RU2201784C2 - Exerciser - Google Patents

Abstract

FIELD: sportive equipment. SUBSTANCE: electronic exerciser has block-diagram comprising program-controlled boxer's bag with impact movable limbs and device for providing coordinated displacement of said bag to sportsman upon delivery of signals corresponding to location of sportsman on ring and for continuous controlling of sportsman's functional state by output from sensors disposed in said bag, as well as for continuous controlling of sportsman's psychophysiological state by output from sensors attached to sportsman's body and adapted for delivering signals corresponding to sportsman's heart rate, blood pressure, skin surface resistance, temperature. Exerciser of such construction may be used in training of beginners and skilled sportsmen of single combat events such as box, kick box and various kinds of karate. EFFECT: increased efficiency by activated exercising process. 10 cl, 6 dwg

Description

 The invention relates to the field of sports equipment for training, namely, simulators for boxing, which can also be used in the preparation of athletes of other types of martial arts such as kickboxing, different types of karate, hand-to-hand combat.

 A large number of inventions on this topic are known, protected in the form of copyright certificates of the former USSR, patents of Ukraine, Russia and other countries of the world, in which, first of all, methods for measuring the reaction time of athletes, the strength and accuracy of strikes, endurance, etc. are continuously improved taking into account the available electronics components for a specific period of time. For example, inventions of the same author on devices for training boxers on ed. USSR 674751, A 63 B 69/20 (bull. 27, publ. 07/25/79) and 685298, 63 B 69/20 (bul. 34, publ. 18.09.79) were designed to improve tactical tasks by automating the training process , studies of the reaction speed of athletes and included the following main elements: the trainer’s console with a front panel on which control signal lamps and punch direction selection contacts are connected, connected to the corresponding signal lamps, and the target for striking an athlete is made in the form of a vertically mounted shield on which mouth standard bulbs in places geometrically similar to reproducing the most vulnerable points on the head and body of the boxer have been updated, and the contacts for choosing the direction of the blow by the trainer are electrically connected to the corresponding light-indicator bulbs (ed. St. USSR 674751), and in the case of a sparring partner includes equipment in the form training helmet and training belt, on which reaction-signal lamps are installed at the most vulnerable points (ed. St. USSR 685298). The time was measured using an electric stopwatch.

 The disadvantages of these known devices include only partial automation, the lack of feedback and informing the athlete about the moments and nature of the mistakes made by him.

 By auto USSR 856473, A 63 B 69/32 (bull. 31, publ. 23.08.81) a structural diagram of the simulator-analyzer in the form of functional blocks is intended for improving and measuring technical indicators of boxers: reaction speed, accuracy, strength and endurance. The simulator provides a cyclic task of fixed time intervals for the training load and fixed pauses between them, necessary for the rest of athletes. The inventors believe that for training boxers it is enough to have four force sensors, which, being fixed at certain points on the boxing bag, allow you to practice side impacts, blows to the head and body. Introduced light indication to start and control the intervals of training loads and sound indication of the beginning and end of pauses. Adaptation of the device to the specific tasks of the training process is provided by the manual control unit. Undoubtedly, this known solution has the same drawbacks as previously indicated.

 According to the patent of the Russian Federation 2084256, A 63 B 69/00 (bull. 20, publ. 20.07.97) a problem is solved that is close to the claimed invention, but the training device is not intended for boxers, but for highly qualified wrestlers. It made an attempt to increase the effectiveness of training by simulating the opposing opposing forces specific for a wrestling match, capturing the moment and capture force, introducing biological feedback, as well as through semi-automatic programming of training modes. In particular, in the process of training, information is taken about the pulse rate - heart rate (heart rate), blood pressure (BP) of the wrestler, which is carried out using the heart rate and blood pressure removal unit placed on the athlete. Information about the measured values of heart rate and blood pressure of a wrestler is fed to a computer that compares the indicated current values with the maximum permissible values characterizing the athlete's tolerance of training loads. At the same time, the computer can reduce the load, and in emergency cases block the work of the simulator. If the measured current values of heart rate and blood pressure are exceeded, an alarm signal is displayed on the display panel or an audible signal is given. In view of the features that distinguish wrestling from boxing, it is quite problematic to directly apply the known solution for training boxers. The disadvantages of this decision, despite the statement about the feedback of the biological connection, include the lack of the sports match, the game nature of the training, as well as the sound feedback about the mistakes made by the athlete.

 The FIPS examination is considering the author's application for 2000114037/20 dated 5.06.2000 for an electronic simulator, which shows structural block diagrams of two interconnected simulator options for the development of special boxer motor responses and attention development. With the author’s invention, the above decision on the application submitted to FIPS does not coincide on the main distinguishing point - the absence of an active sparring partner simulator, although it coincides on a number of functional blocks, for example, a biological feedback block with an athlete in the form of speech commands, program-controlled blocks, setting the pace, rhythm of strokes and controlling the speed, accuracy and strength of the athlete's strokes.

 As the closest analogue adopted for the prototype, you should specify the simulator according to the description to ed. USSR 1768193, A 63 B 69/24 (bull. 38, publ. 15.10.92), which is intended for training combat sportsmen, as well as for the psychophysical training of operators of various complex control systems, of which the human operator is a component, and also for conducting psychophysical classes, for example during professional selection. The prototype practically coincides with the claimed invention for its intended purpose and functions, as well as for a number of design features. Common design features are: a suspended load-bearing structure on which a target for striking is mounted, a block of sensors for recording strikes by an athlete against a target, a block of analog-to-digital converters of signals from sensors, a program control block. The prototype uses a control system that implements a sharp change in the sports environment for the trainee, partial programmed control of the training process, and also feedback is introduced through electromagnets interacting with the ferromagnetic floor.

 A disadvantage of the known solution is that there are no blocks for quantitative measurement of the athlete’s reaction time, speed, strength and accuracy of strikes; there is no biological feedback about the moment and nature of the mistakes made by the athlete; there is no information board about the measured parameters. In addition, fixing the targets in addition to hanging on a movably mounted support on the floor creates practically insurmountable obstacles for the boxer's maneuverability due to the specificity of the boxing stance, when one leg with respect to the second should be pulled forward. When training boxers with a hanging boxing bag, the distance from its lower end to the floor, as a rule, is free space with a height of at least 90 cm.

 The basis of the present invention is the task of such interaction in the simulator with the target as a sparring partner, so as to ensure controlled introduction of the target into contact with the athlete to conduct attacking actions while simultaneously monitoring the attacking, defensive and counterattack efforts of the athlete, as well as the dynamics of its change functional and psychophysiological state in the process of training and, thereby, increasing the efficiency of the training process.

 The problem is solved in that in the simulator, which includes a suspended supporting structure, on which a device for moving the target is mounted, a block of sensors for fixing the athlete’s blows to the target, a block of analog-to-digital converters of signals from sensors, a program control block, according to the invention, the supporting structure is fixed above the ropes boxing ring in the form of guides along which, with the possibility of moving in mutually perpendicular directions, a drive carriage block with a target it is a boxing bag suspended in the center of the specified drive carriage above the surface of the ring, with face and body simulators, on the front surface of which are located in the most vulnerable places for impact shock sensors and light indicators of the light-indicating unit, said boxing bag contains a block of movable limbs and a block for their spatial movement, a block of sensors for monitoring the location of the athlete in the ring and a block of sensors for monitoring the position of the boxing bag relative to the athlete are introduced, b the sensor lock of the athlete’s strikes on the target is made in the form of a sensor block for determining the athlete’s functional state from sensors of strength, shock accuracy and speed of motor reactions, a block has been introduced to determine the athlete’s psychophysiological state from sensors placed on the boxer's body and equipment, an amplifier block for metrological certification sensors, a unit for processing information about the functional and psychophysiological state of the athlete and a scoreboard for displaying it, a random clock generator has also been introduced sat down, a timer, a light-indicating unit, an acoustic feedback unit with an athlete, and the first output program control unit is connected to a random number generator, a timer and a light-indicating unit, and the second and third outputs are connected respectively to the second input of the light-indicating unit and the inputs of the acoustic feedback unit communication with the athlete, and the fourth output is connected to a series-connected block of spatial movements of moving limbs and a block of moving limbs, block ohms of sensors for recording athlete’s strikes against the target and the second input of the amplifier unit for metrological certification of sensors and through it with the second input of the information processing unit on the athlete’s functional and psychophysiological status and a display panel for its display, the output of which is connected to the second input of the block of analog-to-digital converters, with the fifth, sixth, seventh, eighth and ninth outputs the program control unit is connected to the first inputs of the amplifier unit for metrological certification of sensors, unit processing information on the functional and psychophysiological state of the athlete and the scoreboard for displaying it, the block of analog-to-digital converters, the drive carriage block, the second outputs of the random number generator and timer are connected to the first and second inputs of the program control unit, the third input of which is connected to the output of the analog- digital converters, and the fourth input is connected to the sensor block of the athlete’s location in the ring, the first output of the block of moving limbs is connected to the second input of the side the bottom of the carriage, the second, third and fourth inputs of the sensor block to determine the athlete’s functional state from the sensors of force, impact accuracy and speed of motor reactions are connected respectively to the second input of the boxing bag and the output of the head boxer bag simulator, as well as to the outputs of the boxing bag position monitoring sensors relative to the athlete and the sensor block of the psychophysiological state of the athlete, the inputs of which are connected respectively to the output of the drive carriage block with boxers they bag and sensors on the body and equipping the athlete.

 A specific difference between the simulator is that the boxing bag is suspended at the end of the bar, the other end pivotally mounted in the drive carriage.

Another difference is that the boxing bag is installed with the possibility of rotation around a vertical axis at angles of up to 360 ^o .

 Another difference is that the attachment unit of the boxing bag to the drive carriage is equipped with dampers against the impacts of the athlete in the form of at least two hydraulic cylinders.

 A specific difference is also that in relation to kickboxing training, a kick leg moving around the vertical axis is fixed on the free end of the boxing bag.

 The difference between the simulator is that the drive carriage is equipped with a means for bringing the boxing bag to the athlete at arm's length based on signals about the athlete's location in the ring.

 A further difference between the simulator is that the means for bringing the boxing bag to the athlete is based on a search engine on the surface of the ring divided into squares.

 The simulator's difference is that the modified ring is divided into squares, on the platform of which there is a system of sensors for monitoring the location of the athlete, triggered by the pressure of the athlete's legs.

 The simulator’s difference is that above the platform of the ring there is a grid of fiber-optic sensors located in each of the unit squares of the ring, triggered by the athlete’s movement.

 The simulator's difference is that the coordinate search system is made in the form of lines of optical sources and light receivers placed in two mutually perpendicular directions from opposite sides of the ring, and a recording device that fires when the athlete crosses the rays.

 The above specific implementations of the simulator are most preferable in the opinion of the author and do not exclude the use of other solutions within the scope of the claimed invention.

 Depending on the complexity of the electromechanical part of the simulator design, as well as to a large extent on the quality of the developed software, using this simulator it is possible to quickly and successfully solve various tasks of the training process both for training young athletes and professional athletes.

 The advantages of the proposed simulator, due to a causal relationship of the features of the invention and the technical result, are that the electronic simulator is based on computer technology and can be implemented on the principle of biotechnological systems, which include a complex of various sensors made on a modern element base, with which both executive mechanisms providing a controlled change in the nature of the simulator’s actions and the psychophysiological state are controlled boxer, equipped with a sparring partner simulator summarizing system in the form of a boxing bag equipped with shock limbs, is equipped with continuous monitoring of the athlete’s functional and psychophysiological state with the introduction of voice feedback to inform the athlete about the moments and nature of the mistakes made, and to achieve high results, it is necessary to ensure interconnection and one-time growth of informative indicators both in functional and in psychophysiological parameters. The accumulation of information in the simulator in the form of a database for each of the athletes allows you to individualize the training process and to constantly monitor skill. The use of such simulators will create optimal conditions for the implementation of comprehensive training of athletes in the shortest possible time. The block-functional diagram of the simulator design is determined by the general methodological approaches to the process of training boxers described below.

 The technical solution incorporated in the electronic simulator allows introducing the ideology of environment-oriented learning (ENVIRONMENTAL-ORIENTATED TRAINING) into the training process.

 In relation to the proposed trainer, the most important distinguishing features are the introduction of a sparring partner simulator with programmatically controlled shock limbs and a means for coordinate bringing the specified boxing bag to the athlete at arm's length to conduct an active fight as a lead, made in the form of a drive carriage suspended above the ring surface , similar in function to the plotter carriage, according to the signals about the coordinates of the athlete’s location on p ring surface. The supply of a boxing bag with vital points applied to it makes it possible to control the dynamic conditions of the training and to practice technicality and accuracy of strikes. For the actual implementation of the coordinate system of bringing the boxing bag to the athlete in the ring, the most appropriate information is the information on the modern optical element base and the used microcircuits, given in the description of the patent of the Russian Federation 2135248, A 63 B 69/00, 69/32 (bull. 24, publ. 08.27.99), in which the coordinate grid in the ring is formed in a non-contact manner and the location of the impact is determined. To fix the strength and accuracy of blows in the proposed simulator, a modern element base and the design of a dynamometer simulator according to the patent of the Russian Federation 2118194, A 63 B 69/00, 69/20 (bul. 24, publ. 27.08.98) can be applied.

 The introduction of a random number generator allows you to randomly set the places of striking, the time intervals between strokes and striking, respectively, with one or another moving limb, which brings the training process closer to the conditions of a real fight. The timer makes it possible to measure the reaction rate of athletes, the speed of retaliatory strikes, control the dynamics of the effectiveness of their actions and programmatically form time intervals taking into account individual characteristics. Blocks for the formation of light signals allow athletes to specify the location of strikes. Acoustic feedback makes it possible to promptly inform athletes about the moments and nature of mistakes made, as well as to manage the psychophysiological state of athletes in the training process. The amplifier unit allows you to programmatically, taking into account the dynamic characteristics of the sensors, measure the level of incoming signals, which ensures the metrological aspects of the measurements. Analog-to-digital converters provide an opportunity to assess the strength and accuracy of strikes, as well as to accumulate information to create a data bank for each of the athletes.

 The software plays a very large role in ensuring the simulator’s efficiency and can include various types of reactions of a boxing bag as a robot to external influences. For example, one of the feedback options is to turn the robot in the direction of a side impact with an attack, or in the frontal impact of an athlete, the robot makes counter-strikes on the move left and right.

 The organization of relations between the blocks of the simulator, shown in the presented functional block diagram, implements the above methodological provisions.

Figure 1 presents a block diagram of a simulator, where:
1 - a computer-based control unit for switching on, automatic control, and flexible operating mode software;
2 - a block of a driving carriage with a boxing bag, equipped with a means for bringing the boxing bag to the athlete;
3 - a boxing bag in the form of head and trunk simulators with built-in mechanical drives of moving limbs and with fixation sensors and shock indicators of impacts to the most vulnerable points;
4 - a simulator of the head of a boxing bag for practicing attacking, defensive and counterattack actions of an athlete;
5 - block spatial displacements to provide programmatically changing movements of moving limbs;
6 - a block of moving limbs to simulate the attacking and counterattacking actions of the enemy;
7 - a block of sensors for determining the speed of motor reactions, the accuracy and strength of an athlete’s blows, as well as the misses made when performing attacking, defensive and counterattack actions;
8 is a block for processing information about the functional and psychophysiological state of an athlete and a scoreboard for displaying it; random number generator for the probabilistic change of places of striking, time intervals between strokes and striking back by any movable limb in accordance with situations arising in the ring;
9 - a timer to provide software-generated characteristics of the simulator, as well as determine the speed of motor reactions, continuous monitoring of the psychophysiological state of athletes before, during and after the fight;
10 - light indication unit for generating light signals for programmatically controlling the direction of the attacking actions of the athlete; an acoustic feedback unit for promptly informing the athlete about the moments and nature of the mistakes made and managing his psychophysiological state;
11 - amplifier block for metrological certification of sensors;
12 is a block of analog-to-digital converters (ADC) for converting the captured information into digital form for entering it into a computer in order to store and create a data bank for each of the athletes;
13 is a block of sensors monitoring the position of the boxing bag relative to the athlete;
14 - a block of sensors monitoring the psychophysiological state of the athlete;
15 is a block of sensors monitoring the location of an athlete in the ring;
16 - block sensors monitoring the psychophysiological state of the athlete;
17 is a block of sensors monitoring the location of an athlete in the ring.

In FIG. 2 and 3 respectively show a side view and a front view of one of the possible schemes for suspending a boxing bag to the guides above the ring, where:
2 - drive carriage block;
3 - a boxing bag;
4 - a head simulator with light indication of vulnerable points;
5 - block spatial displacements to provide programmatically changing movements of moving limbs;
6 - block moving limbs - shock arms;
11 - light indication unit;
18 - guide I-beam;
19 - fastening the beam to the ceiling or to an intermediate structure;
20 - a rod for attaching a boxing bag to a drive carriage;
21 - hinge;
22 - dampers - hydraulic cylinders;
23 - rubberized wheel drive;
24 - electronic scoreboard;
25 - reverse engine.

Figure 4 presents the arrangement of the guides and the block of the drive carriage above the ring indicating the possibility of rotation of the boxing bag at an angle of 360 ^o .

5 and 6 schematically show two types of suspension of a boxing bag for training kickboxers, where:
25 - drive unit;
26 - drive shock leg.

 The simulator consists of two main guides mounted on the ceiling of the hall with brackets. Two carriages with rubberized or plastic (to eliminate noise) grooved wheels move along the guides. The drive is carried out by reversible motors, and the signals to their drive come from a computer. The carriages are interconnected by traverses, along which the drive carriage 2 moves, to which the boxing bag 3 is attached to the bar.

A design variant of the moving boxing bag is that it is moved over the ring area with a rotation of up to 360 ^o .

 The program provides for various types of reactions of the drive carriage and boxing bag to external influences.

 The main blocks and nodes of the electronic simulator are interconnected in this way.

 The control unit 1 of the first output is connected to a random number generator 9 connected in series, a timer 10 and the light signal generating unit 11, and the second and third outputs are connected to the second input of the light signal generating unit 11 and the input of the acoustic feedback unit 12. In addition, the fourth output of the control unit 1 is connected in series with the spatial movement unit 5, the movable limb unit 6, the sensor unit 7 for determining the characteristics of the athletic motor responses, the second input of the amplifier unit 13 and through it with the second input of the information processing and display unit 8 the output of which is connected to the second input of the block 14 of analog-to-digital converters. The fifth, sixth, seventh, eighth and ninth outputs of the control unit 1 are connected respectively to the first inputs of the amplifier unit 13, the information processing and display unit 8, the analog-to-digital converters unit 14, the supporting structure 2 and the boxing bag 3. The second outputs of the random number generator 9 and a timer 10 is connected to the first and second inputs of the control unit 1, the third input of which is connected to the output of the block 14 of analog-to-digital converters. The first output of the movable limbs block 6 is connected with the second input of the supporting structure 2. The second, third and fourth inputs of the sensor block 7 for determining the characteristics of the motor reactions of athletes are connected respectively to the second output of the boxing bag 3, the output of the head simulator 4, and the outputs of the sensor block 15 for monitoring the position of the simulator and the block of 16 sensors to monitor the functional state of martial artists. The inputs of the block 15 sensors to control the position of the simulator and block 16 sensors to control the functional state of the martial artists are connected respectively to the output of the drive carriage 2 and the equipment of the athlete. The output of the sensor unit 17 for monitoring the location of athletes in the ring is connected to the fourth input of the control unit 1.

 Implement an electronic simulator robot for martial arts as follows.

 The control unit 1 can be made similarly known. For example, its functions can be implemented using a computer such as IBM PC with the appropriate architecture and software. The main and auxiliary guides to ensure the possibility of changing the position of the drive carriage relative to the martial artist in the ring, can be made on the basis of profiles and pipes. A boxing bag with the necessary modifications can be used as a boxing bag 3 and a head simulator 4 for practicing the attacking and counterattacking actions of athletes at vital points on the body of opponents. Block 5 spatial displacements to provide programmatically changing movements of moving limbs can be performed on the basis of electromagnets and springs. Block 6 of movable limbs to simulate the attacking and counterattacking actions of the enemy can be made using articulated joints; duralumin tubes with a foam coating and covered with soft leather, with simulators of boxing gloves mounted on the ends of the tubes. A block of 7 sensors for determining the speed of motor reactions, the accuracy and strength of blows of athletes, as well as the mistakes they made when performing attacking, counterattack and protective actions can be performed using well-known technical solutions. For example, sensors of erroneous actions when performing direct, side and blows from below can be made on the basis of microswitches with motion limiters, pulse shapers. Impact force meters are based on strain gauges, and impact velocity meters are, for example, using linear acceleration sensors. The processing unit 8 and the information display board for automatic control of the speed of motor reactions, the quantity, accuracy, strength of strokes and the functional state of athletes can also be made on the basis of well-known technical solutions, for example, using microcontrollers of the K1816BE51 series. A random number generator 9 for a probabilistic change in places of striking, time intervals between strokes and flexible changes in striking back with moving limbs in accordance with the situations that arise in the ring can, for example, be based on KG401 noise generators (A, B, C). A timer 10 for providing programmed time characteristics of the system, as well as determining the speed of motor reactions, biomechanically correct execution of technical techniques for monitoring the current state of athletes before, during and after the fight can be performed on programmable timers KR580BI5E. Block 11 of the formation of light signals for programmatically controlling the direction of the attacking actions of athletes can be implemented using AL307NM LEDs. The acoustic feedback unit 12 for promptly informing athletes about the moments, the nature of the mistakes made and managing their psychophysiological state can be made similarly known, for example, based on a computer with a sound card, low-frequency amplifier and speakers. Block 13 amplifiers for software accounting of the dynamic features of the sensors can be performed, for example, based on measuring amplifiers K140UD17. Block 14 of analog-to-digital converters for digitizing information on the strength of strikes in order to create a data bank for each of the athletes can be made using K111EPV1 microcircuits. Block 15 sensors for monitoring the position of the simulator relative to the training athlete can be performed using microswitches with movement limiters and pulse shapers. Block 16 sensors for monitoring the functional state of martial artists can also be performed using known technical solutions, for example, using measuring amplifiers K140UD17, microcircuits LM393, LF347, MV9009, R5631, a transmitter made, for example, based on microcircuits SL652C, a receiver that can be manufactured using the PSM53-V, SX-7934 (SONY), OPA102AM, and SL6700C chips. The sensor block 17 for monitoring the location of athletes in the ring can be made on the basis of microswitches with movement limiters, pulse shapers.

 Works electronic simulator robot for martial arts as follows.

 If an athlete first starts training using this system, then information about his passport data and qualification level is entered first. Then the initial operating mode is set, for example, the total time and amount of work, as well as the individual phases of the training cycle. In addition, the total number of strokes, the required rate of their striking, the number of punches, their strength, as well as the main task of training, for example, practicing attack and counterattack actions, is selected, a drive carriage 2 with a boxing bag 3 and a head simulator in the athlete’s area is displayed, after what the system is launching.

 After starting the system, the signal about the place of striking, the length of time after which the athlete must strike and the shock limb is selected with which the athlete will be struck, is probabilistically generated by the signal of the first output of the control unit 1 using the random number generator 9. In this case, the corresponding information about the necessary value of the time interval through the first output of the random number generator 9 is fed to the input of the timer 10, which ensures the formation of the necessary value of the time interval in this case. In addition, according to the signal from the second output of the random number generator 9, supplied to the first input of the control unit 1, a signal is input through its second output to the input of the light signal block 11 to highlight the place of striking. Through the fourth output of the control unit 1 and the spatial displacement unit 5, a certain movable limb of the limb unit 6 is set, by which a signal from its first output will strike back in the direction of the athlete. In this case, the movement of the "arms" (or "legs") of the limb unit 6 is set by the control unit 1, which makes a decision on the simulator's actions, guided by the information received, as well as depending on the athlete’s qualifications, the success of his work, etc. For example, at the beginning of a training session, in order for an athlete to get comfortable with the peculiarities of this task, control unit 1 sets a correspondingly slowed-down pace of attacking blows, as well as counterattack movements of the simulator. If the athlete copes with the proposed task, then the set pace of his attacking actions and counterattacking responses of the simulator, in accordance with the given and programmable algorithm, increases until the athlete begins to make erroneous or delayed actions.

 Thus, the simulator monitors the athlete's backup capabilities and prevents overwork. In addition to this, an analysis of his psychophysiological state is carried out before training, at the time of training and after its completion, which helps to increase the effectiveness of the training process by preventing overtraining. This significantly affects the duration of the athletes in the most important competitions and significantly reduces their preparation time. This ensures the objectification and visibility of the performance of athletes, which makes it easier to identify worthy to participate in the most important competitions. After the timer 10 counts the time interval specified by the random number generator 9, the signal from its first output through the first input of the light signal generation unit 11 shows the place for striking, and also the signal from the second output of the timer 10 through the sixth output of the control unit 1 the signal through the first input of the processing unit 8 and the information display board and the countdown of the athlete's reaction begins. At the moment of highlighting of a particular pain point, the athlete must strike as quickly and accurately as possible. This will lead to the generation of a pulse, which through the second input of the sensor unit 7 will go to the second input of the amplifier unit 13 from its output, and from its output to the second input of the information processing and display unit 8, with the help of which information about the moments and nature of the athlete’s actions is accumulated . In particular, at the moment the athlete performs the attacking actions and the “corresponding” microswitch “trips” at the highlighted point, this will lead to the generation of a signal for recording information about the impact force with the aid of block 14 of the analog-to-digital converters in digital form in the control unit 1 through its third input. Depending on the stage of the training cycle, the state and nature of the athlete’s actions at certain points in time, the control unit 1 through the third output generates an acoustic signal using the acoustic feedback unit 12, for example, “Good. Impact force 800 kg” or other acoustic information. For example, at the moment when a signal is received from the second output of timer 10 to the second input of control unit 1 that any stage of the training cycle has been completed, then this signal is generated: "Rest!" During training sessions, a block of 16 sensors for monitoring the functional state of martial artists provides an analysis of the current state of the athlete. At the moment of reaching a certain (programmatically correctable) value of the athlete's level of functional voltage acceptable at this stage of training, the sensor block 16 generates an audio signal to the athlete to correct his condition. This signal is also transmitted over the air to the control unit 1 to change the load level. In the case when it is necessary to develop various tactical and technical skills of athletes in motion, the control unit 1 sets the speed of the electronic robot simulator and the randomness of the nature of its direction of movement in accordance with information about the current location of the athlete obtained using the sensor unit 17 to control the location of the athletes in the ring. Throughout the training process, the physical and psychophysiological state of athletes is continuously monitored using sensors installed both on the simulator itself and directly on the athlete. For example, at the moment of highlighting the next place for striking a signal from the output of the random number generator 9, a timer 10 starts to count down the reaction time of the athlete. When the athlete strikes, the response time of the martial artist is recorded, as well as with the help of a block of 7 sensors - his accuracy and strength. The data obtained are compared with information from previous training sessions, as well as with the information received at the beginning of the training session. Based on the analysis, the training process itself is changed, and the athlete’s current physical and psychophysiological state is evaluated. These data make it possible to track the dynamics of the state of martial arts and program their further improvement.

 As the training of athletes improves, the training algorithm automatically changes.

Claims (10)

 1. The simulator, which includes a suspended load-bearing structure, on which a device for moving the target is mounted, a block of sensors for fixing the athlete’s blows to the target, a block of analog-to-digital converters of signals from the sensors, a program control unit, characterized in that the supporting structure is fixed above the boxing ropes ring in the form of guides along which, with the possibility of moving in mutually perpendicular directions, a drive carriage block with a target, which is made in the form of a boxing bag, is installed, suspended in the center of the specified drive carriage above the surface of the ring, with imitators of the face and body, on the front surface of which at the points most vulnerable to impacts are placed shock sensors and light indicators of the light-indicating unit, said boxing bag contains a block of moving limbs and a block for their spatial movement, a block of sensors for monitoring the location of the athlete in the ring and a block of sensors for monitoring the position of the boxing bag relative to the athlete, a block of sensors for fixing shock Target exchange is made in the form of a sensor block for determining the athlete’s functional state from sensors of strength, shock accuracy and speed of motor reactions, a block has been introduced for determining the athlete’s psychophysiological state from sensors placed on the boxer's body and equipment, an amplifier block for metrological certification of sensors, a processing block information on the functional and psychophysiological state of the athlete and a scoreboard for displaying it, a random number generator, a timer, a light-indication unit are also introduced , an acoustic feedback unit with an athlete, wherein the first output program control unit is connected to a random number generator, a timer and a light-indicating unit, and the second and third outputs are connected, respectively, to the second input of the light-indicating unit and the inputs of the acoustic feedback unit to the athlete, and the fourth output is connected to a series-connected block of spatial movements of moving limbs and a block of moving limbs, a block of sensors for fixing shock switch between the target and the second input of the amplifier block for metrological certification of sensors and through it with the second input of the processing unit for information on the functional and psychophysiological status of the athlete and a scoreboard for displaying it, the output of which is connected to the second input of the block of analog-to-digital converters, and the fifth, sixth , the seventh, eighth and ninth outputs, the program control unit is connected to the first inputs, respectively, of the amplifier unit for metrological certification of sensors, the unit for processing information about functions the ionic and psychophysiological state of the athlete and the scoreboard for displaying it, the block of analog-to-digital converters, the block of the drive carriage, the second outputs of the random number generator and timer are connected to the first and second inputs of the program control block, the third input of which is connected to the output of the block of analog-to-digital converters, and the fourth input is connected to the sensor block of the athlete’s location in the ring, the first output of the block of moving limbs is connected to the second input of the drive carriage block, the second, third and the fourth inputs of the sensor block to determine the functional state of the athlete from the sensors of force, accuracy of blows and speed of motor reactions are connected, respectively, with the second input of the boxing bag and the output of the simulator of the head of the boxing bag, as well as with the outputs of the sensor block for monitoring the position of the boxing bag relative to the athlete and the block sensors for monitoring the psychophysiological state of the athlete, the inputs of which are connected, respectively, with the output of the drive carriage block with a boxing bag and sensors on t barely and the athlete's outfit.  2. The simulator according to claim 1, characterized in that the boxing bag is suspended at the end of the bar, the other end pivotally mounted in the drive carriage. 3. The simulator according to claim 1, characterized in that the boxing bag is mounted with the possibility of rotation around a vertical axis at angles of up to 360 ^o .  4. The simulator according to claim 1, characterized in that the attachment unit of the boxing bag to the drive carriage is equipped with dampers against the impacts of the athlete in the form of at least two hydraulic cylinders.  5. The simulator according to claim 1, characterized in that in relation to kickboxing training, a shock leg movable around a vertical axis is fixed on the free end of the boxing bag.  6. The simulator according to claim 1, characterized in that the drive carriage is equipped with means for bringing the boxing bag to the athlete at arm's length according to signals about the athlete's location in the ring.  7. The simulator according to claims 1 and 6, characterized in that the means for bringing the boxing bag to the athlete is based on a search engine on the surface of the ring divided into squares.  8. The simulator according to claims 1 and 6, characterized in that the modified ring is divided into squares, on the platform of which there is a system of sensors for monitoring the location of the athlete, triggered by the pressure of the athlete's legs.  9. The simulator according to claims 1 and 6, characterized in that above the platform of the ring there is a grid of fiber optic sensors located in each of the unit squares of the ring, triggered by the movement of the athlete.  10. The simulator according to claims 1 and 6, characterized in that the coordinate search system is made in the form of lines of optical sources and light receivers placed in two mutually perpendicular directions from opposite sides of the ring, and a recording device that is triggered when the athlete crosses the rays.

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