SU1188749A1 - Device for simulating human-operator activity - Google Patents

Abstract

A DEVICE FOR MODELING THE OPERATION OF A HUMAN OPERATOR, comprising a random pulse flow generator, first, second and third triggers, three AND elements, a random time delay block, a time interval sensor, a time interval converter code, an incoming wake counter, a served wake counter and an adder, the output of the random pulse generator is connected to the first input of the first element I, the output of which is connected to the input of the counter of the incoming application and the first input of the second element I, the output of which connected to the single input of the first trigger and the input of the random time delay block whose output is connected to the zero input of the first trigger whose output is connected to the second input of the second element And the time interval-code converter whose output is connected to the input of the adder, the sensor start input time intervals, the zero input of the second trigger and the single input of the third trigger are combined and are the device start input, the output of the time interval sensor is connected to the single input of the second trigger Ser, the output of which is connected to the first input of the third element I, the second input of which is connected to the output of the random time delay block, and the output is connected to the reset input of the sensor of time intervals and to the zero input of the third trigger, the output of which is connected to the second input of the first element I, different the fact that, in order to expand the functionality of the device by providing the possibility of determining the probability of a timely and error-free solution of the problem by the operator, it additionally contains a sensor radial numbers, code-voltage converter, Schmidt trigger, (L fourth trigger, fourth AND element and delay element, the output of the second And element connected directly to the zero input of the fourth trigger and the trigger input of the random number sensor, and through the delay element to the installation input of the random number sensor, the output of which is connected to the input of the code-voltage converter, the output of which is connected to the input of the Schmidt trigger, whose output is connected to the first input of the fourth element, And the second input to It is expensively connected to the output of the random time delay unit, and the output is connected to the input of the counter of the serviced quotations.

Description

The invention relates to computing, in particular, to devices for simulating the human operator of a man-machine system (SMM). The device makes it possible to determine the likelihood of the current problem solving and the workload of the operator, which characterizes the intensity of his work. The purpose of the invention is to expand the functionality of the device by making it possible for the operator to determine the probability of a timely and error-free solution of the problem. The drawing shows a functional diagram of the device. The Device contains a generator of 1 tea pulse flow, a counter 2 of the incoming wakes, a second element I 3, a first trigger 4, a block 5 random time delay, a sensor 6 time intervals, a second trigger 7, a third element I 8, a third trigger 9, the first element I 10 transducer time interval code 11, adder 12, counter 13 served by the wok, sensor 14 random numbers, converter 15 code-voltage, Schmidt trigger 16, fourth trigger 17, fourth AND 18 element and delay element 19. The operator is single-channel SMO with failures . The generator 1 of a random stream of pulses simulates an input flow of a flow. Counter 2 counts the total number received by the operator for servicing. The block of random time delays 5 simulates the random service time of the application by the operator. The adder 12 calculates the time of the operator's service for the stock. The total simulation time is set by means of a sensor of 6 time intervals. The sensor of random numbers 14, the converter 15 code - voltage and Schmidt trigger simulates the process of safe (erroneous) work of the operator. The device works as follows. In the initial state, the first 4 and third 9 triggers are in the zero state, and the second 7 and fourth 17 triggers are in the single state. On the sensor 6 of time intervals, an approximate simulation time is accumulated, and according to the "Start" signal, it begins to count down the time. The same signal arrives at the second 7 and third 9 triggers. Moreover, it throws the trigger 7 into the zero state, ensuring the supply of the forbidden potential to the element 8 and the trigger 9 into the single state, ensuring the supply of the resolving potential of the element 10. The generator 1 of a random stream of pulses is intended to simulate flows in the form of a series of pulses separated by random time intervals having any desired distribution law. The pulses from the generator L through the open element AND 10 arrive at counter 2, which counts the total quantity of the quotation and the element AND 3. A second potential is fed to the second input of element 3 from the output of trigger 4, which is in the zero state, so the first pulse generator 1 passes element 3, throws trigger 4 into a single state, starts block 5 of the random time delay and random number sensor 14, and sets trigger 17 to the zero state. Now, from the output of trigger 4 to the second input of element 3, the inhibitory potential is applied and while trigger 4 is in a single state "1 (the operator’s process is simulated when solving the problem), not a single pulse generated by the random flow generator pulses through the element And 3, i.e. while the operator is engaged in the solution of the next task, all subsequent ones arising at this time will be denied service. The point in time when the operator is ready to solve the next one is determined by the response time of the random time delay block 5. The impulse from block 5 triggers overturns into the well-left state, which ensures the supply of the resolving potential to the second input of the element 3. This simulates the timeliness of the task. The accuracy of the problem solution by the operator is characterized by the magnitude of the error allowed by the operator. In relation to operator activity, the magnitude of the error is usually distributed according to normal law. Therefore, the sensor 14 pulse from the output of the element And 3 forms the code of the number, distributed according to the normal law. This code is converted by a converter-voltage code 15 into a voltage that is fed to the input of the Schmidt trigger 16. Typically, the problem can be solved if the error value does not exceed a certain threshold value. The threshold value of the error value stores the Schmidt trigger 16, which is triggered by the leading edge of the voltage pulse from the converter 15, if its value exceeds the threshold value. This ensures that trigger 17 is set to one state. On the falling edge of the voltage pulse from converter 15, Schmidt's trigger is set to its initial state, and the voltage drop arising at its output in this case does not affect the trigger state 17. Trigger 17 provides the supply of the inhibitory potential to the input element And 18. In this case, the pulse from the random time delay block 5 will not pass to the counter 13, but only flips trigger 4 to zero. -code 11 converts the time of the operator (the time during which the trigger

Claims (1)

DEVICE FOR MODELING HUMAN OPERATOR ACTIVITY, containing a random pulse flow generator, first, second and third triggers, three AND elements, a random time delay unit, a time interval sensor, a time interval converter — code, a counter of received requests, a counter of served requests and an adder, an output of the generator a random pulse stream is connected to the first input of the first element And, the output of which is connected to the input of the counter of applications received and the first input of the second element And, the output of which is connected with a single input of the first trigger and an input of a random time delay unit, the output of which is connected to the zero input of the first trigger, the output of which is connected to the second input of the second element And and the input of the converter, the time interval is a code, the output of which is connected to the adder input, the sensor trigger input time intervals, the zero input of the second trigger and the single input of the third trigger are combined and are the input of the start of the device, the output of the time interval sensor is connected to the single input of the second trigger, the output to is connected to the first input of the third AND element, the second input of which is connected to the output of the random time delay unit, and the output is connected to the reset input of the time interval sensor and to the zero input of the third trigger, the output of which is connected to the second input of the first AND element, characterized in that in order to extend the functionality of the device by allowing the determination of the likelihood of timely and error-free solution to the problem statement, it added soder- _Λ INH random number generator, § code-to-voltage converter, Schmidt trigger, fourth trigger, fourth AND element and delay element, the output of the second AND element connected directly to the zero input of the fourth trigger and the trigger input of the random number sensor, and through the delay element to the installation input of the random sensor numbers, the output of which is connected to the input of the code-voltage converter, the output of which is connected to the input of the Schmidt trigger, the output of which is connected to the first input of the fourth element And, the second input of which is connected to output b lock of a random time delay, and the output is connected to the input of the counter of served requests. >