic norms and biomechanics, automatic settings for the load level, and automatic shutdown. Additionally, the training equipment can have a module for automatically notifying the user about the subsequent interruption of the training algorithm. Additionally, training equipment can be represented by any non-automated sports equipment, in this case the process of user identification on the simulator is excluded.

The set of simulators can be configured to be combined into a local network, which provides the ability to centrally monitor the training process of users, as well as to effectively redistribute users in accordance with their programs in case of increased load when using the system in a sports institution.

Additionally, the system may include a mobile application synchronized with user data in the database of the system management module to connect additional capabilities, for example, measuring and analyzing sleep indicators, generating and monitoring compliance with dietary recommendations, monitoring daily activity, etc. The mobile application can be accessed via a tablet or smartphone.

Thus, the claimed method and system are characterized by new, previously unknown from the available sources of information, essential features. The use of the above-described technical solutions provides an increase in the efficiency of control of the training process in real time, that is, in accordance with the change in the user's functional characteristics during the entire training process, which in turn provides the most reliable predicted result for the user. At the same time, the claimed inventions provide an increase in the safety of the training process due to the automation of several functions of the system simultaneously for the implementation of the proposed method, while increasing the user's involvement in the training process, which also has a positive effect on the result. This makes it possible to solve the problem of organizing the training process without the participation of a medical worker or trainer due to the implementation of wearable devices with the ability to automatically generate recommendations for the user about the sequence of the training algorithm tasks and the subsequent automatic adjustment of the training process and the operation of training equipment in the proposed system. Thus, the user receives complete information about training and his condition in statistical trends and in real time. All of the above allows us to conclude that the claimed invention meets the criteria of patentability of "novelty" and "inventive step".

The claimed invention can be made by known methods from known materials, which ensures its compliance with the criterion of patentability "industrial applicability".

The claimed method and system meet the requirement of "unity of invention", since it is such an implementation of the system that ensures the implementation of this method. The stated technical solutions are aimed at achieving the same technical result to improve the efficiency and safety of the training process.

The claimed group of inventions is illustrated by the following drawings.

Figure: 1 is a functional diagram.

The system for organizing the training process contains a measuring stand 1 with diagnostic modules for measuring the user's static physiological indicators, a system control module 2 with a database 3, a smart watch 4 containing a module for measuring the user's dynamic physiological indicators, a wearable cardio sensor 5, a smartphone with a mobile application 6 , as well as cardio and strength training equipment 7, united in a local network. Each of the simulators 7 is equipped with an NFC module for user identification (not shown in the drawings) and a module for notifying the user about the interruption of the training algorithm, while the smart watch 4 contains modules for analyzing periodically measured dynamic parameters of the user, synchronizing with the system control module 2 with the database 3 , cardio and strength training equipment 7 and measuring stand 1, control training equipment 7 and notifying the user about the need to return to measuring stand 1, or go to the next task of the training algorithm, including on the next simulator 7, or stop the training algorithm.

The principle of operation of the claimed group of inventions is as follows.

The user creates an office 8 by means of a smartphone with a mobile application 6, after which he is identified at the measuring stand 1 by entering data. The user undergoes research on the measuring stand 1 and a survey to clarify the characteristics of health, the measuring stand 1 transmits the obtained data about the user to the database 3 of the system control module 2, which processes the information and stores the user data. The user selects the training goal, after which the system control module 2 forms a complete training process program in the user office and transfers it to the database 3, from where the information is transmitted to the simulators 7 and displayed in the smartphone with the mobile application 6. Smart watch 4 and body-worn heart rate sensor 5 connect to a smartphone to sync data. The user is authenticated on the simulator 7 by means of a smart watch 4 and a user identification module on the simulator 7 (not shown in the drawings), the control signal via the NFC module starts the necessary program on the simulator 7, and the user starts exercising within the program or resumes the workout according to previously created program. The user receives, if necessary, information on the smart watch 4 about the completed task and the need to perform the next, directing him to the next simulator 7, or to the measuring stand 1. During the training process, the wearable cardio sensor 5 and the smart watch 4 monitor the activity of the heart, In the event of a significant excess of the threshold values of cardio indicators, smart watch 4 sends a command to stop work on the simulator 7. In this case, the simulator 7 first makes a sound signal to attract the attention of both the user and the person responsible for safety in the gym, after the signal, a shutdown occurs operation of the simulator 7. After the completion of the training algorithm, the data on the state of the physiological dynamic parameters of the user are transferred to the database 3 of the control module of the system 2, the user is tested on the measuring stand 1, after which, if necessary, the complete training process is corrected based on and from the physiological parameters of the user.

Claims (2)

1. A method of organizing the training process, including identification of the user, preliminary measurement of the user's static physiological parameters using a measuring stand, collection and processing of the obtained data, automatic compilation of a training algorithm based on the results of processing the obtained data, periodic measurement of the user's dynamic physiological parameters during execution training algorithm using at least one wearable device, characterized in that before the automatic compilation of the training algorithm, the user selects the training goal, during the execution of the training algorithm by the wearable device, the user's dynamic indicators are periodically analyzed and, based on the analysis, the user is prompted to return to the measuring stand , or go to the next task of the training algorithm, including on the next simulator, or stop to execute the training algorithm, including due to the automatic stop of the simulator in case of exceeding the threshold values of the user's dynamic physiological indicators and notifying the user about this; Based on the results of measurements and analysis of dynamic physiological indicators carried out by the wearable device, the training algorithm is automatically adjusted. 2. A system for organizing the training process, containing a measuring stand with diagnostic modules for measuring static physiological indicators of the user, a system control module with the ability to store and process information, at least one wearable device containing a module for measuring dynamic physiological indicators of the user, and training equipment, which is different the fact that the training equipment is equipped with data synchronization and user identification modules, while the wearable device contains modules for analyzing periodically measured dynamic parameters of the user, synchronizing with the system control module, training equipment and measuring bench, controlling training equipment and notifying the user about the next action within the training algorithm or the need to stop the training algorithm, while the training equipment is a cardio and / or strength training apparatus.

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