RU133633U1 - DEVICE FOR MODELING MASS SERVICE SYSTEMS - Google Patents

Abstract

A device for simulating queuing systems containing the first and second generators of a random stream of pulses, a multichannel block of random time delays, the first, second and third counters, two OR elements, a multi-input AND element, an AND element, a down counter, the first generator of a random pulse stream is connected to the first counter and the second input of the AND gate, and the output of the second AND gate is connected to the input of the second counter, the output of the second random pulse stream generator is connected to the second input of the first OR gate, the output of the multichannel block of random time delays through the second OR gate is connected to the subtractive input of the reverse counter, the output of which is connected to the input of the multi-input element And, characterized in that a second multichannel block of random time delays, the fourth counter and the element AND with an inverse input are added to it, the inverse input of which is connected to the first input of the element And and the output of the multi-input element And, in the second input of the AND element with an inverse input is connected to the output of the first generator of a random stream of pulses, and the output is connected to the input of the first multichannel block of random time delays and the first input of the first OR element, the output of which is connected to the summing input of the reversing counter, the output of the second generator of a random stream of pulses is connected with the input of the third counter and the input of the second multichannel block of random time delays, the output of which is connected to the second input of the second OR element, the input of the fourth counter is connected to the output of the first multichannel block of random time delays

Description

The utility model relates to specialized means of computer technology and can be used to model queuing systems that simulate the operation of automated control systems.

A device is known for modeling queuing systems [SU No. 151703 A1, class G06F 15/20, 10.23.1989], comprising a request flow generator, a counter of received requests, a counter of requests that have been denied service, a block of random time delays, a reverse counter of busy channels reversible queue length counter, four AND elements, three prohibition elements, two OR elements, the output of the application flow generator is connected to the counting input of the counter of incoming applications, the first input of the first AND element and the information input of the first element beyond the bushing, the control input of which and the second input of the first element And are connected to the output of the second element And, the inputs of which are connected respectively to the discharges of the outputs of the reverse counter of busy channels, the summing input of which is connected to the output of the first inhibit element and the first input of the first OR element, the second input of which the subtracting input of the reverse counter of the queue length is connected to the output of the third AND element, the first input of which and the control input of the second inhibit element are connected to the output of the second OR element, the odes of which are connected respectively to the discharge outputs of the reverse counter of the queue length, the output of the first OR element is connected to the input of the random time delay unit, the output of which is connected to the second input of the third AND element and the information input of the second inhibit element, the output of which is connected to the subtracting input of the reverse counter of busy channels , the output of the first element And is connected to the information input of the third prohibition element and the first input of the fourth element And, the output of which is connected to the counting input a denial of service counter, summing the input of the reverse queue length counter connected to the output of the third prohibition element, a waiting queue length code generator and a comparison circuit, the information inputs of the first group of which are connected respectively to the digital outputs of the reverse counter of the queue length, and the information inputs of the second group connected respectively to the information outputs of the waiting code generator of the queue length, the output of "Equal to" the comparison circuit is connected respectively to the control input the third element of the ban and the second input of the fourth element, and the output of the second element And is connected to the start input of the waiting code generator of the queue length.

The disadvantage of this device is that it is not possible to study the behavior of real queuing systems (QS) depending on the laws of distribution of applications and the laws of distribution of their services, since it is not known how many applications are served and how many applications are denied service in a certain period of time.

Closest to the claimed is a device for modeling queuing systems [SU No. 450178 A1, class G06F 15/20, 11/15/1974], containing the first random pulse stream generator connected to the first counter and through the "Prohibition" circuit with a multi-channel random time block delays and the summing input of the reversible counter associated with the comparison unit, the output of which through the first "OR" circuit is connected to the control inputs of the "Prohibition" circuit and the "I" circuit, the signal input of the "I" circuit is connected to the input of the first counter, and the output the "And" circuit is connected to the second counter, and it contains a multi-input "And" circuit, a third counter, a pulse generator and a second random pulse stream generator connected to another input of the first "OR" circuit and one input of the pulse generator, the output of which is connected to the input the third counter and through the second OR circuit, with the subtracting input of the reverse counter, the bit outputs of which are connected through the multi-input circuit AND to the other input of the pulse generator, and the output of the multi-channel block of random delays is connected "OR" the other input of the second circuit.

The disadvantage of this device is that it performs the simulation of a system consisting of several service channels in the event of a malfunction of the entire service system at the same time, which is almost unlikely, and, as a result, the termination of service applications.

The technical result is the expansion of functionality by providing the ability to simulate a system consisting of several service channels in the event of a malfunction of one or more channels without stopping service applications.

The technical result is achieved by the fact that in a device for modeling queuing systems containing the first and second generators of a random pulse stream, a multi-channel block of random time delays, the first, second and third counters, two OR elements, a multi-input element And, an element And, a reverse counter, the first random pulse stream generator is connected to the first counter and the second input of the element And, and the output of the second element And is connected to the input of the second counter, the output of the second random stream generator and pulse is connected to the second input of the first OR element, the output of the multi-channel block of random time delays through the second element OR is connected to the subtracting input of the reverse counter, the output of which is connected to the input of the multi-input element And, the second multi-channel block of random time delays, the fourth counter, and the And element are added an inverse input, the inverse input of which is connected to the first input of the element And and the output of the multi-input element And, the second input of the element And with the inverse input is connected to the output of the first generator of a random pulse stream, and the output is connected to the input of the first multi-channel block of random time delays and the first input of the first OR element, the output of which is connected to the summing input of the reverse counter, the output of the second generator of the random pulse stream is connected to the input of the third counter and the input of the second multi-channel block of random time delays, the output of which is connected to the second input of the second OR element, the input of the fourth counter is connected to the output of the first multichannel case block time delays.

The introduction of these additional elements and the sequence of their connection makes it possible to simulate a system consisting of several service channels in the event of a malfunction of one or more channels without stopping the service of applications.

A device for modeling queuing systems (Fig. 1) contains, a first generator 1 of a random pulse stream, an AND 2 element with an inverse input, an And 3 element, a first multi-channel block 4 random time delays, the first OR element 5, the second OR element 6, reversible counter 7, multi-input element And 8, first counter 9, second counter 10, second random pulse stream generator 11, second multi-channel block 12 random time delays, third 13 and fourth 14 counters.

A device for modeling queuing systems (Fig. 1) contains the first 1 and second 11 random pulse stream generators, the first 4 and second 12 multi-channel blocks of random time delays, the first 9, second 10, third 13 and fourth 14 counters, two elements OR 5 and 6, the multi-input element And 8, the element And 3, the reverse counter 7, and the element And 2 with an inverse input, the first generator 1 of a random pulse stream connected to the first counter 9 and the second input of the element And 3, and the output of the second element And 3 is connected with the input of the second counter 10, output d of the second generator 11 of a random pulse stream is connected to the second input of the first element OR 5, the output of the first multichannel unit 4 of random time delays through the second element OR 6 is connected to the subtracting input of the reversible counter 7, the output of which is connected to the input of the multi-input element And 8, inverse input element And 2 with an inverse input is connected to the first input of the And 3 element and the output of the multi-input And 8 element, the second input of the And 2 element with an inverse input is connected to the output of the first random pulse generator 1, and the output is connected to the input of the first multi-channel block 4 random time delays and the first input of the first element OR 5, the output of which is connected to the summing input of the reverse counter 7, the output of the second random pulse generator 12 is connected to the input of the third counter 13 and the input of the second multi-channel block 12 random time delays, the output of which is connected to the second input of the second element OR 6, the input of the fourth counter 14 is connected to the output of the first multi-channel block 4 random time delays.

The device (figure 1) works as follows. The pulse from the first generator 1 of a random pulse stream passes through an open AND 2 element with an inverse input and simultaneously arrives at the first input of the first OR 5 element and to the input of the first multichannel unit 4 of random time delays, from the output of the first OR 5 element, the pulse is fed to the summing input of the reverse counter 7. The pulse received at the summing input of the reverse counter 7, increases its content by one, thereby simulating the occupation by the application of one serving channel. The same impulse, having passed the first multichannel block of 4 random time delays and appearing at its output after a random time that simulates the service time of the application, enters through the second element OR 6 to the subtracting input of the reversible counter 7 and writes off the unit from it, thereby simulating the release of one of serving channels.

In the case when the model simulates the occupation of all the service channels (all units are recorded in counter 7), an output signal is issued from the output of the multi-input element And 8, which closes the element And 2 with an inverse input at the inverse input and opens the And 3 element at the first input.

As a result, the arrival of pulses at the summing input of the reverse counter 7 and the multi-channel block 4 of random time delays is stopped, and the pulses pass through the open element And 3 to the input of the second counter 10, fixing the number of request pulses that have been denied service due to busy channels.

The moment of appearance at the output of the second pulse generator 11 simulates the failure (appearance of a malfunction) of one of the channels.

The failure of one of the channels leads to the fact that in the system for maintenance there will be one channel less. This can be imagined as a channel busy with maintenance. Therefore, to simulate a failure, it is necessary to add a unit to the contents of the reverse counter 7.

The pulse from the output of the second generator 11 is supplied to the second input of the first element OR 5 and then to the summing input of the reverse counter 7, increasing its content by one. Moreover, this impulse does not enter the input of the first multichannel unit 4 of random time delays, which eliminates the imitation of service requests. At the same time, the pulse from the output of the second generator 11 is supplied to the inputs of the third counter 13 and the second multi-channel block 12 of random time delays. The third counter 13 counts the number of channels that failed for a certain period of time simulation, and the second multichannel block 12 random time delays simulates the time of repair and restoration of the failed channel.

After a certain random time corresponding to the duration of the restoration work, an impulse is issued from the output of the second multi-channel block 12 of random time delays, which arrives at the second input of the second element OR 6 and then to the subtracting input of the reverse counter 7 and writes off the unit from it, thereby simulating the release of one after restoration of its operability and the operation of the device is performed in the standard mode.

In addition, the impulse, having passed the first multi-channel block 4 of random time delays and appearing at its output after a random time that simulates the service time of the application, is fed to the input of the fourth counter 14, which fixes the number of served applications for a certain period of modeling time.

The total number of applications received in the system is calculated by the first counter 9.

In the prototype device, when a system malfunction occurs, the pulses to the summing input of the reverse counter 7 are stopped, and the request pulses are received at the input of the second counter 10, fixing the number of request pulses that have been denied service due to busy channels.

In the inventive device in the event of a malfunction of one or more channels, the arrival of pulses to the summing input of the reversible counter 7 does not stop, but only the total number of channels ready to accept the service request decreases.

Statistical characteristics of the operation of the QS modeled by the proposed device is calculated by known methods based on the readings of counters 9, 10, 13 and 14.

Thus, the device provides enhanced functionality by providing the ability to simulate a system consisting of several service channels in the event of a malfunction of one or more channels without stopping service applications.

Claims (1)

A device for modeling queuing systems containing the first and second generators of a random pulse stream, a multi-channel block of random time delays, the first, second and third counters, two OR elements, a multi-input element And, an element And, a reversible counter, the first generator of a random pulse stream is connected to the first counter and the second input of the element And, and the output of the second element And is connected to the input of the second counter, the output of the second generator of the random pulse stream is connected to the second input of the first element OR, the output of the multi-channel block of random time delays through the second element OR is connected to the subtracting input of the reverse counter, the output of which is connected to the input of the multi-input element And, characterized in that it also has a second multi-channel block of random time delays, the fourth counter and the And element with an inverse input, the inverse input of which is connected to the first input of the element And and the output of the multi-input element And, the second input of the element And with the inverse input is connected to the output of the first generator with pulse stream, and the output is connected to the input of the first multi-channel block of random time delays and the first input of the first OR element, the output of which is connected to the summing input of the reverse counter, the output of the second random pulse stream generator is connected to the input of the third counter and the input of the second multi-channel block of random time delays the output of which is connected to the second input of the second OR element, the input of the fourth counter is connected to the output of the first multichannel block of random time assignments yerzhok.

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