RU2561868C1 - Method for examining and assessing psycho-physiological state of individual - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves examining characteristics of the psycho-physiological state (PPS) by presenting diverse stimuli to a person being tested each of which is expected to elicit its own reaction scenario implying a sequence of alternating excitatory and inhibitory processes depending on the stimulus parameters, with controlling the stimuli presentation rate depending on the accuracy of the reaction of the person being tested. The PPS characteristics is presented by a nervous process liability (NPL) evaluated by the recorded total number of stimuli for a specified period of the test time. As additional PPS characteristics, warming-up and endurance of the nervous system are to be evaluated by staging the specified period of the test time equally. Recorded stimuli number arrays, inter-stimulus interval lengths (ISIL), errors and accurate reactions of the person being tested are determined and recorded at each stage. Average ISIL is determined at each stage, and diagrams showing average ISIL and recorded stimuli numbers variations at each test stage, as well as a flow chart of errors of each stimulus reactions of the person being tested are constructed. The warming-up is shown by the length of the average ISIL diagram plateau taking into consideration the flow chart of reaction errors of the person being tested, whereas the endurance is shown by the shape of the average ISIL diagrams and the recorded stimuli number. The individual's PPS is assessed by the derived NPL test results, warming-up and endurance of the nervous system.

EFFECT: higher evaluation accuracy.

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Description

The invention relates to psychophysiology and is intended to assess the psychophysiological state (PPS) of a person. It can be used for dynamic monitoring of the psychophysiological state of personnel, for professional selection and assessment of personnel in the structures of psychological and psychophysiological support of various departments, and also for use in determining the suitability and prospects of athletes, taking into account their psychophysiological characteristics.

Typological features of the nervous system and stable psychophysiological individual characteristics of a person are of great importance for the effectiveness of various activities. The study of psychophysiological characteristics allows us to take into account their features to ensure the selection of an adequate type of activity, control the psychophysiological state and ensure a high level of performance and professional longevity.

There are various ways to assess the psychophysiological state. In particular, the “Method for assessing the mobility of human nervous processes” is known (1). Carry out the movement of a point object with a given speed around the circle, making one revolution in 3 s. At the moment of the supposed coincidence of the position of the moving point object with the mark by pressing the “Stop” button, stop the movement of the point object in a circle for a predetermined time equal to 1 s. The point object and mark mismatch error is calculated — the delay error time taken with a positive sign and the lead error time taken with a negative sign. A point object and mark mismatch error is noted in the coordinates “the value of the mismatch error is the number of attempts to combine the point object with the mark” and the movement of the point object around the circle is resumed. The described procedure is repeated, the function R _i = f (t) is plotted, where R _i is the error of the mismatch between the point object and the mark in the i-th attempt to combine with the corresponding sign until a steady state is obtained when the adaptation process is completed. The number of the registration attempt is determined, which corresponds to the end of the transition process, the time of the transition process T is calculated by the formula: T = nt + (n-1) Δt, where n is the number of the registration attempt corresponding to the end of the transition process, t is the time the object moves around the circle, Δt - the set time to stop the point object on the circle when you click the Stop button. The transition process is taken as an assessment of the mobility of human nervous processes. The method increases the reliability of the results.

The well-known "Method for assessing the mobility of human nervous processes" (2). On the screen of the video monitor, the test subject is presented with a circle on which a mark and a point object are placed. A point object moves at a given speed in a circle, making one revolution in 3 s. At the moment of the supposed coincidence of the position of the moving point object with the mark by pressing the “Stop” button, stop the movement of the point object in a circle for a predetermined time equal to 1 s. The point object and mark mismatch error is calculated — the delay error time taken with a positive sign and the lead error time taken with a negative sign. The error of the mismatch of the point object and the mark in the coordinates "the value of the error of mismatch is the number of attempts to combine the point object with the mark" is noted and the movement of the point object around the circle is resumed. The procedure is repeated, the function R _i = f (t) is plotted, where R _i is the error of the mismatch between the point object and the mark in the i-th attempt to combine with the corresponding sign until a steady state is obtained when the transition process of the device is completed. The registration attempt number n, corresponding to the end of the transient process, is determined. The mobility assessment is the number of the matching attempt corresponding to the end of the transition process, while for n <3 they consider “mobility high”, for n = 3 they consider “mobility average”, for n> 3 they consider “mobility low”. The method allows to increase functionality and obtain a qualitative assessment of the mobility of the nervous processes of the subjects.

The disadvantages of the methods is that the interpretation is not provided for all possible cases, the described criteria apply to those cases when there is a pronounced transient process leading to stabilization of the work and increase the accuracy of stops on the part of the subject. In real studies, there is not necessarily an explicit transition process that completes during the course of the study. The scatter of values can both decrease, and remain at approximately the same level, and in some cases even increase.

A known method for evaluating the functional mobility of human nervous processes using the Khilchenko test. The description of the functional mobility assessment test is described in subsection (3). The technique was developed by Khilchenko and modernized by V.G. Cherepanov and K.V. Sugonyaev. It is designed to assess the functional mobility of nervous processes.

The functional mobility of the nervous processes is evaluated by the extremely fast rate of presentation of light signals. For the examination, a PNN-3 device and a stopwatch are required. The subject is invited to press the right button with the right hand to light up the red signal, the green button to press the left button with the left hand, and not to respond to the appearance of yellow. The rate of presentation of the signals is automatically adjusted depending on the accuracy and speed of the motor reactions of the subject. Each time the button is pressed correctly, the exposure time of the next signal decreases by 20 ms, and for every mistake made, it increases by 20 ms. The rate of presentation of signals is accelerated until the number of errors exceeds 50% of the total number of signals. The initial exposure of the signal is 900 ms. The examination continues for 2 minutes (120 s). Usually, after 60-50 s the maximum rate is reached, after which it either remains stable or decreases due to the development of fatigue.

The disadvantages of the analogue (FPNP according to Khilchenko) are low accuracy (measurements are carried out using a stopwatch) and insufficiently high information content, because Only one value is subjected to analysis - the total number of stimuli that has passed in 120 s. Moreover, approximately the same values of stimuli can correspond to completely different graphs of the dynamics of changes in the duration of inter-stimulus intervals, depending on the correctness or incorrectness of the subjects pressing the buttons.

The cited literature indicates that when performing the test "usually after 60-50 s the maximum pace is reached, after which it remains either stable or decreases due to the development of fatigue", however, fixing the fact of a change in the pace during the test and analyzing the dynamics of identification of fatigue processes is not performed. Accordingly, the psychophysiological characteristics of the productivity and strength (endurance) of the nervous system are not taken into account and interpreted.

The technical result of the proposed method for the study and evaluation of the psychophysiological state of a person consists in expanding the functionality of the method of assessing the state by additional analysis of psychophysiological characteristics based on stored information about the dynamics of errors and correct answers, as well as the dynamics of changes in the duration of interstimulus intervals (DMSI), depending on the correctness of the actions test subject, and additionally assessed the inability and strength (endurance) of the nervous system (6).

The proposed method for the study and assessment of the psychophysiological state of a person allows you to expand the diagnostic capabilities of the methodology and get a better and more comprehensive assessment of the psychophysiological state of the subjects.

The positive effect of the proposed method of research and assessment of the psychophysiological state of a person is confirmed by the results of an experimental study on a group of 68 subjects.

The studies were carried out using the module of psychomotor tests (MIG), which works in combination with the psychophysiological testing device UPFT-1/30 “Psychophysiologist”.

The technical result is achieved by the fact that the test subject is consistently presented with color stimuli of different colors on the LED display, changing randomly, each color corresponds to its expected actions on the part of the test subject. Testing scenarios, taking into account the instructions, provide an alternate change in the excitatory and inhibitory process depending on the parameters of the stimulus.

The rate of presentation of signals is automatically adjusted depending on the accuracy of the instructions. In the process of testing, arrays of values of the durations of interstimulus intervals (DMSI) of errors and the correct reactions of the test subject are recorded and formed, and graphs of these values are constructed,

For a more convenient perception of the tendency of the DMSI, the fixed time interval for the test is divided into 6 stages of 20 s. The average DMSI for each stage is determined and graphs are constructed that reflect the changes in the average DMSI and the number of recorded stimuli at each stage of the test time, as well as a graph of the dynamics of the reaction of the test person to each stimulus supplied.

Estimation of workability is carried out by the value of the duration of the output of the graph of the average DMSI in a gentle area, taking into account the graph of the dynamics of the reaction errors of the subject. The endurance assessment is carried out on the basis of the analysis of the form of the graphs of the average DMSI and the number of recorded incentives. The assessment of human PPS is carried out on the basis of the obtained results of the research of FINN, the inability and endurance of the nervous system.

The following are several examples of studies with an expanded analysis of the psychophysiological state, including an assessment of the functionality of the mobility of nervous processes, ingestibility and endurance.

In FIG. Figure 1 presents the results of a study analysis with very high functional mobility, high productivity and high endurance.

In FIG. 2 presents the results of a study analysis with low functional mobility, a very low level of productivity and high endurance.

In FIG. Figure 3 presents the results of a study analysis with high functional mobility, a high level of productivity and low endurance.

In FIG. 4 presents the results of the analysis of the study with very low functional mobility, very low workability, high endurance.

In FIG. 5 presents the results of the analysis of the study, which showed that this study is invalid and needs to be repeated, re-instructing the subject.

The proposed method for the study and assessment of the psychophysiological state of a person is as follows.

1. The test subject is presented with color stimuli of different colors on the LED indicator.

2. The color of the stimuli changes according to a random law, each color corresponds to its expected actions on the part of the subject.

3. The correct actions on the part of the subject are:

- Pressing the “YES” button on the appearance of a red signal;

- Pressing the “NO” button on the appearance of a green signal;

- Skip pressing a button for a yellow signal;

4. The rate of presentation of signals is automatically adjusted depending on the accuracy of the instructions.

- The initial value of the duration of the interstimulus interval (DMSI) is 900 ms.

- With each correct reaction from the subject to the presented color stimulus (including inaction on the yellow stimulus), the duration of the inter-stimulus interval decreases by 20 ms.

- For each incorrect reaction from the subject to the presented color stimulus, the duration of the inter-stimulus interval increases by 20 ms.

- Thus, the rate of presentation of the stimulus varies depending on the actions of the subject, which affects the total number of stimuli that will be presented to him for a fixed interval of time of the test - 120 s.

- The LED glow time (exposure) depends on the current value of the inter-stimulus interval and the subject's actions. If the subject presses the button, then the glow stops, the next glow continues at the end of the current inter-stimulus interval. If the button is not pressed, the exposure time is equal to the time of the inter-stimulus interval. The duration of the next interstimulus interval is adjusted depending on the correctness of pressing or not pressing the button.

5. During the test, arrays of values of the duration of the interstimulus interval (DMSI) and the sign of the correctness of the reaction on the part of the subject for each stimulus are stored.

6. Based on these data, it is determined:

- The total number of incentives for 120 s.

- Number of stimuli at six 20-second time intervals.

- The average duration of interstimulus intervals over six 20-second time intervals.

7. The graphs of the DMSI and the dynamics of errors in relation to the numbers of stimuli are constructed, as well as the graphs of the average values of the DMSI and the number of stimuli in relation to six 20-second intervals;

8. Based on the analysis of the data obtained, an interpretation of the psychophysiological state is carried out:

- A general assessment of the functional mobility of nervous processes is carried out according to the total number of stimuli that have passed in 120 s. FINN is assessed on a 10-point scale, taking into account the recommendations set forth in (5).

- Classification of the type of the graph of the average DMSI is carried out according to the following positions: “descending”, “concave”, “ascending”, “convex”. These classification options are used in evaluating productivity and endurance.

- The evaluation of the characteristics of the workability is carried out by the value of the duration of the transition process (DAY) of the DMI schedule. In the physiology of work and sports, the term “workability” denotes the property of individual functional systems and the body to increase levels of functioning at the beginning of work in accordance with its nature and intensity (6). The workability stage is characterized by an increase in the quality of the activity compared to the initial state, denoted as the state of operational rest preceding the activity. This stage is characterized by the gradual involvement in the work of the functional systems of the body that ensure the labor process. For the presence of inoperability, the “downward” and “concave” type of the graph of medium DMSI are characteristic. In some cases, the inoperability is also present with the “convex” type of the graph, in the case when the DMSI values when switching to a gentle portion of the graph are less than 850 ms. The presence of an “ascending” type is interpreted as invalid research, which may be due to misunderstanding and following test instructions. The operational state of functioning is determined by the output of the DMI graph to a gentle section with approximately the same number of alternating errors and correct reactions. The shorter the transition period, the higher the productivity and the faster the transition to a working state that characterizes the level of functioning possible for a particular subject. DAY values ≤25 s are interpreted as a high level of workability; DAYs> 25 s, but ≤50 s are interpreted as the average level of workability; DAYS> 50 s are interpreted as low workability. In the event that, from the very beginning of the study, the number of errors exceeds the number of correct answers, there is no transition process for lowering the graph of average DMSI with access to a relatively flat section, and the graph is mainly ascending throughout the study, this is interpreted as an invalid study that needs to be repeated by further instructing the subject.

- The achieved DMSI value, corresponding to a relatively flat plot, corresponds to the boundary of the functional capabilities of a particular subject and quantitatively characterizes the maximum possible indicators of his working condition using the model of the task used in the FINN technique as an example.

- Assessment of the strength of the nervous system is carried out on the basis of the classification of the shape of the graph of the average values of the LCMS for 20-second stages. The strength of the nervous system is a property of the nervous system, reflecting its performance and endurance, i.e. ability to withstand long and heavy loads. The identification of the “concave” type of the graph of the average DMSI values (and, accordingly, the “convex” type of the graph of the number of stimuli) for six 20-second stages reflects a significant deterioration in the efficiency of the activity and indicates an increase in fatigue in the process of execution, i.e. about poor stamina. The more pronounced is the rise in the phased graph of the average values of the DMSI in the second half of the study, and the earlier this rise begins, the less endurance. If the average values of the 5th or 6th stage (conditional breakdown into 20-second fragments) do not exceed the average values of the gentle area by more than 10%, this is regarded as a high level of endurance; if these values are in the range> 10% and ≤25%, then this is regarded as an average level of endurance; if these values are in the range> 25% and ≤50%, then this is regarded as a low level of endurance; if these values are in the range> 50%, then this is regarded as a very low level of endurance.

Example of study No. 1 - very high functional mobility (10 points), high workability, high endurance.

Above is a graph reflecting the dynamics of the duration of the interstimulus interval (DMSI) and a graph of the dynamics of errors. On the bottom left is a graph of the average values of the DMSI for six 20-second stages of a total of 120-second study, the bottom right is a graph of the number of incentives for six 20-second stages of a total of 120-second study.

The graph of error dynamics shows that on the first 27 stimuli there were only 2 erroneous answers (red bars) and 25 correct answers (green bars). Taking into account the inherent mechanism for controlling the rate of stimulus delivery, the DSMI graph decreases very quickly and reaches a relatively flat section (after about the 27th stimulus, which corresponds to about 19-20 seconds from the start of the test). The exit to the gentle slope corresponds to the completion of the transition process and the transition from the initial state to the operating state.

The achieved values of the DMSI of the operating state (PC) are quite low (of the order of 420 ms, which subsequently decrease to a level of the order of 300 ms), which indicates a high level of functional mobility. As a result, the total number of stimuli was 272, which according to the criteria corresponds to "a very high functional mobility of the nervous processes (10 points)."

On the graph of the average values of the DMSI and the number of stimuli for the 20-second stages, it can be seen that after the end of the work-in period, these values vary within small limits, the “concave” type of the graph is not detected, respectively, there are no obvious signs of a decrease in the strength (endurance) of nervous processes.

The final interpretation of the study reflects “very high functional mobility of nervous processes (10 points)” (based on a high total number of stimuli equal to 272), “high workability” (based on quick access to a relatively gentle area) and “high endurance” (on on the basis of the absence of a “concave” type of graph of the average values of the DMI and the absence of significant differences at the 5th and 6th stages).

Example of study No. 2 - low functional mobility, very low workability, high endurance.

The total number of stimuli in 120 seconds in this study reached 169, which, according to the criteria, is regarded as “low functional mobility of nervous processes (3 points)”.

In contrast to study example No. 1, at the beginning of the study, a large number of errors (red bars down) were observed, which led to the fact that the duration of the inter-stimulus interval increased and reached a maximum of 1100 ms, exceeding the initial value (900 ms) by 300 ms. The initial values of 900 mm were achieved only on the 39th stimulus, after which a slow process of reducing these values began, the completion of which can be attributed to the 87th stimulus. The work-in period was about 78 seconds, which is about 4 times higher than the values obtained by the example of study No. 1. A very long transition process from the initial background state to the working state allows us to interpret this as a very low level of inoperability.

Since the phased graph of the mean values of the DMSI is not concave, but monotonously dropping, and the graph of the number of stimuli is monotonically increasing, the state of fatigue did not occur during the test and this can be regarded as “high endurance”.

Example of study No. 3 - high functional mobility, high workability, low endurance.

The total number of stimuli in 120 seconds in this study reached 212, which, according to the criteria, is regarded as “high functional mobility of the nervous processes (7 points)”.

The transition process from the initial state to the operating state is completed quite quickly, approximately 24 seconds after the start of the test. Accordingly, this study has a high level of productivity.

However, a phased graph of the average DMSI values is clearly concave with a very significant increase in the DMSI in the second half of the study. The graph of the number of incentives, respectively, is convex in nature. This is regarded as the onset of a state of fatigue already in the middle of the study (in the region of 60-70 s). The average value of the DMSI at the 6th stage is almost 2 times higher than the average values of the 3rd and 4th stages, respectively, this is interpreted as a very low level of endurance.

Example of study No. 4 - very low functional mobility, very low workability, high endurance.

The total number of stimuli in 120 seconds in this study reached 149, which, according to the criteria, is regarded as “very low functional mobility of the nervous processes (1 point)”.

From the beginning of the study to the provision of the 41st stimulus, the DSMI schedule was upward due to the excess of the number of errors over the number of correct answers. Then begins a steady decline in the DICI schedule, passing into a relatively flat area after the 85th stimulus. The completion of the transition process approximately corresponds to 89 s and is interpreted as low workability. The level of DMSI of a gently sloping area characterizing the completion of the operating period and the transition to a working state is approximately 540 ms, which reflects the potential for functioning, but after a long operating period. The absence of a rise in the graph of average DMSI at the final stage is regarded as the absence of manifestations of fatigue and, accordingly, as “high endurance”.

Case Study 5 - Invalid study. The presence of a monotonously ascending graph of average DMI (“ascending” type of phased graph) indicates that the tasks were either not performed at all or were performed incorrectly, most likely due to a misunderstanding of the instruction. The presence of green elements in the error dynamics graph in this case corresponds to the expected skipping of pressing a button when a yellow LED indicator appears.

In this case, the study needs to be repeated, once again instructing the subject and making sure that he understood what he needs to do.

Thus, the proposed method for the study and assessment of the psychophysiological state of a person allows you to increase the functionality of the method and get a better assessment of the condition of the subjects.

The claimed method can be widely used for dynamic monitoring of the psychophysiological state of staff, for professional selection and assessment of staff in the structures of psychological and psychophysiological support of various departments, as well as for use in determining the suitability and prospects of athletes based on their psychophysiological characteristics.

Information sources

1. A method for assessing the mobility of human nervous processes. Patent No. 2336021 C1, 09.24.1007, publ. 10/20/2008.

2. A method for assessing the mobility of human nervous processes. Patent No. 2417750 C1, 12/01/2009, publ. 05/10/2011.

3. Dudyev V.P. Psychomotorics: Dictionary, 2008

4. Workshop on psychophysiological diagnosis: textbook. allowance for students. higher textbook. institutions. - M .: VLADOS. 2000 .-- 128 s.

5. Methodology for assessing the functional mobility of nervous processes using the PNP-3 device (PNP-3-01, MPM-01, AWP SPO “Selection”) ”section 4.1 on page 475 of the book Methods of military professional psychological selection. Ed. prof. G.M. Zarakovsky and V.I. Lazutkina - M .: Military Publishing House, 2005 .-- 528 p.

6. Psychophysiology. Dictionary. Authors Bezrukikh M.M., Farber D.A., PER SE Publishing House, Moscow, 2005.

Claims (1)

A method for assessing the psychophysiological state (PPS) of a person, including studying the characteristics of PPS by presenting different types of stimuli to the subject, each of which is expected to have a different reaction variant, which implies a sequential alternating change of the excitatory and inhibitory process depending on the parameters of the stimulus, controlling the rate of presentation of stimuli depending on the correctness the test subject’s response, while the functional mobility of the nervous processes (FPNP) at dawn is assessed as a characteristic of PPS the recorded total number of stimuli for a fixed time interval of the test, characterized in that, in addition to the FSF, the characteristics and performance of the nervous system are evaluated as PPS characteristics, for which during the test the fixed time interval of the test is divided into equal intervals - stages, determine and fix on At each stage, arrays of values of the number of recorded stimuli, the duration of the interstimulus intervals (DMSI), errors and the correct reactions of the test person, are determined They average the DMSI for each stage and build graphs reflecting changes in the average DMSI and the number of recorded stimuli at each stage of the test time, as well as a graph of the dynamics of the error of the test person’s response to each supplied stimulus; in this case, the assessment of the workability is carried out by the value of the duration of the output of the average DMI graph in a shallow section taking into account the graph of the dynamics of the reaction errors of the test subject, and the endurance assessment is based on the form of the average DMI graphs and the number of recorded stimuli; in this case, the assessment of human PPS is carried out on the basis of the obtained results of the study of FPNP, inability and endurance of the nervous system.

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