RU2051619C1 - Device for psychophysiological examinations - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device comprises a decision-analyzing unit which carries out separate assessment of the taken decision after successful realization of a task or after a failure of its realization, and a unit for recording the decision taken which makes it possible to estimate the degree of subjective confidence in the effect expressed in the delay of realizing an erroneous decision (differentiated estimation of the realization of the decision taken which resulted in a success or failure in carrying out the task). EFFECT: improved design. 3 cl, 1 dwg

Description

 The invention relates to medicine, namely to devices for evaluating the characterological and typological properties of the subject, and can be used for career guidance and professional selection of operators.

 Known reflectometer for evaluating the response time of the operator, providing a measurement of the quality of perception of stimuli and the number of erroneous responses of the subject.

 A device for studying the ability of probabilistic forecasting of a person is known, which allows to obtain information about the average response time and determine the degree of subjective confidence of the subject.

 A device for psychophysiological research is known, containing a control unit for presenting stimulus effects, connected to a response accuracy determination unit, the inputs of which are connected to the outputs of the reaction signal input unit, and also connected through the task complexity control unit from input units of the task complexity signal.

 Unlike the prototype, the proposed device allows to obtain not only a qualitative, but also a quantitative assessment of the decision-making implementation process, reflecting the model of the future result.

 The objective of the invention is to assess the subjective confidence of the decision on the basis of anticipatory reflection, as a reflection of the expected future or anticipation.

 Significant differences are: the presence of a decision analysis block designed to assess the implementation of the decision taken separately for cases of a correctly made decision and an incorrectly made decision, the presence of a block of registration of decisions made, which allows assessing the subjective confidence in the decision made by the effect expressed in the delay in the implementation of the wrong decision (the decision to increase the complexity of the task led to failure to complete it). Advance reflection of failure leads to uncertainty of its implementation and an increase in the latent period due to the appearance of anxiety anxiety, a decrease in the significance of the signal for a given experimental situation, as well as a decrease in interest and attention to this task. In the case of an anticipatory reflection of luck, its implementation is accelerated and the necessary action is facilitated.

 The goal is achieved in that the device for psychophysiological research, containing a stimulus presentation unit, connected to a response accuracy determination unit connected to a reaction signal input unit and through a task complexity control unit to a task complexity signal input unit, further comprises a decision decision analysis unit, a first input which is connected to the output of the reaction signal input unit, the third input is connected to the stimulus presentation unit, and the fourth input is connected to the response accuracy determination unit Bani and recording unit taken decisions, the first four inputs of which are connected to respective outputs of the decision analysis unit, and the fifth input is the input for setting the initial state of the device. In this case, the decision analysis module includes the first trigger, the inputs of which are the corresponding inputs of the reverse counter of this block, the third input of which is also the third input of the reverse counter, whose output is connected to the first through the R-input of the second trigger and the first inputs of the third and fourth circuits and the second outputs of the decision analysis unit; the fourth input of the reverse counter is connected to the first input of the decision analysis block, the second inputs of the third and fourth circuits And through the third trigger are connected to the fourth input of the decision analysis block, the R-input of the trigger is connected through an inverter, the third inputs of the third and fourth circuits AND are combined and are the third input of the decision analysis block, the decision decision registration block includes four series-connected indicators, a decoder and a counter, the information inputs of which are the corresponding inputs of this block, and the second inputs of the first and third counters are combined and are the input of the installation of the initial state of the device.

 The drawing shows a functional diagram of the proposed device.

 The device includes a decision analysis analysis unit 1, a decision decision registration unit 2, stimulus presentation unit 3, a response accuracy determination unit 4, a task complexity control unit 5, a response signal input unit 6, a task complexity input signal unit 7. Blocks 3-7 are of the same name with the blocks of the prototype, with the same numbers and functionality. Block 3 is made in the form of a pulse generator and a counter with a variable conversion factor. Block 4 is made in the form of a fifth element And connected in series, an indicator of a moving object and a sixth element I. Moreover, the second input of the sixth element And, corresponding to the third input of the block, the second input of which is connected to the second output of the reaction signal input block (block 6), made in the form of series-connected start and stop keys and corresponding pulse shapers, as well as a trigger and an OR element. The starter key and the pulse shaper for starting the device are the first output of block 6, the stop key and the pulse shaper for stopping a moving object are the second output of this block. Block 5 is made in the form of series-connected indicator, decoder and reversible counter, one input of which is connected to block 7, made in the form of series-connected key and pulse shaper. The decision analysis unit 1 contains a first trigger 8 and a reverse counter 9 connected in series, the first three inputs of which are the corresponding inputs of this block, the output of the reverse counter 9 through the R input of the second trigger 10 and the first inputs of the third and fourth circuits And 11 and 12 are connected to the first and second outputs of the decision analysis block; the second inputs of the third and fourth circuits And 11 and 12 through the third trigger 13 are connected to the fourth input of this block, while the R-input of trigger 13 is connected through the inverter 14, the third inputs of the third and fourth circuits And 11 and 12 are combined and are the third input of the analysis unit the decision, the first input of the block is connected to the fourth input of the reverse counter 9.

 Block 2 registration of the decision includes four series-connected indicators 15-18 time of the latent period, the decoder 19-22 and the counter 23-26, the information inputs of which are the corresponding inputs of this block, and the second inputs of the counters 23 and 25 are combined and are the input 27 setting the initial state of the device.

 The device operates as follows.

 Input 27 receives the impulse to set the device to its original state. In this case, the trigger of block 6 is reset, the counters 23 and 25 are reset, the reverse counter of block 5 is set to the "all units" state, the indicator of the moving object of block 4 is in the initial state. From the output of the clock pulse generator of block 3, signals are sent to the counting input of the reverse counter, constant pulses are sent to the counting input of the counter with a variable conversion factor of block 3, a digital signal of the direct code of the reverse counter of block 5 is received to the control input of this counter, determining in the initial state of the device maximum conversion factor possible for him, corresponding to the minimum difficulty level of the upcoming task. From the first output of the trigger of block 6, the logical "0" is supplied to the second input of the third element And block 4, which prevents the passage of pulses from block 3 to the first input of the indicator of a moving object of block 4, the arrow of which is stationary in the initial state. The test subject by pressing the button of the block 7 acts on the pulse shaper of this block, the signal of which is fed to the subtracting input of the reversible counter of the block 5 and sets the conversion factor of the counter of the block 3 in accordance with the complexity of the task that the subject is supposed to complete. At the same time, the signal enters the third input of the reverse counter 9 and resets it, and through the S-input of trigger 8 to the first input of the reverse counter 9, which begins a direct countdown of the latent period. Next, the test subject by pressing the start key of block 6 acts on the corresponding pulse shaper, from the output of which through the trigger of this block a logic unit signal is supplied to the second input of the fifth element AND of block 4, which allows the passage of pulses from block 3 to the first input of the indicator of the moving object of block 4, the object which starts moving at a speed proportional to the digital code of the current task complexity. In this case, the signal of the logical unit from the first input of block 6 also comes through the R-input of trigger 8 to the second information input of the reverse counter 9, switching its operation from direct count to reverse. At the same time, the signal from the first input 6 of the block enters the S-input of the second trigger 10, setting the unit state of the first inputs of the third and fourth circuits And 11 and 12.

 In accordance with the instruction, at the moment the moving object coincides with the zero position of the scale, the test subject presses the stop key of block 6. At the same time, a logical zero signal is sent to the third AND element from the third input of block 4 through the OR element and the trigger of this block, blocking the passage of pulses to indicator of a moving object of this block, the object of which stops. At the same time, from the second output of block 6, a signal is supplied to the second input of the sixth element AND of block 4. If the moving object is outside the zone of the reaction accuracy tolerance predetermined by the experimenter, a logic unit signal is generated at the input of block 4 and fed to the summing input of the reversing counter block 5 and the fourth input of block 1 analysis of the decision. At the same time, the state of the reverse counter of block 5 increases by one, which increases by this value the conversion factor of the counter of block 3, decreasing the pulse repetition rate at the input of block 4, and decreases the code of the current task complexity by 1 point. The signal from the output of block 4 also goes to the fourth input of the registration block of the adopted decision 2, corresponding to the information input of the counter 26, which registers the fact of a wrong decision, which is displayed on the indicator 18 through the decoder 22, and, when received at the S-input of the trigger 13, the signal is received to the second input of the circuit And 12, through which signals from block 3 begin to flow to the second input of block 2, corresponding to the first input of the counter 25, which starts the countdown of the implementation of the wrong decision. In this case, the signal from the output of the unit 4 for determining the accuracy of the response through the inverter 14 is fed to the R-input of the trigger 13 and blocks the signal from passing through the third circuit And 11 to the first input of the unit 2 for registering the decision, and when the inverted signal is received at the third input of the unit 2, the inverted signal is not registered on the counter 24.

 After the state of the reverse counter 9 is reset to zero, a signal is output from its output to the R-input of the second trigger 10, blocking the passage of pulses through the fourth circuit And 12 to the information input of the counter 25, which ends the countdown of the implementation of the wrong decision, which is through the decoder 21 indicated on indicator 7.

 Then the subject makes a decision either to increase the complexity of the next task (if he disagrees with the task complexity decrease by 1 point, he can increase it by any admissible number of times using the key of block 7, since according to the instruction, the task of the subject is to achieve the maximum possible over the entire series of tasks for them the number of points) and then, after pressing the button of block 7, the status code of the reverse counter of block 5 will change in the direction of decreasing the conversion factor of the counter of block 3 and the pulse frequency at the first input of the block eye 4 will increase, and the first input of trigger 8 receives a signal that characterizes the next cycle of the device and determines the direct code of the reverse counter 9. Next, the test person presses the start key of unit 6 and proceeds to the next task, and the second input of trigger 8 receives a signal setting the reverse stroke of the reverse counter 9.

 If the moving object at the time of stopping is within the tolerance range of the reaction accuracy, from the second output of the reaction signal input block 6, a signal is also sent to the third input of block 4, the output of which is set to a zero signal, which, passing through the inverter 14, is fed to the trigger R input 13, from the output of which the signal enters the second input of the third circuit And 11, through which the signals pass to the information input of the counter 23, which starts the countdown of the correctly made decision. In this case, the signal from the output of the response accuracy determination unit 4, arriving at the S-input of trigger 13, blocks the signal from passing through the fourth circuit And 12 to the second input of the decision-making registration unit 2, and arriving at the third input of unit 2, corresponding to the information input of the counter 24, registers the fact of the right decision.

 After the state of the reverse counter 9 is reset, a signal is output from its output to the R-input of trigger 10, blocking the passage of pulses through the third circuit And 11 to the information input of the counter 23, which ends the countdown of the implementation of the correctly made decision, which is indicated through the decoder 19 on indicator 15.

 At the end of the study, the arithmetic mean value of indicators 15 and 17 is calculated (the accumulated value is divided by the value of indicators 16 and 18, respectively), the sum of which is an indicator of the time for the implementation of correctly and incorrectly made decisions, and the difference is an indicator of the subjective confidence of the decision made.

 The proposed device, based on the theory of anticipatory reflection as a reflection of the expected future or anticipation, carrying out a separate assessment of decision making after successful completion of the task and failure to complete the task, as well as recording the decision made, allows you to quantify the degree of subjective confidence in the effect expressed in the delay in implementation incorrectly the decision made (a differential assessment of the implementation of the decision that led to the success or failure of the assignment).

Claims (3)

 1. DEVICE FOR PSYCHOPHYSIOLOGICAL RESEARCH, containing a stimulus presentation unit, the output of which is connected to the first input of the response accuracy determination unit, the second and third inputs of which are connected to the outputs of the reaction signal input unit, the output of the response accuracy determination unit is connected to the first input of the task complexity control unit, the second input of which is connected to the output of the input unit of the task complexity signal, and the output of the task complexity control unit is connected to the input of the stimulus presentation block, input b The reaction signal input input, the fourth input of the response accuracy determination unit and the third input of the job complexity control unit are the input of the device, characterized in that a decision-making registration unit and a decision-making analysis unit are introduced into it, the first, second, third and fourth inputs of which are connected respectively with the output of the input block of the signal for the complexity of the task, one of the outputs of the input block of the reaction signal, the output of the stimulus presentation block, the output of the response accuracy determination block, the first four inputs Yes, the decision-making registration unit is connected to the outputs of the decision-making analysis unit, and the fifth input of the decision-making registration unit is connected to the input of the device.  2. The device according to p. 1, characterized in that the decision analysis module includes a first trigger, the inputs of which are the corresponding inputs of the block, and the outputs are the corresponding inputs of the reverse counter of the decision analysis module, the third input of which is also the third input of the reverse counter, whose output is through the second trigger and the first inputs of two AND elements connected to the first and second outputs of the decision analysis unit, the fourth input of the reverse counter is connected to the first input of this unit ka, and the second inputs of the two AND elements are connected through the third trigger to the fourth input of the block, while the R-input of the trigger is connected through the inverter, the third inputs of the two AND elements are combined and are the third input of the block.  3. The device according to claim 1, characterized in that the decision-making registration unit includes four sequentially connected indicators, a decoder and a counter, the information inputs of which are the corresponding inputs of this block, and the second inputs of the first and third counters are combined and are the input of the device.

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