SU1272340A1 - Device for simulating the queueing systems with relative priorities - Google Patents

Abstract

The invention relates to computing and to be used in the instrumental study of mass-service systems. neither The purpose of the invention is to expand the functionality by determining the length of the common queue. The device contains a random flow generator of low priority quotes, a random flow generator of high priority quotes, a high priority quotes counter, a high priority quotes lost counter, a low priority quotes counter, a low priority quotes lost counter, elements of the ban, elements And, OR elements, reversible counter of occupied channels, reversible counter for high priority in the common queue, reversible counter for low priority in the common queue, reversible counter for ok queue, multi-input AND eleS cops, multi-input OR elements (block A random time delay. 1 yl.

Description

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Claims (2)

ij I12 The invention relates to computing and can be used for instrumental investigation of queuing systems. The purpose of the invention is to expand the functionality of the device for. account for determining the length of the common queue. The drawing shows a device diagram. The device contains a random flow generator 1 with a low priority priority (first stream), a random priority generator 2 with a high priority flow (second stream), a high priority flow meter 3, a counter 4 lost high priority requests, a low 5 count priority, counter 6 lost low priority orders, fourth 7, second 8, third 9, five and the first prohibition elements, quarter 12, first three, second 14, five 15, sixth 16, third 17 And elements , elements OR 18-22, reversible counters 23 channels occupied, 24 for high . {priority in the common queue, 25 low priority quotes in the common queue, 26 quotes in the queue, first 2 and second 28 AND multi-input elements, first 29 and 30 second multi-input OR elements, block 31 is randomly delayed. The device works as follows. I When there is no queue and in the system one channel is free, signals from the output of multi-input elements AND 27 and 28, multi-input elements OR 29 and 30 are absent, and pulses from the generators 1 and 2 pulses through the open prohibition elements 7 and 10, the element OR 19, the open prohibition element 9 arrives at the summing input of the counter 23 of the occupied channels and at the same time through the element OR 18 enters the block 31 of random time delays, simulating the service process. The arrival of a signal at the totalizing input of the counter 23 busy channels increases its code by one, which means that one channel is busy. An impulse of a random time delay unit, which develops at the output after a time equal to the random service time, goes to the subtracting input of the counter of occupied channels 23 and, subtracting a unit from its content, thereby simulating the end of the maintenance work on the application and the release of the channel. At the moment of time when all the channels are occupied, the output of the multi-input element And 27, associated with the bits of the counter 23, a signal arrives at the control input of the prohibition element 9 and at the inputs of the elements 14 and 17. The element 9 of the prohibition closes, elements AND 14 and 17 are opened. This stops the flow of signals from the generators to the summing input of the 23 busy channels counter and to the block 31 of random time delays. Signals from generator 1 through element AND 17, element OR 21 to the summing input of counter 26 of the total number of queued in the queue and simultaneously to the summing input of the counter 25 of the number of low priority queuing in the queue, and from generator 2 through the element I 14, the element OR 21 to the summing input of the counter 26 is the quota in the queue and to the summing input of the counter 24 high priority quotations standing in the queue. As soon as at least one unit is recorded on the counter 24, indicating that there is a queue for service from the second flow of the order, the output of the multi-input element OR 29 is given a clock signal. The signal from its output goes to the control input of the prohibition element 11 and opens the element AND 13. As a result, the impulse from the block 31 of random time delays goes through the open element AND 13, the element OR 22 to the subtracting input of the counter 26 and directly from AND 13 to the flashing input of the counter 24 and, by writing off one of them, thereby imitating the completion of the service of one application. At the same time, the same signal through the element OR 18 is fed to the input of the block 31 of random time delays 31, thereby termination of the service of one application. At the same time, the same signal through the element OR 18 is fed to the input of a block of random time delays 31, imitating by itself the acceptance for service of one of the high-priority applications standing in line. 3 If there are low priority orders in the queue (counter 25), the signal from the output of the multi-input circuit OR 3 is fed to the element AND 16 and through the element OR 20 to the control input of the prohibition element 8. However, the pulse from the output of the block 31 random time delays does not go to the subtract The inputs of counters 25 and 26, since the prohibition element 11 is at this time closed by the control input by a signal from the multi-input element OR 29. Thus, priority is given to servicing the applications received in the queue from the generator 2. At the moment — time when all the queues are occupied, i.e. over all the bits of the reversible counter, queue 26 will be one, at the output of the multi-input element And 28 there will be a signal that goes to the control inputs of barred elements 7 and 10 and elements 12 and 15, and elements 12 and 15 will open and pulses from generators 1 and 2 pass to counters 6 and 4, which calculate the number of applications that were denied service from the first and second streams, respectively. If there are no high priority applications in the queue, i.e. zeros are written on all bits of counter 24, then the signal from the output of the multi-input element OR 29 is absent. As a result, the element AND 1 is closed, the prohibition element 11 is opened and the pulses from the output of block 31 through the open element AND T6, the element OR 2 will be fed to the read input of the counter 26 of the wok that is in the turn, and simultaneously to the reading input of the counter 25. Decommissioning 1 of these counters simulates the process of sampling from the queue for the generator 1. At the same time, the pulse from the output of block 31 through the open element AND 16, the element OR 18 enters the input of block 31, thereby simulating the acceptance for service from the first thread. Therefore, in the absence of high priority requests, low priority applications received from generator 1 will be serviced. The statistical characteristics of the operation of the queuing system are calculated by 40 known methods based on meter readings. Apparatus of the Invention A device for simulating queuing systems with relative priorities, comprising a random flow generator of high priority requests, a random flow generator of low priority requests, a high priority request counter, a low priority request counter, a loss counter of high priority requests, a counter lost low priority queuing, reversible counter of occupied channels, the bit outputs of which are connected respectively to the inputs of the first multi-input element AND, reversible counter of the high priority queuing queue, the bit outputs of which are connected respectively to the inputs of the first OR multi-input element, reversible counter of the low priority queuing loop, the bit outputs of which are connected respectively to the inputs of the second multiple input OR cell, six elements AND , three OR elements, five prohibition elements and a block of random time delays, the output of which is connected to the first input of the first element AND and the information inputs of the first and second elements of When the second prohibition element is output, the output of the second prohibition element is connected to the subtracting input of the reversible counter of occupied channels, the summing input of which and the first input of the first OR element are connected to the output of the third prohibition element, whose information input is connected to the output of the second OR element, and the control input of the third prohibition element is connected with the output of the first multi-input element And and the first inputs of the second and third elements And, the output of the random flow generator of the high-priority application is connected to the counting input of the counter C wok high priority information input prohibition fourth element and the first input of the fourth AND gate, whose output is okay to the counting input of the counter wiped nnyh applications are high prioritea, vkod homo random generator applications are the low priority Con