RU2620921C1 - Method of assessing playing sportsman's physical actions and accuracy - Google Patents

Abstract

FIELD: sports.

SUBSTANCE: circle on a display with a mark and a point object moving at the specified speed round a circle is presented to the tested sportsman. The sportsman being tested follows the point object travelling and stops it moving round a circle by pressing Stop button once seeing an assumed matching of the moving point object and the mark. That is followed by calculating a matching error of the point object and mark - a lag time with a positive sign or a lead time with a negative sign, and proceeding with moving the point object round a circle after some time. The subject, with an interval of predetermined duration performs a predetermined number of batches of a predetermined number of stops moving point of the object in the mark position. In each series is calculated time evaluation test reaction to a moving object on a mathematical formula. According to the results of all the series, the arithmetic mean value of the delay or error anticipation and the arithmetic mean of the RMS delay errors or deviations anticipation, is calculated on the basis of the results of individual series. The accuracy of motor actions is estimated at the value of the arithmetic mean value of the delay error and lead, calculated based on the results of all the series. The stability of the motor actions is estimated at the value of the arithmetic mean value of the standard deviations of the delay error and lead, calculated on the results of the individual series.

EFFECT: method allows the results of testing to evaluate the accuracy of the motor action team sports athlete at the expense of instrumental measurements.

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Description

The invention relates to sports medicine and is intended to assess the accuracy and stability of the motor actions of an athlete in sports, in which the score is won as a result of a series of strokes on a sports apparatus, such as badminton, tennis and others.

In game sports, the athlete is required to quickly assess competitive situations, make adequate decisions and technical skills when performing motor actions [1]. The effectiveness of motor actions depends on motor capabilities [2], caused, along with other parameters, by the accuracy of movements, which is understood as the quality of the motor act, implemented in compliance with a predetermined system of characteristics [3].

The effectiveness of performing motor actions is quantitatively evaluated in addition to accuracy by a number of indicators, including stability, that is, by performing a motor action with a small range of deviations in a series of 5-10 repetitions [4].

A known method for diagnosing motor functions of a person, including recording the trajectories of the joint movement of the eye, head and arm during a test for spasmodic visual stimuli, measuring latent periods, durations, maximum speeds and the number of multiple saccadic movements of the eye, head and arm and comparing them with a reference norm, characterized in that the movement of both eyes is recorded simultaneously, while the difference in latent periods, durations and the number of sets is additionally measured nnyh saccadic eye movements, and the ratio of their maximum speeds and the obtained characteristics are diagnosed motor function [5].

The disadvantage of this method is the inability to determine the accuracy of motor actions.

Achieving high results in game sports largely depends on the spatial (differentiation, accurate reproduction and measuring of spatial intervals, spatial orientation) and time (differentiation, exact reproduction and measuring time intervals) human properties [6].

A complex spatio-temporal reflex is the reaction to a moving object [7], therefore this test can be used to assess the accuracy and stability of the motor actions of an athlete in playing sports.

A known method for assessing the accuracy of motor actions of an athlete in sports is that the subject is presented with a circle on the screen of the video monitor on which the mark and point object are placed, the point object moves at a given speed around the circle, at the moment the position of the moving point object with the mark coincides the test subject by pressing the Stop button stops the movement of a point object in a circle, then the error of discrepancy between the point object and the mark is calculated - the time of the error is delay positive sign or lead with a negative sign and after a specified time resume the movement of a point object in a circle, repeat the described procedure a specified number of times, determine the maximum absolute value of the error of mismatch of a point object and a mark, assess the accuracy of the motor actions of the test subject to be equal to the maximum absolute value of the error of mismatch point object and tags [8].

In this method, the maximum absolute value of the error of discrepancy between a point object and a label is determined, which characterizes the probability of error in a series of motor actions, that is, the probability of technical marriage, however, the accuracy and stability of motor actions are not evaluated.

Closest to the technical essence of the proposed method is a method for assessing the accuracy of the motor actions of a sports athlete in sports, which consists in the fact that the subject is presented on the screen of the video monitor with a circle on which the mark and point object are placed, the point object moves at a given speed around the circle, at the moment the supposed coincidence of the position of the moving point object with the mark, the test subject stops the movement of the point object in a circle by pressing the Stop button, then the error of a point object and a mark is the time of a delay error with a positive sign or lead with a negative sign and after a specified time they resume the movement of a point object in a circle, the described procedure is repeated a specified number of times, and the new one is that a variational series of errors of mismatch of a point object and labels, calculate the variational range of the series by the formula: R = t _max -t _min , where t _max and t _min are the largest and smallest members of the variational series, ms; note on the numerical axis a segment bounded by the largest and smallest members of the variational series, the accuracy of the subject's motor actions is estimated by the location on the numerical axis of the segment bounded by the largest and smallest members of the variational series of errors of mismatch between the point object and the mark closest to the symmetry with respect to the zero point and less the value of the variational range of errors of mismatch between a point object and a label [9].

The disadvantage of this method is the lack of stability assessment of motor actions in game sports.

The technical result of the proposed method is to expand the functionality by obtaining an assessment of the stability of the motor actions of an athlete playing sports.

The technical result is achieved by the fact that the test subject is presented on the screen of the video monitor with a circle on which the mark and a point object are placed, the point object moves at a given speed around the circle, at the moment the position of the moving point object coincides with the mark, the test subject stops the movement of the point object by pressing the Stop button around the circle, then the error of discrepancy between the point object and the mark is calculated - the time of the error of delay or lead and then after a specified time resume the movement then of a circular object, the described procedure is repeated a predetermined number of times, and it is new that the subject repeats a predetermined number of series of a given number of stops of a moving point object in the region of the position of the mark with a break of a given duration, and in each series the estimate of the test reaction time t of the test subject to moving is calculated object as an arithmetic mean value by the formula:

where t _i - ie the value of the delay or lead error, ms; n is the number of stops of a point object in the region of the position of the label; and standard deviation of delay and lead errors; according to the results of all series, the arithmetic mean of the errors of delay and lead is calculated and the mean arithmetic mean of the standard deviations of the errors of delay and lead calculated from the results of individual series; the accuracy of motor actions is estimated by the lower value of the arithmetic mean of the errors of delay and lead, calculated from the results of all series; the stability of motor actions is estimated at a lower value of the arithmetic mean value of the standard deviations of the errors of delay and lead, calculated from the results of individual series.

The task of the subject, seeking to stop the moving object, precisely combining it with the mark, is to find a certain amount of lead taking into account the speed of the object, the remaining distance and the speed of its motor actions [10]. The actions of the test subject in such a situation correspond to the actions of the sportsman of the game sports, which makes it possible to evaluate the accuracy and stability of the test motor actions.

In FIG. 1 shows the circle presented to the test subject on the screen of the video monitor, where 1 is the mark, 2 is the point object moving at a given speed around the circle.

The proposed method for assessing the accuracy and stability of the motor actions of an athlete playing sports is as follows.

On the screen of the video monitor, the test subject is presented with a circle on which a mark 1 and a point object 2 are placed, moving at a given speed around the circle (Fig. 1). The subject, observing the movement of the point object 2, at the time of the supposed coincidence of the position of the moving point object 2 with the mark 1 by pressing the Stop button, stops the movement of the point object 2 in a circle.

Then, the mismatch error of the point object 2 and the mark 1 is calculated — the time of the delay or lead error, and after a specified time, the movement of the point object 2 around the circle is resumed.

A subject with a break of a given duration performs a given number of series from a given number of stops of a moving point object in the region of the mark position.

In each series, the estimate of the test reaction time t of the test subject to a moving object is calculated as the arithmetic mean value according to formula (1) and the standard deviation of the values of delay and lead errors. According to the results of all series, the arithmetic mean value of the errors of delay and lead is calculated and the arithmetic mean value of the standard deviations of the errors of delay and lead, calculated according to the results of individual series.

The accuracy of motor actions is estimated by the lower value of the arithmetic mean of the errors of delay and lead, calculated according to the results of all series.

The stability of motor actions is estimated by the smaller value of the arithmetic mean value of the standard deviations of the errors of delay and lead, calculated from the results of individual series.

The inventive method allows the results of testing to evaluate the accuracy and stability of the motor actions of an athlete playing sports.

Thus, the claimed method of evaluating the accuracy and stability of the motor actions of an athlete playing sports has new properties that determine the receipt of a technical result.

Example 1

Subject Z., 12 years old, a student of the Youth Sports School, badminton department, showed a circle on the screen of a video monitor of a personal computer, on which a mark and a point object are placed, moving clockwise around the circle, making one revolution in 2.0 seconds (Fig. 1).

The subject, observing the movement of a point object around the circumference, at the time of the supposed coincidence of the position of the point object with the position of the mark, pressed the computer keyboard key "Space", which performs the function of the "Stop" button. The computer at the moment of pressing the “Space” key stopped the movement of the point object around the circle, calculated the error of the mismatch between the position of the point object and the mark — the time of the delay error or the lead error, entered the value of the error time into the storage device and after 1 sec continued the movement of the point object around the circle.

The subject performed 15 series of 7 stops of a moving point object in the region of the position of the mark with a break of 20 seconds between series.

The number of episodes is selected based on the control competitions held in the youth sports school up to 15 points scored. The number of stops of a moving point object in the area of the mark position and the duration of the break are selected based on pedagogical observations of the control competitions.

In each series, the estimated reaction time t of the test subject to a moving object was calculated as the arithmetic mean value according to formula (1) and the standard deviation (RMS) of the delay and lead errors. The calculation results are shown in table 1.

The arithmetic mean of the errors of delay and lead ahead and the arithmetic mean of the standard deviations of the errors of delay and lead calculated from the results of individual series are 25.0 and 13.5 ms, respectively.

Example 2

Subject Y., 12 years old, student of the Children's and Youth Sports School, badminton department, similarly to subject Z., performed a test to estimate the reaction time to a moving object.

Estimates of the reaction time t of the test subject to a moving object, calculated by the formula (1), and standard deviations (RMS) of the values of the errors of delay and lead in series are shown in Table 2.

The arithmetic mean of the errors of delay and lead ahead and the arithmetic mean of the standard deviations of the errors of delay and lead calculated from the results of individual series are 23.8 and 15.3 ms, respectively.

An analysis of the test results indicates that the arithmetic mean of the errors of delay and lead, calculated according to the results of 15 series, in the subject Z., equal to 25.0 ms, more than in the subject I., equal to 23.8 ms. Consequently, the accuracy of the motor actions of test Z. is worse than that of test Y.

The arithmetic mean value of the standard deviations of the latency and lead errors calculated by the results of individual series calculated by subject Z., equal to 13.5 ms, is less than that of test I., equal to 15.3 ms. Consequently, the stability of the motor actions of subject Z. is better than that of subject I.

Thus, the proposed method allows the results of testing to evaluate the accuracy and stability of the motor actions of an athlete playing sports.

Information sources

1. Radchich I.Yu. Approaches to in-depth individualization and technology for monitoring player training in connection with the problem of Olympic selection // Theory and Practice of Physical Culture. - 2003. - No. 11. - S. 16-19.

2. Korenberg VB Sports opportunities and abilities // Theory and practice of physical culture and sports. - 2009. - No. 3. - S. 3-9.

3. Belokopytova Zh., Lavrentieva V., Kozhevnikova L. The content and structure of the program for the development of coordination abilities in girls of 10-13 years engaged in rhythmic gymnastics // Physical Education of Students (Ukraine, Kharkov). - 2010. - No. 3. - S. 3-8.

4. Galimova A.G., Zinker V.M. Coordination abilities as a factor in improving human conditions // Bulletin of the Buryat State University. - 2014. - No. 1. - S. 51-56.

5. Patent 2146494 of the Russian Federation, IPC А61В 5/103, А61В 5/16. A method for the diagnosis of human motor functions and a device for its implementation / Baziyan B.Kh., Dmitriev I.E. - No. 99105342/14; declared 03/24/1999; publ. 03/20/2000.

6. Petrov A.M. Brain and movement. - M.: Publishing House of the military-industrial complex, 1997. - 300 p.

7. Karaulova N.I. Possibilities of using the reaction to a moving object in assessing the results of training // Human Physiology. - 1982. - T. 8, No. 4. - S. 653-660.

8. Patent 2457785 of the Russian Federation, IPC АВВ 5/16. A method for assessing the accuracy of motor actions of an athlete playing sports / Zakamsky A.V., Polevshchikov M.M. Rozhentsov V.V. - No. 2011122491/14; declared 06/02/2011; publ. 08/10/2012.

9. Patent 2531972 of the Russian Federation, IPC АВВ 5/16. A method for assessing the accuracy of motor actions of an athlete playing sports / Pesoshin A.A., Rozhentsov V.V. - No. 2013136763/12; declared 08/06/2013; publ. 10/27/2014.

10. Methods and portable equipment for the study of individual psychological differences of a person / N.M. Peysakhov, A.P. Kashin, G.G. Baranov, R.G. Vagapov; Ed. V.M. Shadrina. - Kazan: Publishing house Kazan. University, 1976 .-- 238 p.

Claims (3)

A method for assessing the motor actions of an athlete in game sports, which consists in the fact that the test subject is presented on the screen of the video monitor with a circle on which the mark and the point object are placed, the point object moves at a given speed around the circle, at the moment the position of the moving point object coincides with the mark, the test subject is pressed the Stop button stops the movement of a point object in a circle, then the error of the mismatch between the point object and the mark is calculated — the time of the delay or lead error and after a specified time, the movement of a point object around the circle is resumed, the described procedure is repeated a predetermined number of times, characterized in that the subject repeats a predetermined number of series from a given number of stops of a moving point object in the region of the mark position with a break of a given duration, in each series, the time estimate is calculated reaction t of the test subject to a moving object as the arithmetic mean value according to the formula:

where t _i - ie the value of the delay or lead error, ms; n is the number of stops of a point object in the region of the position of the label; and standard deviation of delay or lead errors; according to the results of all series, calculate the arithmetic mean of the errors of delay or lead and the arithmetic mean of the standard deviations of the errors of delay or lead calculated according to the results of individual series; the accuracy of motor actions is estimated by the lower value of the arithmetic mean of the errors of delay or lead, calculated from the results of all series; the stability of motor actions is evaluated by a lower value of the arithmetic mean value of the standard deviations of the errors of delay or lead, calculated from the results of individual series.

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