RU2127547C1 - Device for evaluation of operator's activity - Google Patents

Abstract

FIELD: psychophysiological examinations. SUBSTANCE: device has vegetative function control unit 11, physiological state analyzer 16, program setting unit 18, response reaction input unit 22, reaction correctness analyzer 32, and mode of operation setting unit 34. Device is connected to evaluation signal forming 48 through recording unit 36. real process simulator includes data representation unit 24, test former 20 and light indicator 26. Individual result evaluation unit 40 consists of series-connected storage unit 42, average value calculation unit 44 and comparison unit 46. EFFECT: enhanced accuracy of operator's activity evaluation. 5 cl, 3 dwg

Description

 The invention relates to medical equipment, in particular to the automation of psychophysiological research, and may find application in the professional selection of persons in critical professions, mainly vehicle drivers.

 It is known that a specific feature of labor activity in the conditions of monotony is the periodic disconnection of the operator from the process of active production activity, which can significantly reduce the reliability of his work. Since the period of active activity is purely individual, its study requires the use of automated means of analyzing operator activity (L. Nersesyan, Psychological aspects of improving the reliability of managing moving objects, Promedek, Moscow 1992, pp. 146-147).

 A number of systems for professional selection are known that make it possible to present a series of stimuli in a certain order and record the response of the subject. So, in the invention (SU 888173, KhIIZhT, G 09 B 9/00, A 61 B 5/16, 1981) there is a simulator of real processes, which can be used as a block "reaction to a moving object" (RDO), the analyzer correctness reactions, control unit of autonomic functions (pulse, skin resistance (CGR) recorders), GNI tonus recorder. The simulator also contains an evaluation signal generator associated with the registration unit. The communication of the simulator with the subject is carried out through the input unit of responses. This device allows you to determine the reason for the decline in health immediately at the time of decline by examining the state of a number of the most important subsystems of the operator’s body.

 Known automated device for evaluating the effectiveness of operator activity in monotony (SU 1362446 A1, KPI and others, A 61 B 5/16, 1987). It is a complex equipped with a place for the subject, as well as the workplace of the experimenter. Incentives are automatically presented to the test subject and he should as soon as possible click on the corresponding button, and in addition, assess his subjective state also through the buttons. The device is equipped with a calculator that performs statistical processing of the temporal characteristics of the test subject's reaction. These data are displayed on the experimenter's console.

 The closest in technical essence and the achieved result is a device for professional selection of operators and determination of the level of vigilance under the influence of monotonous factors with the control of natural fluctuations in the level of wakefulness (RU 2037207 C1, NIIPKI automation equipment ..., G 09 B 9/00, 1995). The device contains a physiological state analyzer (according to RAG), a test subject’s console with a simulator of real processes and a response input unit and an analyzer of their correctness. In addition, there are blocks for setting the training program and operating modes, as well as an evaluation signal generator. This device also allows you to automate the determination of the moment when the level of wakefulness is reduced to a dangerous level, however, it conducts a limited determination of physiological parameters only by RAG.

 However, the prototype does not provide for the assessment of the psychophysiological state in personalized conditions with long-term observations of operators in dynamics. In addition, the psychophysiological state can be determined more reliably when registering the pulse of the operator.

 The objective of the patented invention is the creation of a device that allows you to conduct versatile studies of operator activity, using methods for assessing emergency preparedness for emergency action (GED) in conditions of monotony and fatigue, reaction to a moving object, determining stress resistance, tremor, etc., while ensuring the convenience of research as for subject, and for the experimenter.

 The technical result of the invention is the expansion of functionality while ensuring ease of use is achieved due to the fact that the device for evaluating operator activity includes a control unit for vegetative functions, the output of which is connected to a physiological state analyzer connected to one of the inputs of the program setting unit, the outputs of which are connected to one input of a simulator of real processes and a block of control of vegetative functions. There is a response input unit, one output of which is connected to another input of a real process simulator and a reaction accuracy analyzer connected to a mode setting unit connected to another output of the program setting unit and a recording unit connected to the output of the evaluation signal generating unit.

 An individual result evaluation unit with an average value calculation unit is introduced into the device. The real processes simulator contains an information presentation unit, a test driver and a light indicator, while the first output of the test driver is connected to the information presentation unit, the second to the indicator, and the third output connected to the reaction analyzer is the output of the simulator, the inputs of which are the inputs of the driver test.

 The individual result evaluation unit contains sequentially connected memory blocks, calculating the average value and comparison, and the input of the individual result evaluation unit is the input of the memory unit connected to the output of the analyzer of the correctness of reactions and to one of the inputs of the comparison unit, to the other input of which one of the outputs of the unit is connected setting modes, the output of the evaluation unit is the output of the comparison unit connected to the input of the evaluation signal generating unit.

 The response block may include a processor, a tremor and tapping test contact sensor located on the test subject’s remote control together with a light indicator, as well as a joystick input device, while the said contact sensor is connected to the processor through a chatter suppression circuit and a counter.

 Means for recording a skin-galvanic reaction can be made in the form of two electrodes connected to the processor through a converter of electrical resistance of the skin to an electrical signal and an analog-to-digital converter.

 The vegetative function control unit may include a processor and pulse recording means made in the form of an optocoupler with means for fixing the subject’s earlobe, while the light-emitting element of the optocoupler is connected to the generator, and the photodetector is connected to a circuit containing a current-voltage converter connected in series , a comparator and counter connected to the processor.

 The device may contain two personal computers connected by a data exchange bus, forming the workplace of the subject and the experimenter.

The invention is illustrated in the drawings, where:
in FIG. 1 shows a block diagram of a device using computers.

in FIG. 2 is a block diagram of a device;
in FIG. 3 is a block diagram of a test subject's console;
The basis of the invention are the following premises. It is known that for the purposes of railway transport, as an object of increased attention of operators of various professions, the main of which are the drivers and their assistants, the criteria for occupational selection are readiness for emergency action (GED) - integral quality, switching attention, emotional stability (stress resistance) , reliability in a state of fatigue. The same criteria can be used not only for psychological prognosis, but also for psychological examination. The patented device allows due to the used set of instrumental methods of applied psychology with a high degree of probability to evaluate operator activity in the conditions of monotony. The methods that can be implemented in the device include tests:
a. assessing the level of vigilance (GED) under conditions of monotonously acting factors, as well as in conditions of fatigue;
b. reaction to a moving object (RDO);
in. determination of stress tolerance;
Mr. feelings of time;
D. simple and complex visual-motor reaction;
e. assessment of the state of the cardiovascular system in terms of cardio intervals;
g. tremor scores;
and. assessment of individual psychomotor pace (tapping test);
K. assessment of the critical frequency of fusion of light flicker;
l assessment of the speed of switching attention and emotional stability.

 In FIG. 1 shows a block diagram of a device when implemented on the basis of software and hardware. The device includes a block 1 of the test, block 2 of the experimenter, connected by bus 3 data exchange. The test unit 1 includes a remote control 4, input means 5 (joystick), as well as a personal computer 6. Monitor 7 of computer 6 is used for presenting visual tests, sound speakers 8 are used for presenting audio information, and devices on remote control 4 are used for performing them. Computer 9 in block 2 of the experimenter is designed to control the process of evaluating operator activity, processing information, and documenting (block 10).

 A block diagram of the device is shown in FIG. 2. The device includes a unit 11 for monitoring vegetative functions with channels 12 for measuring pulse and 14 recording RAG connected to it. The output of block 11 is connected to the input of the analyzer 16 of the physiological state, the first output of which is connected to block 18 of the program. Block 18 is connected by one input to the test driver 20, to the other input of which a response input unit 22 is connected. The outputs of the shaper 20 are connected to the block 24 of the presentation of information, the indicator 26, and to the block 22 is connected to the contact probe 28 for recording tremor and tapping test. Elements 26, 28 are structurally placed on the panel 30 of the remote control 4 of the test person. The third output of the shaper 20 and the output of block 22 are connected to the first input of the reaction analyzer 32, to the other inputs of which the output of block 16 is connected, as well as the output of the mode setting block 34, the outputs of which are connected to the registration block 36. Block 34 is connected to an input keyboard 38.

 The individual result evaluation unit 40 comprises a series-connected memory unit 42, an average value calculating unit 44 and a comparison unit 46, the output of which is the output of the unit 40 and connected to the evaluation signal generating unit 48, the output of which is connected to the recording unit 36. In this case, the input of block 40 is the input of memory block 42 connected to the output of the analyzer 32, as well as to one of the inputs of the comparison unit, to one of which is connected one of the outputs of the mode setting block 34.

 In FIG. 3 is a block diagram of a test subject's console. The remote control 4 includes a processor 50 with channels 12 for measuring pulse, 14 for recording RAG, an electric contact probe 28 for registering tremor and tapping test, and a light indicator 26 for tests to determine the merger of the frequency of light flicker and tapping test. Channel 12 includes a generator 52 controlled by processor 5, loaded onto a light emitting diode 54. A photodetector 56 is placed in the zone of the latter, forming together with the diode 54 an optocoupler couple 58. The output of the photodetector 56 is connected to a series-connected converter 60, a comparator 62 and a counter 64, the output of which connected to the processor 60. The channel 14 registration RAG includes two electrodes 66 connected to the input of the Converter 68, the output of which is connected to the input of the ADC 70, the output of which is connected to the processor 50.

 To give the corresponding light signals, the indicator light 26 is connected to the indicator control unit 72. The contact probe 28 interacts with pads 74 (tapping test) and 76 (tremor), and in the latter case, different-sized holes 77 are made in the pit 76. Elements 28, 74, and 76 are connected to the chatter suppressor circuit 78 connected to the counter 80.

 All nodes 52, 60-64, 68-72, 78-80 are connected by appropriate buses to the processor 50 for synchronization of operation and data exchange.

 The device operates as follows.

 The computer keyboard 7 is not used in the process of work, it is necessary only at the stage of preliminary familiarization of the subject with the operating modes to select a specific technique.

 An optocoupler pair 66 of the pulse channel 12 is attached to the subject (the preferred location is the earlobe), as well as electrodes 66 of the RAG recording channel 14. The experimenter, by means of computer 9, selects a research mode (classification test a-l). Depending on the test method, the mode setting unit 34 gives the program setting unit 18 the corresponding commands for generating the tests in block 20.

 Depending on the received command, the work of the following blocks is initiated (see table).

 So, when the channel 12 is initiated, a signal about a change in current between the electrodes 66, the value of which is inversely proportional to the skin resistance, is converted into a voltage in the converter 68, and then to a digital code in the ADC 70. At the initial time, block 11 transmits the measured values to the analyzer 16 of the physiological state, in which the current value of the level of vigilance of the subject is determined. Depending on the current value of the vigilance level, the program setting unit 18 issues various programs to the test generating unit 20. In this case, the information presentation unit 24 displays the corresponding visual tests on the screen 7 of the computer 6, and the test signals and speech information on the sound columns 8.

 When channel 14 is initiated, the processor 50 includes a generator 52, which generates a 5 kHz square wave and powers the light emitting diode 54. The photodetector 56 of the optocoupler couple 58 detects a change in the light flux passing through the tissue and caused by the pulse wave. The signal from the photodetector is fed to the current-to-voltage converter 60, then to the comparator 62 and the counter 64. The comparator 62 compares the current voltage values with the threshold level set during tuning, and the counter 64 calculates the number of signal exceeded by a predetermined threshold value proportional to the number of pulse beats. The measured values are also sent to the analyzer 16.

The indicator control unit 72 (a red light emitting diode can be used as an indicator) provides two indicator operation modes:
- mode I of the tapping test timer and tremor assessment (test g, u), according to which the indicator has a constant glow in the interval of adjustable times 10-100 sec .;
- mode II presentation of flickers (test k).

 In mode I, using the mode setting unit 34 through the keyboard 38, the experimenter sets the time of the test. In this case, the indicator 26 is constantly on, and the recording channel with the contact probe 28, blocks 78, 80 is in the on state, that is, it is ready to count the number of probe closures at sites 74 or 76.

 The test subject is given a command to operate the probe (the invention does not relate to methods — they are known): each touch of the contact pad with the probe causes the appearance of pulses, the number of which, after suppressing bounce in block 78, is counted by the counter 80. Information from the counter output is fed to the input of the analyzer 32 of the correct reaction .

 To conduct all tests, a block 34 for setting modes is initiated through the keyboard 38 at the workplace (bl.2) of the experimenter, as well as block 18 for setting test programs. Block 18 controls the shaper 20 of the test. He displays on the block 24 visual information that is conveniently performed in the form of a monitor 7 of computer 6. In addition, the driver 20 provides an indicator 26. The responses of the test person from the probe 28, as well as the joystick 5, are sent to the analyzer 32 through the response input unit 22, which can be implemented on the basis of the computer 9 of the experimenter.

 On the screen of the block 24 of visual information, depending on the test, a discrete moving point (for the test according to method a) or other stimulating signals in the form of various light figures can be formed.

 The analyzer 32 of the correctness of the reactions compares the indicators obtained as a result of the tests with the reference values of the indicators, taking into account the physiological state of the subject coming from block 16. Block 34 carries out the binding of the data with the operating mode.

 From the output of the analyzer 32, the data are recorded in the memory unit 42, which contains a data bank for a particular subject. In block 44, the average value of the measured characteristic is calculated, for example, the average number of strokes with the probe 28 in the tapping test for the entire duration of the test. In comparison block 46, the current and average values are compared, and the difference between these values is output at the output of said block. In block 48 of the formation of the evaluation signal, a comparison of the signal with the specified standards. If the signal exceeds the normative by more than 10%, an unsatisfactory assessment is given to the subject, at a level of less than 10% - satisfactory. The results are stored in block 36 registration.

 Depending on the hardware and software base used, part of the blocks can be implemented programmatically based on the principles of constructing the system described in the present invention.

 The invention satisfies the conditions of patentability, being new, is characterized by an inventive step, as well as industrial applicability as described.

Claims (5)

 1. A device for evaluating operator activity, including a control unit for vegetative functions, the output of which is connected to a physiological state analyzer connected to one of the inputs of a program setting unit, the outputs of which are connected to one input of a simulator of real processes and a control unit for vegetative functions, a response input input unit , one output of which is connected to another input of a simulator of real processes and an analyzer of the correctness of reactions, connected to a mode setting unit connected to another output the house of the program setting unit and the registration unit connected to the output of the evaluation signal generating unit, memory and comparison units, characterized in that an individual result evaluation unit with an average value calculating unit is introduced into the device; the simulator of real processes contains an information presentation unit, a test driver and a light indicator, while the first output of the test driver is connected to the information presentation unit, the second to the indicator, and the third output connected to the reaction analyzer is the output of the simulator, the inputs of which are the inputs of the driver test; the individual result evaluation unit contains sequentially connected memory blocks, calculating the average value and comparison, and the input of the individual result evaluation unit is the input of the memory unit, connected to the output of the analyzer of the correctness of reactions and to one of the inputs of the comparison unit, to the other input of which one of the outputs of the unit is connected setting modes, the output of the evaluation unit is the output of the comparison unit connected to the input of the evaluation signal generating unit.  2. The device according to claim 1, characterized in that the response unit includes a processor, an electrical contact tremor and tapping test sensor, located on the test subject’s remote control together with a light indicator, as well as a joystick input device, wherein said electrical contact sensor is connected to the processor through the bounce suppression circuit and counter.  3. The device according to claim 1 or 2, characterized in that the vegetative function control unit includes a processor and means for detecting a skin-galvanic reaction made in the form of two electrodes connected to the processor through a skin electrical resistance to electrical signal and analog-digital converter converter.  4. The device according to any one of claims 1 to 3, characterized in that the vegetative function control unit includes a processor and pulse recording means made in the form of an optocoupler with means for fixing the subject’s earlobe, while the light-emitting element of the optocoupler is connected to generator, and photodetector - to a circuit containing a series-connected current to voltage converter, a comparator and a counter connected to the processor.  5. The device according to any one of paragraphs.1 to 4, characterized in that it contains two personal computers connected by a data exchange bus, forming the workplace of the test and the experimenter.

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