SU1603397A1 - Device for modeling two-channel queuing system - Google Patents

Abstract

The invention relates to specialized computer aids and is intended to simulate the process of distributing and servicing applications between the channels of a queuing system. The purpose of the invention is to expand the functionality of the device by simulating multi-phase queuing systems with repeated services. The goal of the invention is achieved by introducing a model of device servicing devices, triggers, pulse shapers, OR elements, AND elements, and reversible counters. The essence of the invention consists in the possibility of simulating a service ticket in a returnable two-phase QS, in which the application passes the service sequentially in the first, second and again in the first service phases, waiting for the second phase to be serviced and the first phase to be repaired. 1 il.

Description

The invention relates to specialized computer aids and is intended to simulate the process of distribution and servicing applications between the channels of the queuing system I.

The purpose of the invention is to expand the functional capabilities of the device by simulating random service intervals, respectively, of the first phase, second and again first.

The drawing shows a functional diagram of a stochastic device for simulating a two-channel queuing system.

The device contains a control trigger 1, the first 2, the second 3, the third 4, quarter 5, five 6 and sixth 7 elements And, the first 8 and second 9 service channels, the first 10 and second 11 blocks of random service pulse generators.

Each of the service channels 8 and 9 contains the first - third triggers 12-14, the first 15 and the second 16 pulse generators, the sixth 17, the fifth 18, the first 19, the fourth 20, the third 21 OR elements, the sixth 22, seventh 23 , the first 24, the second 25, the fifth 26 elements And, the second element OR 27, the first 28 and the second 29 reversible counters, the third 30 and the fourth 31 elements I.

Models 8 and 9 of the service devices are mass system channels.

oh oh oh: with

Wise service. Each of the service channels can be in one of six states: occupied by the application in the first phase of the service, occupied by the application in the second phase of the service, occupied by the application in the first and second phases of the service, occupied by the application again in the first phase, servicing the application in the second service phase and again in the first, free. The device has the following sequence of maintenance phases: maintenance in the first phase, in the second phase, re-maintenance in the first phase.

Requirements (requirements) are accepted for servicing only in the period of time when the channel is free from servicing the first phase, i.e. at the same time, two applications can be serviced in the channel. In addition, two channels are provided in each channel to wait for the service, respectively, for those applications that have been serviced by the first phase and sent to the second phase, and which have been serviced by the second phase and are sent to re-service the first phase. The applications of 1T to the corresponding queues, when the service phases, ku-v and applications are sent, are serviced by the previous applications. Queuing requests are sent to service the respective phases as soon as these phases are released.

The presence of high unit potentials at the blocking outputs of the models of the servicing devices testifies to the busy state of the first servicing phase of the corresponding channels. In each model 8 or 9 of the servicing device, trigger 12 simulates the initial service in the first phase, trigger 14 - service in the second phase, and trigger 13 - repeated service in the first phase. The unit state of these triggers signals applications for the maintenance of the corresponding phase.

Triggers 12-14 go to the zero state at the moment of action of the front of the pulse arriving at their zero inputs. The same triggers go to one state, and counters 28 and 29 change their state at the moment of the action of the pulse slices, enter

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55

corresponding to their inverse corresponding inputs.

The shapers 15 and 16 pulses form pulses similar to those arriving at the information input of the device, during a drop in the unit potential to zero, acting on their inputs.

The device works as follows

Applications are received at the informational input of the device and further on the elements And 2-5. Depending on the state of the control trigger 1, into which it is installed with a predetermined probability P, the signals arriving at the control inputs of the device, the input goes either to the first or second channel through the corresponding elements 2, 3 in the presence of zero signals on the blocking outputs of the first 8 and second 9 models of servicing devices in case both channels are free from servicing the first phase. In this case, elements 4, 5 of the application do not pass through, since zero potential is present on their vply entrances locking these elements. Next, through the corresponding elements And 6, 7, the application enters directly the informational inputs of the corresponding model 8, 9 of the service device.

In case one of the channels is serviced by the first phase, then the opening one of the corresponding elements AND 5 or 4 paq decides the passage of the application to the other free channel, and the absence of a zero potential at the inverse input of the elements AND 6, 7 prohibits the passage of applications into a busy channel.

In case both channels are occupied by blotting out the first phase or the first queue is completely filled with applications waiting for the second phase to be served, the application fails due to the absence of zero potentials at the inverse inputs of the And 6 and Y elements.

Consider the operation of service device models, having previously assumed that the 12-H triggers and the counters 28 and 29 are in the zero state. Applications come to the zero inverse inputs of the flip-flops 12, respectively, of the first 8 or second 9 models of the serving ports.

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20

By this, the indicated triggers are transferred to the zero state. In this case, the channels switch to the service mode of the charge in the first phase. At random times, the unit inputs of the flip-flops 12 receive pulses from the independent, respectively, first and second outputs of the generator unit 10. The flip-flops 12 are transferred to unit states. At the same time, short duration pulses are formed at the outputs of the pulse shaper 15, which pass through the elements OR 17 to the inverse zero inputs of the trigger 14, transferring them to zero states, thus simulating a transfer to the second phase. The next application can go to service the first phase, that is, to arrive at zero inverse inputs of flip-flops 12. Similarly, at random times, individual inputs of flip-flops 14 receive pulses from the independent first and second outputs of the generator 11, respectively. The triggers 14 are transferred to single states. At the output of the formers of 16 pulses, short duration pulses are formed which, through the OR 18 elements and opened by single potentials from the inverse outputs of the trigger 12, if they are not occupied by servicing the first phase of the next order, the elements And 22 arrive at the inverse zero inputs of the trigger 13 than transfer them to the zero state, i.e., the receipt of the re-servicing rate of the first phase is simulated. In this case, the service of the applications in the first service phase by means of single potentials from the direct outputs of the flip-flops 12 or 13 at the outputs of the OR 20 also formed single blocking potentials, which, applying to the inverse inputs of the elements AND 6.7 of the device (respectively from the first 8 or the second 9 models of the servicing device) lock these AND elements and do not allow the next applications to enter

Geors 12 or 13 open the elements And 30, 31 and the pulses of the charge through these elements pass to the inverse summing inputs of the reversible counters 29, which bring them to the first state. In this case, the unit I. 26 opens with unit potentials from the outputs of the elements OR 21. The following pulses. After servicing the second phase, the states of the counters 29 increase. When the corresponding applications switch to re-servicing the first phase, i. when triggers 12 or 13 are zeroed, zeroing impulses through elements AND 26, then through elements OR OR 18 and open elements AND 22 (since triggers 12 will have time to zero and unit potentials from their inverse outputs open elements And 22) pass into inverse the zero inputs of the flip-flops 13, than transfer them to the zero state, i.e. An imitation of the application from the second stage, 25 where it was awaiting the re-servicing of the first phase, to re-servicing the first phase. .

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The device also provides for such a situation, when, after the initial servicing of the application in the first phase, the second phase is occupied by the specific activity of the previous application. In this case, applications after the service of the first phase come first

35 namely, to summing inverse inputs of reversible counters 28 through open elements AND 23. Elements And 23 are opened by single potentials from the direct outputs of the flip-flops 14. At the same time, the first phase can be serviced by the first phase, i.e. if one application is serviced in the first phase, then the queue may be M-1 per wok. If the application is serviced in the first phase, in the presence of M-1, the quotation in the first stage goes into the same queue, i.e. the queue becomes the M order, then single signals are formed at the outputs of the elements

40

the service of the first phase in accordance with AND 24 and in this case the application does not pass

Geors 12 or 13 open the elements And 30, 31 and the pulses of the charge through these elements pass to the inverse summing inputs of the reversible counters 29, which bring them to the first state. In this case, the unit I. 26 opens with unit potentials from the outputs of the elements OR 21. The following pulses. After servicing the second phase, the states of the counters 29 increase. When the corresponding applications switch to re-servicing the first phase, i.e. when triggers 12 or 13 are zeroed, zeroing impulses through elements AND 26, then through elements OR OR 18 and open elements AND 22 (since triggers 12 will have time to zero and unit potentials from their inverse outputs open elements And 22) pass into inverse the zero inputs of the flip-flops 13, than transfer them to the zero state, i.e. An imitation of the application from the second stage, where it was awaiting re-servicing of the first phase, to re-servicing the first phase, is simulated. .

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thirty

The device also provides for such a situation, when, after the initial servicing of the application in the first phase, the second phase is occupied by the specific activity of the previous application. In this case, applications after the service of the first phase come first

35 namely, to summing inverse inputs of reversible counters 28 through open elements AND 23. Elements And 23 are opened by single potentials from the direct outputs of the flip-flops 14. At the same time, the first phase can be serviced by the first phase, i.e. if one application is serviced in the first phase, then the queue may be M-1 per wok. If the application is serviced in the first phase, in the presence of M-1, the quotation in the first stage goes into the same queue, i.e. the queue becomes the M order, then single signals are formed at the outputs of the elements

40

 And 24, and in this case, the application does not pass

service channel. If at the moment of transfer of the application for re-servicing of the first phase, the triggers 12 turn out to be occupied by servicing the next applications, then the zero potentials from their inverse outputs block And 22 elements, which do not allow the inputs to the inputs of the triggers 13 to be blocked. corresponding model of the service device. With the release of the second service phase at the time of arrival from the outputs of block 55 of the zeroing impulses, these pulses, with their hind fronts through elements 25, reduce the states of the counters 28 and the triggers 14 are translated into one state, thereby simulating

arrival of wakes from the queue for the service of the second phase.

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the invention

A device for simulating a two-channel queuing system comprising a control trigger, six AND elements, a first block of random service pulse generators and two service channels, each of which contains two reversible counters, two pulse shapers, seven AND elements, six OR elements, in each service channel, the bit outputs of the first reversible counter are connected respectively to the inputs of the first AND element and the inputs of the first OR element, the output of which is connected to the first input The second element And, the outputs of the third and fourth elements And are connected respectively to the first and second inputs of the second element OR, the distant outputs of the second reversible counter are connected respectively to the inputs of the third element OR, the output of which is connected to the first input of the fifth element And, direct output the first trigger is connected to the input of the first pulse generator; the inputs of the control trigger are inputs of setting the operating mode of the device; the direct output of the control trigger is connected to the first input of the first element nA and devices, and the inverse output of the control trigger is connected to the first input of the second element AND device, the second inputs of the first and second elements AND devices and the first inputs of the third and fourth elements AND are combined and are the information input of the device, the output of the first element AND devices are connected with the first input of the fifth element And the device and the output of the fourth element And the device, the output of the second element And the device is connected to the first input of the sixth element And the device and the output of the third element And the device The first and second outputs of the first block of random service pulse generators are connected to the single inputs of the first triggers of the first and second service channels, respectively, characterized in that, in order to extend the functionality by simulating multi-phase queuing systems it further comprises a second block of random service pulse generators, and each service channel further comprises a third trigger, fifth and sixth elements OR, and in each service canap the direct output of the first trigger is connected to the first input of the fourth element OR and the first input of the fourth element AND, and the inverse output of the first trigger is connected to the first input of the sixth element AND, the output of which is connected to the inverse zero input of the second trigger, the direct output of which is connected to the second input of the fourth element OR and the first input of the third element AND, the second inputs of the third and fourth elements AND are connected to the output of the second pulse generator and the first to One of the fifth OR element, the output of which is connected to the second input of the sixth AND element, and the second input of the fifth OR element and the subtractive input of the second reversible counter are connected to the output of the fifth AND element, the output of the second OR element, and the output of the first pulse shaper is connected to the first input of the sixth element OR and the first input of the seventh element AND, the output of which is connected to the summing input of the first reversible counter, the subtracting input of which is connected to the output The second element And the second input of the sixth OR element, the output of which is connected to the inverse zero input of the third trigger, the direct output of which is connected to the input of the second driver of the pulses and the second input of the seventh element And, and the output of the first element AND, connected to the third input of the fourth element OR, the outputs of the fourth OR elements of the first and second service channels are connected to the second inputs of the third and fourth elements of the device AND, respectively, and the inverse inputs of the fifth and sixth elements, respectively In the device, the first output of the first block of random service pulse generators is connected to the single input of the second trigger and the BtopbiM input of the fifth element of the first service channel, the second output of the first block of random service pulse generators is connected to the single input of the second trigger and the second input of the fifth element And the second service channel, the first output of the second block of random pulse service generators is connected to the single input of the third trigger and the second input of the second element And the first second channel of service, and the second output of the second generator case1603397

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The service pulses are connected to the single input of the third trigger and the second input of the second element AND of the second service channel, and the outputs of the fifth and sixth elements of the device AND are connected to the inverse zero inputs of the first triggers of the first and second service channels, respectively.

Claims (1)

Claim A device for simulating a two-channel queuing system containing a control trigger, six AND elements, a first block of random service pulse generators and two service channels, each of which contains two reverse counters, two pulse shapers, seven AND elements, six OR elements, in each channel service bit outputs of the first reversible counter are connected respectively to the inputs of the first AND element and the inputs of the first OR element, 20 the output of which is connected to the first input of the second AND element, the outputs of the third and fourth AND elements are connected respectively to the first and second inputs of the second OR element, the 25 outputs of the second reverse counter are connected respectively to the inputs of the third OR element, the output of which is connected to the first input of the fifth AND element, the direct output is -JO of the trigger is connected to the input of the first pulse shaper, the inputs of the control trigger are inputs of the device operating mode setting, the direct output of the control trigger is connected to the first input of the first element a And the device, and the inverse output of the control trigger is connected to the first input of the second element And the device, the second inputs of the first and second elements And the device and the first inputs of the third and fourth elements And are combined and are the information input of the device, the output of the first element And the device is connected with the first in-45 house of the fifth element AND device and the output of the fourth element AND device, the output of the second element AND device is connected to the first input of the sixth element AND device and the output of the third element AND device jq two, the first and second outputs of the first block of random service pulse generators are connected respectively to the single inputs of the first triggers of the first and second service channels, characterized in that, in order to expand the functionality by modeling multi-phase queuing systems with repeated service in one of the phases, it additionally contains a second block of random service pulse generators, and each service channel additionally contains a third trigger, fifth and sixth electric OR, and in each service channel, the direct output of the first trigger is connected to the first input of the fourth OR element and the first input of the fourth AND element, and the inverse output of the first trigger is connected to the first input of the sixth AND element, the output of which is connected to the inverse zero input of the second trigger, direct the output of which is connected to the second input of the fourth OR element and the first input of the third AND element, the second inputs of the third and fourth elements AND are connected to the output of the second pulse shaper and the first input the first OR element, the output of which is connected to the second input of the sixth AND element, and the second input of the fifth OR element and the subtracting input of the second reverse counter are connected to the output of the fifth AND element, the output of the second element OR is connected to the summing input of the second reversible counter, and the output of the first pulse shaper is connected to the first input of the sixth element OR and the first input of the seventh element AND, the output of which is connected to the summing input of the first reversing counter, the subtracting input of which is connected to the output of the second element And and the second input of the sixth OR element, the output of which is connected to the inverse zero input of the third trigger, the direct output of which is connected to the input of the second pulse shaper and the second input of the seventh ele ent, and the output of the first AND element is connected to the third input of the fourth OR element, the outputs of the fourth OR elements of the first and second service channels are connected to the second inputs of the third and fourth elements AND devices, respectively, and to the inverse inputs of the fifth and sixth elements AND devices, respectively, the first output the first block of random service pulse generators is connected to a single input of the second trigger and the second input of the fifth element AND of the first service channel, the second output of the first block is the generator Case ⁹ 1603397 pulses service connected to a single input of the second flip-flop and a second input of the fifth element and the second service channel, a first output of the second block of random maintenance pulse generators connected to a single input of the third flip-flop and a second input of the second AND gate of the first service channel, and the second output the second random service pulse generator is connected to a single input of the third trigger and the second input of the second element AND of the second service channel, and the outputs of the fifth and sixth And lementov ustroyst · va connected to zero inverted inputs of the first flip-flops of the first and second channels serviced Bani.