RU1777826C - Device for psychophysiological studies - Google Patents

Abstract

Device for psychophysiological examinations. Usage: the device is intended for obtaining objective data on the state and functions of the central nervous system, diagnosis of neuropsychiatric diseases, occupational selection and other tasks of medicine. The invention provides high reliability and objectivity of indicators of psychophysiological examinations due to the distinction and selection from the recorded signals of the examination of deliberately false signals caused by the oscillatory process (bounce) arising from the dynamic action of a response tool (conductive probe) or directly to the subjects psychophysiological response sensors, and isolating in the reaction processing channel only those impulses that are determined by the true reactions. SUBSTANCE: device for psychophysiological research contains a conductive probe. a psychophysiological response sensor unit and an indicator processing unit, an OR element, a protection interval setting unit and serially connected pulse generator, a blocking element, a protection unit, a coincidence element and a selection unit, the second input of which is combined with the input of the OR element, is connected to the output of the sensor unit psychophysiological reactions, with the output of the OR element connected to the second input of the protection unit, the second input of the blocking element connected to the output of the coincidence element, the second input of which is connected n with the output of the specifying protection intervals, and the output selection unit connected to the input parameters of the processing unit. 3 ill. Ё VI V | VI 00 to ON

Description

The invention relates to medical equipment, in particular to devices for psychophysiological studies. It can be used to obtain objective data on the state and functions of the central nervous system (CNS) of a person in solving problems of monitoring the performance and fatigue of the nervous system, diagnosing neuropsychiatric diseases, occupational selection and other medical tasks.

The problem of protection against false positives occurs in most devices for psychophysiological studies in which the recorded and practiced element of behavior (psychophysiological reaction) of the subject is his behavioral act associated with the dynamic action of the reaction sensor, for example, using a response tool in electric

contact with the reaction sensor, or when using electric buttons, touch or touch-contact pads as a reaction sensor.

These devices do not contain means of protection against false alarms when the subject is dynamically exposed to reaction sensors, which ultimately distorts the research results.

A Tremograph-trainer device is known, comprising a test subject’s response tool made in the form of a metal probe, a psychophysiological sensor of a test subject made in the form of a conductive labyrinth for conducting a response tool in it, and a subject’s reaction processing channel made in the form of a reaction number counter.

A disadvantage of the device is that false positives can occur during the examination of the test subject, both due to a change in the orientation of the response tool and its dynamic action on the reaction sensor.

The closest solution is a tremor test device containing a response tool in the form of a conductive probe, a block of reaction sensors made in the form of a conductive tablet with a groove cut in it in the form of a labyrinth, and a test reaction processing unit. In this device, the design of the response tool reduces the number of false positives that occur due to the deviation of the probe from a vertical position relative to the reaction sensor.

However, this device does not provide protection against other false positives, which play the most important role in the origin of the methodological error and lead, ultimately, to inaccuracies in psychophysiological studies. These are such false alarms that arise due to the oscillatory processes that always occur during the movement of the instrument and its dynamic interaction with the reaction sensor at the moments when the subject's reactions occur and cease. As a result of these oscillatory processes, when a subject performs one reaction, additional impulses appear that the channel for processing the reactions does not differ from the true reaction of the subject and processes it as ordinary, complete reactions. When processing false positives as a full-fledged reaction, the reaction processing channel produces distorted examination indices, the degree of distortion of which cannot be estimated, which reduces the objectivity and accuracy of the results and negatively affects the objectivity of the examinations.

The aim of the invention is to increase the reliability and objectivity of the obtained indicators of psychophysiological studies by eliminating false positives.

0 The goal is achieved in that a psycho-physiological research device containing a conductive probe, a psychophysiological response sensor unit, and an indicator processing unit introduces an OR element 5, a protection interval setting unit and serially connected pulse generator, a blocking element, a protection unit, a matching element, a selection unit, the second input of which, combined with the input of the OR element, is connected to the output of the block of sensors of psychophysiological reactions, and the output of the OR element is connected to the second input of the block while protection, the second BYPASS of the lock element is connected

5 with the output of a coincidence element, the second input of which is connected to the output of the block for setting the protection intervals, and the output of the selection block is connected to the input of the indicator processing unit.

0 in FIG. 1 shows a block diagram of a device; in FIG. 2 - diagrams of signals; in FIG. 3 is an example embodiment of an electrical circuit diagram.

The device comprises (see Fig. 1) a current-conducting probe 1, a reaction sensor unit 2, an indicator processing unit 3, a pulse generator 4 connected in series, a blocking element 5, a protection unit 6, a matching element 7 and a selection unit 8,

0 the output of which is connected to the block 3 processing indicators. The device also comprises a protection interval setting unit 9 connected to the second input of the coincidence element 7, and an OR element 10 connected to the second input of the protection unit 6. In this case, the output of the block 2 of psychophysiological response sensors is connected to the input of the OR element 10 and to the second input of the selection block 8, and the output of the coincidence element 7

0 is also connected to the second input of the blocking element 5.

The conductive probe 1 can be made, for example, as in the prototype, connected to a power source (see Fig. 3) and

5 serves to accomplish the test subject's task of conducting the probe 1 through the labyrinth of the reaction sensor unit 2, without touching the latter.

Block 2 of the reaction sensors is designed to receive the reactions of the test, i.e. involuntary touching of the probe 1 with the walls of the labyrinth of the block 2 of the reaction sensors during the movement of the probe 1. In particular, the number of such reactions is used to test the dynamic tremor and visual-motor coordination of the test subject with various movements of the hand: horizontal, vertical, along one or another diagonal, in areas of different curvature, for which it is necessary to have a differentiated characteristic, indicative for further comparisons.

It can be made in the form of several (for example, four) conductive plates with a groove cut out in each of them in the form of one or another labyrinth (for example, a straight line segment of various orientations, a sinusoid, etc.). In this case, the patient’s reaction is touch, i.e. the impact of the probe on the edge of the groove in the labyrinth.

The indicator processing block 3 is intended to obtain a quantitative assessment of the indicator that the subject has completed the survey task. The processing of reactions received in block 3 can be different, for example, it can be a differentiated calculation of the number of touches on each of the sensors of the sensor block 2. For this, the processing unit 3 can be performed, for example, in the form of a set of counters (on K176IE4 microcircuits) according to the number of reaction sensors of unit 2 connected to digital indicators as shown in FIG. 3, which allows for differential counting of the number of reactions.

The pulse generator 4 is designed to generate pulses used by the protection unit 6 to generate a time interval code between the pulses following from the output of the sensor unit 2. It can be performed, for example, in the form of a multivibrator assembled on a logical element OR NOT.

The blocking element 5 is designed to block the pulses of the generator 4 passing through it to the protection unit 6. It can be made in the form of a logical circuit (for example, on a K561LE5 chip) that implements the function of the SS SS GI. as shown in FIG. 3, where SB is the signal at the output of the blocking element 5, SS is at the output of the comparison element 7, GI is at the output of the 4 pulse generator.

The protection unit 6 is intended to form protection time intervals, i.e. intervals between the trailing edge of the previous and leading edges of the subsequent pulse from the output of the reaction sensor unit 2, if this interval is less than the threshold value, which ensures the blocking of false responses and the identification of the true reactions of the test person. It can be performed, for example, in the form of a counter 5 pulses having an initial setup (reset) input connected to the output of the OR element 10, and a counting input connected to the output of the blocking element 5, for example, on the chip K561IE20.

0 Matching element 7 is intended to compare two values - the number accumulated by the protection unit b during the time between two pulses following each other from the sensor unit 2 and the number set by the protection interval setting unit 9, and

to generate a resolution signal

 passing the next response impulse

(reaction) to the processing unit through block 8

breeding. It can be performed, for example, on a K561IE10 chip having two multi-bit inputs A and B. connected as shown in FIG. 3.

Block 8 selection is designed to pass through the element 7 matches on block 3

5 processing only those reactions occurring from the output of reaction unit 2 that are permitted by protection unit b. It can be performed, for example, in the form of a set of RS-triggers (according to the number of reaction sensors in

0 block 2), the S-inputs of which are connected to the corresponding sensors of block 2. a R-inputs are combined and connected to the output of the matching element 7 (Fig. 3).

Block 9 defining intervals of protection

5 is intended to set the threshold value of the protection interval for its subsequent comparison in element 7, coinciding with the time intervals between the trailing edge of the previous and leading edges

0 subsequent pulses generated by a block of 2 reaction sensors.

It was found that with various specific types of psychophysiological reactions of the subjects, the occurrence of two

5 consecutive true reactions of the test subject is possible only with an interval of time t, between reactions not less than a certain specific value, depending on the type of psychophysiological examination. This time d is a methodically justified value according to the criterion of the fundamental impossibility of the true reactions of the test subject with a shorter interval than m, and is taken as the threshold value of the protection interval specified by block 9.

Thus, pulses following each other with a time interval between the trailing edge of the first and the leading edge of the next smaller time t are related to deliberate false responses acting within the time interval of the current reaction. The exception of the passage of these pulses for processing to the processing unit 3 is carried out by the selection block 8 according to the control signals from the output of the coincidence element 7, formed taking into account the threshold value of the interval m specified by the block 9, and the sign of the completion of the current reaction is the absence of another pulse after the trailing edge of the previous pulse during the threshold time interval t, the value of which in the binary code is set using the block 9 of the defining the intervals of protection.

For this, block 9 (see Fig. 3) can be made in the form of a switching multi-bit node (according to the number of bits of the binary code at the output of the protection block 6), in which part of the bits is connected to logical 0 and part to logical 1 to generate the necessary binary code.

The OR element 10 is designed to convolve the pulses from the reaction sensors 2 and to start the count by the latching unit 6 at the end of each pulse. It can be made as a multi-input (according to the number of reaction sensors in block 2), as shown in FIG. 3 logical circuits OR on the chips K561LA8 and K561LN2.

The device operates as follows.

The switching elements of block 9 specify a threshold value g of the protection interval corresponding to this type of psychophysiological examination.

In the initial state, when the device is connected to a power source, the generator 4 begins to generate service pulses, and at the output of block 9 a binary code of the protection interval is generated (see Fig. 2a). In the absence of test reactions at the outputs of the reaction sensors of unit 2, there are no signals, as a result of which the signal does not arrive at the second input of the protection unit 6 from the output of element 10. In this case, the protection unit b begins to accumulate pulses arriving at its first input through the blocking element 5 from the pulse generator A. This accumulation occurs until the binary code of the accumulated number coming from the output of the protection unit 6 to the coincidence element 7 does not coincide with the code of the specified protection interval present at the second input of the coincidence element 7 (from the output of block 9). At the moment of coincidence

at the output of element 7, a coincidence signal appears, which is fed to the second input of blocking element 5 and prevents the passage of pulses from generator 4 to

the first input of the protection unit 6. As a result of this, the state of the protection unit 6 ceases to change and a match signal is stored at the output of the match element 7. This signal also arrives at the reset input of selection block 8, which leads to its cleaning. This state of the device is maintained until a reaction occurs.

The test subject is instructed to complete a typical task. His request

5 grab the probe in your hand, place it at the beginning of the slot of one of the sensors in block 2 and draw it along the slot, without touching its walls, at the ends of the slot. He must perform such an operation sequentially

0 with each sensor of a block of 2 reactions.

When the test subject conducts a probe along the slot of one of the sensors of block 2, involuntary reactions appear in the form of touches caused by tremor of the test person’s hand. errors in coordination of movement, etc. At the same time, at the output of the corresponding sensor of unit 2, and hence at the output of the OR element 10, pulses of interaction of the reaction tool by the sensor 2 of psychophysiological reactions appear. Due to the dynamism (oscillatory process) of this interaction, each reaction is represented not by a single pulse, but by a certain sequence (series) of them, most often as shown in FIG. 2s In this case, the leading edge of the first pulse represents the true moment of the onset of the reaction, while the remaining pulses are additional false pulses.

On the leading edge of the first pulse of the series, at the input of the initial installation (from the output of the OR element 10, Fig. 2d), the accumulated number is reset in the protection unit 6.

5 As a result of this, the match condition in the match element 7 is violated and the match signal at the output of the element 7 is canceled (Fig. 2e). This results in a reset signal being removed from the selection unit 8.

0 As a result, the leading edge of the first pulse received from one of the sensors of block 2 in the corresponding channel of selection block 8 sets it to state 1 (see Fig. 2f). This means that a true response has been accepted for subsequent processing. In the indicated embodiment. processing unit 3, this processing consists in counting the number of reactions: when one of the channels of the selection unit 8 is set to state 1, on the corresponding counter of unit 3

a signal arrives leading to an increase in the contents of the counter by one and highlighting of the resulting number on the corresponding digital indicator of block 3 (see Fig. 2e).

At the same time, violation of the matching condition in the matching element 7 leads to the fact that the blocking from the blocking element 5 is released and the pulses from the pulse generator 4 again begin to arrive at the counting input of the protection unit 6. However, while the high level of the first pulse of the series is maintained at the output of the OR element 10, the block

6 is in a reset state and does not accumulate impulses arriving at it. As soon as the pulse at the output of the OR element 10 is removed, the protection unit b begins to accumulate service pulses from the output of the generator 4. When the next pulse arrives at the reset input of the protection unit 6 from the output of the OR element 10, the next accumulated number is reset in the protection unit 6. Thus, over the entire series of pulses arising from interaction with reaction sensors, the coincidence conditions in element 7 cannot be satisfied, because the time between the trailing edge of the previous and leading edges of the subsequent pulses from the output of the OR element 10 is not enough to accumulate in block 6 a number equal to the threshold value set by block 9. As a result of this, throughout the reaction, there is no match signal at the output of the match element 7, which ensures that the state of the selection block 8 remains unchanged, i.e. skipping block 8 selection on block 3 processing indicators only one pulse corresponding to the leading edge of the true reaction signal (see Fig. 2e). Thus, the indicator processing unit 3 adds only one unit in the corresponding reaction counter.

If the reaction has stopped and there are no pulses at the output of the OR element 10, then the signal does not arrive at the input of the initial installation of the protection unit b and the unit 6 continues to accumulate the pulses of the generator 4. During the time t, after passing the trailing edge of the last pulse in the protection unit 6, a number equal to set by block 9, as a result of which, after this time m, a match signal appears at the output of the match element 7. This signal blocks the passage of pulses from the generator 4 to the protection unit 6, as a result of which the state of the protection unit 6 and the element

The coincidence ceases to change until the leading edge of the first impulse of the next test subject arrives. In addition, the coincidence signal is fed to the reset input of the selection unit 8 and clears its contents, ready to receive the next reaction code 5.

Thus, only true reactions are received to the processing unit 3 without the false bounce signals accompanying each reaction. AT

0 as a result of this, in the processing unit 3, the number of reactions accumulates, i.e. the number of interactions of the response tool (probe) with the block of the reaction sensor 2 (separately for each of the sensors of the block 2 in

5 corresponding channel of the processing unit 3).

The described device can be successfully used not only for the study of tremor, but also for the implementation of other

0 methods of psychophysiological examination of the patient. In this case, other designs of the block of sensors 2 (push-button, touch, etc.) can be used according to the claimed scheme. In this case, in block 9

5, a different value of the protection interval is set corresponding to the type of examination and the type of block of reaction sensors used.

Thus, when using buttons (contact areas) or other reaction sensors as reaction sensors, another number of g is encoded on the block 9 for setting the protection intervals, which is equal to the threshold interval for the true tests to pass. covert when interacting with specifically

5 selected sensor type. The indicated thresholds for the protection intervals are currently experimentally established for all types of psychophysiological response sensors.

0 Thus, the inventive device by comparing the time interval between the trailing edge of the previous pulse and the leading edge of the next pulse coming from the output of the sensors

5 reactions, with a threshold value of this interval, set for each particular type of psychophysiological examination, and the formation of the corresponding control signal, provides protection against false alarms associated with chatter during dynamic interaction of the response tool, or the test subject with the reaction sensor.

5 Due to this, the reliability and objectivity of the received- significantly increased. survey indicators by eliminating obviously false signals recorded in the prototype, the number of which cannot be estimated.

Claims (1)

SUMMARY OF THE INVENTION A device for psychophysiological research comprising a conductive probe, a block of psychophysiological reaction sensors and a processing unit for indicators, characterized in that, in order to increase the reliability and objectivity of the obtained indicators by eliminating false alarms, an OR element is introduced into it, a unit for setting protection intervals and series-connected pulse generator, blocking element, protection unit, coincidence element, selection unit, the second input of which, combined with the input of the OR element, is connected to the output of the psychophysiological response sensor unit, the output of the OR element is connected to the second input of the protection unit, the second input of the blocking element is connected to the output of the coincidence element, the second input which is connected to the output of the protection interval setting unit, the output of the selection unit is connected to the input of the indicator processing unit.