RU2492897C1 - Method of interactive training - Google Patents

Abstract

FIELD: sport.

SUBSTANCE: invention relates to physical education and sport, and is intended for interactive training in game types, for aerobic and fitness exercises. The training is carried out on the playing field with a controlled light dynamic illumination. The light dynamic illumination is created by a light emitter mounted with a video camera at a predetermined height above the playing field. Using the light dynamic illumination the permitted zones are specified, where the trainee should be. In the trainee prior to the training the amount of load is determined, corresponding to 35, 50, 75, 100 and 125% of the suitable maximum oxygen consumption. The warming-up time and the time of onset of fatigue are determined, the range of variation of heart rate (HR) during warming-up and before onset of fatigue. The hardware and software system records the duration of the threshold interpulse interval defined by the trainee. The hardware and software system puts the incoming information into memory, processes, and if the heart rate value of the trainee during warming-up is below the maximum allowable value, after the end of time of warming-up a recommendation is given to increase the intensity of load. If the heart rate value of the trainee during warming-up is higher than the maximum allowable value, the hardware and software system changes to the program of minor complexity that specifies a lower intensity of the load. The training ends when the onset of fatigue.

EFFECT: increased accuracy of control of the training athlete and the ability to change the conditions of the training process depending on the degree of preparedness, which eliminates excessive fatigue of the athlete.

Description

The invention relates to physical education and sports, and is intended for interactive training in game forms, for aerobics, fitness and other sports, which are characterized by a variety of motor actions.

There is a method of playing soccer and hockey, which consists in the struggle of competing players for the possession of the ball or puck on the playing field and the subsequent defeat of one goal freely set in the center of the field by tipping it or displacing the ball or puck, respectively, from a distance exceeding the radius made in the center of the field annular platform [1].

The disadvantage of this method is limited functionality, lack of control of the functional state of the body of the players.

A known method for diagnosing the functional state of the body, which consists in monitoring the parameters of blood oxygenation and oxygen deoxygenation by measuring changes in time of its optical characteristics when placing a blood sample in a sealed heat and moisture-resistant chamber filled with a gas mixture with a fixed partial pressure of oxygen, and oxygen exchange of the blood sample under study with the gas mixture in the chamber with continuous contact of blood with the gas mixture and the continuous recording of an optical signal characterizing the temperature of blood oxygen saturation during the whole process of blood gas exchange with the gas mixture in contact with it, characterized in that the blood gas exchange processes are carried out in several stages by alternately repeatedly oxygenating and / or deoxygenating a blood sample in a substantially small volume, while measuring the optical characteristics of blood they carry out modeling of various states of the blood sample under study by changing the composition of the gas mixture filling the chamber, and assessing the functional state of the organism lead by matching optical characteristics obtained in this simulation [2].

The disadvantage of this method is the need for sampling, a long time for their analysis.

A known method for assessing the functional state during stress testing, including recording a patient’s electrocardiogram followed by building a rhythmogram and creating its mathematical model, characterized in that the patient’s electrocardiogram obtained by bicycle ergometry examination is analyzed by creating a mathematical model of the variability of cardio intervals with the construction of the best trends: straight - during the period increase in heart rate, hyperbole - during the period when maximum heart rate is reached, while optimization of the parameters of hyp Rbola is achieved by the least squares method on the interval of stationary heart rate, and the parameters of the line are determined by the least squares method on the interval of increase in heart rate from the beginning of the load to the points ensuring the touch of the hyperbola, while the instant heart rate at the touch point of modeling trends: the line and the hyperbola characterizes the functional state of the body, this value of instant heart rate in the range of 147-160 beats per minute determines satisfactory, less than 147 - poor, more than 160 - good functional condition [3].

The disadvantage of this method is that registering the response of the heart rate to physical activity, it cannot be definitely said whether it reflects the state of the executive organ - the heart, or is associated with the features of the autonomic regulation of cardiac activity [4].

During the period of adaptation to physical activity in the body, as a functional system, continuous changes occur due to the regulation of autonomic functions in various organs and systems of the body [5]. In the regulatory processes occurring in the human body, the central nervous system plays a dominant role, therefore, in studying the adaptation of a person to physical activity, it is necessary to evaluate the dynamics of the state of the central nervous system itself [6]. As parameters characterizing the state of the central nervous system, the parameters of the state of the visual analyzer are used, since the effectiveness of its functioning depends primarily on the level of functioning of the central nervous system [7].

A known method of ranking people according to indicators of the functional state of the central nervous system, which consists in making judgments about the state of information and analytical functions according to the definition of psychophysiological indicators, characterized in that the assessment is made according to the calculated integral indicator of the functional state of the central nervous system, determined by testing light stimuli of different colors and according to the determination of the time of sensorimotor reactions, calculated as the weighted average value of the understatement aemogo place in the team ranking as measured by the criteria indicators: the excitability of the nerve centers and the lability of the nervous processes, defined by the critical frequency of flashing the merger in the cortical centers of the visual analyzer to the right and left hemispheres of the brain alone; the speed of perception of sensory information and the development of decisions on motor reactions in the motor cortex of the right and left hemispheres of the brain separately; the dominant algorithms for the functioning of the information-analytical structures of the central nervous system according to interhemispheric functional asymmetry of the cerebral hemispheres, determined by indicators of the excitability of nerve centers for test signals of different colors; degrees of interhemispheric functional asymmetry of the cerebral hemispheres, determined by the time of visual-motor reactions to light signals presented in the right and left half-fields of vision and the implementation of motor reactions by a hand controlled from the same hemisphere of the brain into which the light test stimulus is addressed; the degree of psychoemotional tension, defined as the difference between the indices of the excitability of the nerve centers on the test signals of red and green; moreover, the subject, occupying a higher place according to the above criteria, in the implementation of prognostic assessment is regarded as the most promising and able to show high results in the upcoming professional activity [8].

In the method, the functional state of the central nervous system is evaluated by determining the time of sensorimotor reactions and the critical frequency of fusion of light flickers.

The disadvantage of this method is the low accuracy of measuring the critical frequency of light flicker and, as a consequence, not a reliable assessment of the functional state of the central nervous system [9].

The criterion of the functional state of the central nervous system is the time of sensation, which is understood as the time between the moment of light exposure on the retina and the moment of the appearance of the corresponding visual sensation, due to the finite rate of physical and chemical processes in the retina and optic nerve [7]. Sensation time is estimated by the method of paired light stimuli by measuring the threshold interpulse interval [10]. The accuracy of estimating the sensation time is higher than the accuracy of estimating the critical frequency of light flickers [9], which makes it possible to more reliably determine the functional state of the central nervous system, evaluating the operating time and fatigue.

A known method for evaluating the running time is that the test subject is given a test with a constant load and a sequence of paired light pulses of 200 ms duration is presented, separated by an inter-pulse interval of 70 ms, repeated at a constant time interval of 1 s; periodically, by the method of successive approximation, the threshold interpulse interval is determined, at which two pulses in a pair merge into one, and a graph is plotted of the dynamics of the threshold interpulse interval in coordinates "the value of the threshold interpulse interval - test time"; operating time is estimated by the time the graph of the dynamics of the threshold inter-pulse interval reaches the “plateau” [11].

There is a method of determining human fatigue, which consists in the fact that the test subject is given a test with a constant load and a sequence of paired light pulses of 200 ms duration is shown, repeating through a constant time interval of 1 s, separated by an interpulse interval of 70 ms; periodically, by the method of successive approximation, the threshold interpulse interval is determined, at which two pulses in a pair merge into one, and a graph is plotted of the dynamics of the threshold interpulse interval in coordinates "the value of the threshold interpulse interval - test time"; the state of human fatigue is determined by the time of a sharp decrease in the values of the threshold interpulse interval [12].

The disadvantage of methods for estimating the running-in time and determining fatigue is to set a constant load equal to 100% of the proper maximum oxygen consumption, determined by B.P. nomograms. Prevarsky. It is known that the load determined by nomograms is averaged. However, the same in intensity and duration of exposure can be stress factors for one person and not possess these properties for another. According to A.N. Korzhenevskogo et al. [13] the use of loads of the same volume and intensity leads to an increase in functionality only in 30-40% of trainees - in those for whom the load was optimal. For more trained athletes, these loads are ineffective, and for insufficiently trained athletes, they are inadequate and lead to overwork.

The closest in technical essence to the proposed method is a method for training players and athletes with a sports equipment on the playing field, including performing training on the field with controlled dynamic lighting, characterized in that by means of dynamic lighting set the permitted areas in which the athlete must be while holding sports equipment, while unpredictably for the athlete, they change the position, shape and area of the allowed areas, if possible the athlete is constantly located ivat sports equipment in the allowed band is judged on the growth of sports skill of the athlete and the effectiveness of training, change of position, shape and area of the allowed bands and the workout mode is set manually or by software-hardware complex. [14]

The disadvantage of this method is limited functionality, lack of control of the functional state of athletes.

The technical result to which the claimed invention is directed is to increase the effectiveness of training during physical education and sports, which are characterized by a variety of motor actions, by ensuring the interactivity of the training and monitoring the functional state of the trainee.

The technical result is achieved by the fact that the interactive training is carried out on the playing field with controlled dynamic lighting, by which the allowed zones are set in which the trainee should be located, while the position, shape and area of the allowed zones are unpredictable for the trainee, the position, shape and area are changed allowed zones and training modes are set by a hardware-software complex, and the new one is that the playing field contains football and / or hockey gates and / or supports, on which oryh mounted shields with basketball basket; dynamic lighting is created by a light emitter installed with a video camera at a predetermined height above the playing field; the hardware-software complex contains a library of programs of varying complexity for modeling individual and / or group testing, training and game modes of various sports games, for aerobics and fitness; the training person in advance of the training on B.P. nomograms Prevarski determine the magnitude of the load corresponding to 35, 50, 75, 100 and 125% of the maximum maximum oxygen consumption, at given loads determine the time of use and the time of onset of fatigue, the range of changes in heart rate during use and before the onset of fatigue; to determine the running-in time and the range of changes in heart rate during running-in, the trainee is given a test with a given constant load and a sequence of paired light pulses with a duration of 200 ms, separated by an inter-pulse interval of 70 ms, repeated at a constant time interval of 1 s; heart rate is periodically measured and the threshold interpulse interval is determined by the method of successive approximation, at which two pulses in a pair merge into one, a graph of the dynamics of the threshold interpulse interval is plotted in coordinates "the value of the threshold interpulse interval - test time"; the running time of the trainee is estimated by the time the graph of the dynamics of the threshold inter-pulse interval reaches the “plateau”; the maximum allowable heart rate during operation is determined at the time the graph of the dynamics of the threshold interpulse interval reaches the “plateau”; to determine the time of onset of fatigue and the range of changes in heart rate before the onset of fatigue, the test is continued, the state of fatigue of the trainee is determined by the time of a sharp decrease in the threshold interpulse interval; the maximum allowable heart rate before fatigue is determined at the time of a sharp decrease in the values of the threshold interpulse interval; the trainee selects a program for modeling an individual or group testing or training or game mode and starts it; heart rate during a training session is measured and transmitted to the software and hardware complex, the training process is shot with a video camera, video from the camera is transferred to the hardware and software complex; 10 light stimuli are presented to the trainer periodically on a horizontal or vertical surface under the control of a hardware-software complex, which is a sequence of paired light pulses with a duration of 200 ms, separated by an interpulse interval, repeating through a constant time interval of 1 s; at the first stage of measurements in the first light stimulus, the interpulse interval is 1 ms, in each subsequent light stimulus, the interpulse interval is increased compared to the interpulse interval of the previous light stimulus by 5 ms, the trainee determines the light stimulus with the highest number for which the fusion of two light pulses is subjectively felt paired into one, and touches it with your hand or another part of the body or with any object; at the second stage of measurements in the first light stimulus, the inter-pulse interval is set equal to the inter-pulse interval of the light stimulus, which is determined at the first stage by training as a light stimulus, for which the merging of two light pulses in a pair is subjectively felt, and in each subsequent light stimulus, the inter-pulse interval is increased compared to 0.5 ms interval of the previous light stimulus, the trainee determines the light stimulus with the highest number, for which fusion is subjectively felt two light pulses in a pair into one, and touches it with your hand or another part of the body or with any object; at the third stage of measurements in the first light stimulus, the inter-pulse interval is set equal to the inter-pulse interval of the light stimulus, which is determined at the second stage by training as a light stimulus, for which the merging of two light pulses in a pair is subjectively felt, and in each subsequent light stimulus, the inter-pulse interval is increased compared to the inter-pulse interval of the previous light stimulus at 0.1 ms, the trainee determines the light stimulus with the highest number for which fusion is subjectively felt the appearance of two light pulses in a pair into one, and it touches it with the hand or another part of the body or with any object, fixing the value of the duration of the threshold interpulse interval in the hardware-software complex; the hardware-software complex saves the incoming information, builds a graph of the dynamics of the threshold interpulse interval in the coordinates “the value of the threshold interpulse interval - test time”, displays the current value of the heart rate and the dynamics of the threshold interpulse interval to display the correspondence of the intensity and speed of motor actions the functional state of the trainee; if the values of the heart rate of the trainee during training or after its completion are below the maximum allowable value for this period, they are displayed on the display screen in one color and / or are accompanied by sound signals and / or a combination of sound signals and / or the corresponding musical melody, in this case after the end of the operating time, a recommendation is made to increase the intensity of the load; if the values of the heart rate of the trainee during training or after its completion are higher than the maximum permissible value for this period, they are displayed on the display screen in a different color and / or are accompanied by other sound signals and / or another combination of sound signals and / or other appropriate musical melody, in this case, the hardware-software complex switches to a program of less complexity, which sets a lower intensity of the load; the training is completed when fatigue occurs, which is determined by the dynamics of the threshold interpulse interval at the time of a sharp decrease in its values.

The proposed method of interactive training is as follows. Interactive training is carried out on the playing field with controlled dynamic lighting, containing football and / or hockey gates and / or supports, on which are installed the shields with a basketball basket. The dynamic lighting is created by a light emitter installed with a video camera at a predetermined height above the playing field. The dynamic zones set the permitted zones in which the trainee should be. Changing the position, shape and area of the permitted zones and training modes is specified by a hardware-software complex that contains a library of programs of varying complexity for modeling individual and / or group testing, training and game modes of various sports games, for aerobics and fitness classes.

At the trainee, in advance of training, according to B.P. nomograms Prevarski determine the magnitude of the load corresponding to 35, 50, 75, 100 and 125% of the maximum maximum oxygen consumption. At specified loads, the running-in time and the time of onset of fatigue, the range of changes in the heart rate during operation and before the onset of fatigue are determined.

To determine the running-in time and the range of changes in heart rate during running-in, the trainee is given a test with a given constant load and a sequence of paired light pulses with a duration of 200 ms, separated by an inter-pulse interval of 70 ms, repeated through a constant time interval of 1 s, is presented. The heart rate is periodically measured and the threshold interpulse interval is determined by successive approximation, at which two pulses in a pair merge into one. Build a graph of the dynamics of the threshold interpulse interval in the coordinates "the value of the threshold interpulse interval - test time". The running time of the trainee is estimated by the time the graph of the dynamics of the threshold interpulse interval reaches the “plateau”. The maximum allowable heart rate during operation is determined at the time of the output of the graph of the dynamics of the threshold interpulse interval to a "plateau".

To determine the time of onset of fatigue and the range of changes in heart rate before the onset of fatigue, the test is continued, the state of fatigue of the trainee is determined by the time of a sharp decrease in the threshold interpulse interval. The maximum allowable heart rate before fatigue is determined at the time of a sharp decrease in the threshold interpulse interval.

The trainee selects a simulation program for an individual or group testing or training or game mode and starts it. In a trainee, during the training, the heart rate is measured and its values are transmitted to the hardware-software complex. The training process is shot with a video camera, the video image from the camera is transmitted to the hardware-software complex.

A trainer periodically on a horizontal or vertical surface under the control of a hardware-software complex is presented with 10 light stimuli, which is a sequence of paired light pulses with a duration of 200 ms, separated by an interpulse interval, repeating through a constant time interval of 1 s. At the first stage of measurements in the first light stimulus, the interpulse interval is 1 ms; in each subsequent light stimulus, the interpulse interval is increased by 5 ms compared to the interpulse interval of the previous light stimulus. The trainee determines the light stimulus with the highest number, for which the merging of two light pulses in a pair into one is subjectively felt, and touches it with the hand or another part of the body or with any object. The hardware-software complex records the duration of the inter-pulse interval determined by the trainees in the first stage.

At the second stage of measurements in the first light stimulus, the inter-pulse interval is set equal to the inter-pulse interval of the light stimulus, which is determined at the first stage by training as a light stimulus, for which the merging of two light pulses in a pair into one is subjectively felt. In each subsequent light stimulus, the interpulse interval is increased by 0.5 ms compared to the interpulse interval of the previous light stimulus. The trainee determines the light stimulus with the highest number, for which the merging of two light pulses in a pair into one is subjectively felt, and touches it with the hand or another part of the body or with any object. The hardware-software complex records the duration of the inter-pulse interval determined by the trainees in the second stage.

At the third stage of measurements in the first light stimulus, the inter-pulse interval is set equal to the inter-pulse interval of the light stimulus, which is determined at the second stage by training as a light stimulus, for which the merging of two light pulses in a pair into one is subjectively felt. In each subsequent light stimulus, the interpulse interval is increased in comparison with the interpulse interval of the previous light stimulus by 0.1 ms. The trainee determines the light stimulus with the highest number, for which the merging of two light pulses in a pair into one is subjectively felt, and touches it with the hand or another part of the body or with any object. The hardware-software complex records the duration of the threshold inter-pulse interval determined by the trainees in the third stage.

The hardware-software complex saves the incoming information, builds a graph of the dynamics of the threshold interpulse interval in the coordinates "the value of the threshold interpulse interval - test time", displays the current value of the heart rate and the dynamics of the threshold interpulse interval to display the correspondence of the intensity and speed of motor actions the functional state of the trainee. If the values of the heart rate of the trainee during training or after its completion are below the maximum allowable value for this period, they are displayed on the display screen in one color and / or are accompanied by sound signals and / or a combination of sound signals and / or a corresponding musical melody. In this case, after the running-in time is over, a recommendation is made to increase the load intensity.

If the values of the heart rate of the trainee during training or after its completion are higher than the maximum permissible value for this period, they are displayed on the display screen in a different color and / or are accompanied by other sound signals and / or another combination of sound signals and / or other appropriate musical melody. In this case, the hardware-software complex switches to a program of less complexity, which sets a lower load intensity.

Training is completed when fatigue occurs, which is determined by the dynamics of the threshold interpulse interval at the time of a sharp decrease in its values.

When implementing the inventive method, well-known technical solutions and means can be used, for computer processing of the obtained information, known or original software can be used.

The inventive method allows for interactive training in physical education and sports, which are characterized by a variety of motor actions, to individualize the training load, increase the effectiveness of training, avoiding the state of fatigue by objective monitoring of the functional state of the trainee.

Thus, the claimed method of interactive training has new properties that determine the receipt of a positive effect.

Information sources

1. Patent 2063783 of the Russian Federation, IPC A63B 67/00, A63B 71/02. The method of playing football and hockey and the playing field for its implementation / Evminov V.V .; publ. 07/20/1996.

2. Patent 2218085 of the Russian Federation, IPC A61B 5/145. A method for diagnosing the functional state of an organism and a device for its implementation / Veretyakhin V.V., Zaritsky A.R., Perevedentseva E.V. and etc.; publ. 12/10/2003.

3. RF patent 2355302, IPC A61B 5/0452. A method for assessing the functional state during stress testing / Pokhachevsky A.L., Sadelnikov B.A .; publ. 05/20/2009.

4. Karpman V.L., Belotserkovsky Z.B., Gudkov I.A. Testing in sports medicine. - M.: Physical Education and Sports, 1988 .-- 208 p.

5. Zimkin N.V. On the variability of the structure of a functional system in the process of activity and in case of fatigue // Physiological Journal of the USSR THEM. Sechenov. - 1984. - T. LXX. - No. 12. - S.1593-1599.

6. Maslov N.B., Bloshchinsky I.A., Maksimenko V.N. The neurophysiological picture of the genesis of fatigue, chronic fatigue and overwork of a human operator // Human Physiology. - 2003. - T.29. - No. 5. - S. 123-133.

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8. Patent 2316247 of the Russian Federation, IPC A61B 5/00, A61B 3/06. A way of ranking people according to the functional state of the central nervous system / Ovchinnikov ND; publ. 02/10/2008.

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Claims (1)

A method of interactive training on the playing field with controlled dynamic lighting, which sets the allowed zones in which the trainee should be located, while unpredictably changing the position, shape and area of the allowed zones, changing the position, shape and area of the allowed zones and training modes hardware-software complex, characterized in that the playing field contains football and / or hockey gates and / or supports, on which shields with a basketball basket are installed; dynamic lighting is created by a light emitter installed with a video camera at a predetermined height above the playing field; the hardware-software complex contains a library of programs of varying complexity for modeling individual and / or group testing, training and game modes of various sports games, for aerobics and fitness; the training person in advance of the training on B.P. nomograms Prevarski determine the magnitude of the load corresponding to 35, 50, 75, 100 and 125% of the maximum maximum oxygen consumption, at given loads determine the time of use and the time of onset of fatigue, the range of changes in heart rate during use and before the onset of fatigue; to determine the running-in time and the range of changes in heart rate during running-in, the trainee is given a test with a given constant load and a sequence of paired light pulses with a duration of 200 ms, separated by an inter-pulse interval of 70 ms, repeated at a constant time interval of 1 s; heart rate is periodically measured and the threshold interpulse interval is determined by the method of successive approximation, at which two pulses in a pair merge into one, a graph of the dynamics of the threshold interpulse interval is plotted in coordinates "the value of the threshold interpulse interval - test time"; the running time of the trainee is estimated by the time the graph of the dynamics of the threshold inter-pulse interval reaches the “plateau”; the maximum allowable heart rate during operation is determined at the time the graph of the dynamics of the threshold interpulse interval reaches the “plateau”; to determine the time of onset of fatigue and the range of changes in heart rate before the onset of fatigue, the test is continued, the state of fatigue of the trainee is determined by the time of a sharp decrease in the threshold interpulse interval; the maximum allowable heart rate before fatigue is determined at the time of a sharp decrease in the values of the threshold interpulse interval; the trainee selects a program for modeling an individual or group testing or training or game mode and starts it; heart rate during a training session is measured and transmitted to the software and hardware complex, the training process is shot with a video camera, video from the camera is transferred to the hardware and software complex; 10 light stimuli are presented to the trainer periodically on a horizontal or vertical surface under the control of a hardware-software complex, which is a sequence of paired light pulses with a duration of 200 ms, separated by an interpulse interval, repeated after a constant time interval of 1 s; at the first stage of measurements in the first light stimulus, the interpulse interval is 1 ms, in each subsequent light stimulus, the interpulse interval is increased compared to the interpulse interval of the previous light stimulus by 5 ms, the trainee determines the light stimulus with the highest number for which the fusion of two light pulses is subjectively felt paired into one, and touches it with your hand or another part of the body or with any object; at the second stage of measurements in the first light stimulus, the inter-pulse interval is set equal to the inter-pulse interval of the light stimulus, which is determined at the first stage by training as a light stimulus, for which the merging of two light pulses in a pair is subjectively felt, and in each subsequent light stimulus, the inter-pulse interval is increased compared to 0.5 ms interval of the previous light stimulus, the trainee determines the light stimulus with the highest number, for which fusion is subjectively felt two light pulses in a pair into one, and touches it with your hand or another part of the body or with any object; at the third stage of measurements in the first light stimulus, the inter-pulse interval is set equal to the inter-pulse interval of the light stimulus, which is determined at the second stage by training as a light stimulus, for which the merging of two light pulses in a pair is subjectively felt, and in each subsequent light stimulus, the inter-pulse interval is increased compared to the inter-pulse interval of the previous light stimulus at 0.1 ms, the trainee determines the light stimulus with the highest number for which fusion is subjectively felt the appearance of two light pulses in a pair into one, and it touches it with the hand or another part of the body or with any object, fixing the value of the duration of the threshold interpulse interval in the hardware-software complex; the hardware-software complex saves the incoming information, builds a graph of the dynamics of the threshold interpulse interval in the coordinates “the value of the threshold interpulse interval - test time”, displays the current value of the heart rate and the dynamics of the threshold interpulse interval to display the correspondence of the intensity and speed of motor actions the functional state of the trainee; if the heart rate of the trainee during training or after it is below the maximum allowable value for this period, they are displayed on the display screen in one color and / or are accompanied by sound signals and / or a combination of sound signals, and / or the corresponding musical melody, in this case after the end of the operating time, a recommendation is given to increase the intensity of the load; if the values of the heart rate of the trainee during training or after its completion are higher than the maximum permissible value for this period, they are displayed on the display screen in a different color and / or are accompanied by other sound signals and / or another combination of sound signals, and / or other appropriate musical melody , in this case, the hardware-software complex switches to a program of less complexity, which sets a lower load intensity; the training is completed when fatigue occurs, which is determined by the dynamics of the threshold interpulse interval at the time of a sharp decrease in its values.