SU1142842A1 - Device for simulating process for servicing requests - Google Patents

Abstract

A DEVICE FOR SIMULATING THE APPLICATION SERVICE PROCESS, containing two pulse generators with a random following interval, three AND elements, two triggers, an inhibit element and the first isolation diode, the output of the first element I is connected to the start input of the first pulse generator with a random following interval, the output of which is output of the device’s high priority wok and connected to the first input of the second element I, the second input of which is connected to the first output of the primary trigger, the second output of which under Connected to the first input of the third element AND, the second input of which is an input for the low priority device, the input for the high priority application of which is the first input of the first element AND, the second input of which is connected to the first output of the second trigger, the second output of which is connected to the input of the prohibition element, the information input of which is connected to the output of the third element I, and the output through the first separating diode to the output of the second element I and the input of starting the second pulse generator with The following interval, the output of which is the output of the low priority device, characterized in that, in order to expand the functionality of the device by taking into account the processes of failures and repairs of the servicing device, it additionally contains a failure generator and a recovery generator, each of which is made in the form of pulse generators with a random spacing interval, and DEDB with separation diodes, moreover (L output of the fault generator is connected through the second isolation diode d with the first input of the first trigger, the output of the first element, and through the third and fourth isolating diodes are connected respectively to the first input of the second trigger and to the control input of the second pulse generator 4 with a random following interval, the device start input is the 00 4 input of the fault generator connected to recovery generator output, tc the failure generator output is connected to the recovery generator input, the output of which is connected to the second input of the first trigger through the fifth isolation diode, you od generates torus failures connected to the control input of the first pulse generator with a random interval sequencer and turn the sixth and seventh dividing diodes respectively to the first input of the second flip-flop and the control input of the second pulse generator t

Description

with a random following interval, the output of which through the eighth isolating diode is connected to the second input of the first trigger, the output of the inhibit element through the nine separating diode is connected to the first input of the first trigger, the trigger input

the device through the tenth separation diode is connected to the second input of the second trigger, and the output of the first pulse generator with a random interval following through the eleventh separation diode is connected to the second input of the second trigger.

one

The invention relates to specialized computer facilities, is intended to simulate the process of servicing a flow of applications with different priorities, and can be used in devices simulating the operation of queuing systems.

A device for simulating queuing systems is known, comprising a random voltage generator, two blocks of nonlinear elements, a flow generator, a service time shaping unit, a failure flow generator, a queue accumulator, two BAN elements blocks, a switch block, a trigger block, a AND block , three counters, two 1X decoders

The drawbacks of the device are a large number of elements and the complexity of the technical implementation.

Closest to the proposed technical entity is a device for simulating the process of servicing applications with different priorities, containing two. pulse generator with a random interval, three elements And, two flip-flops, a prohibition element and a limiting diode, output of the high priority of the device connected to the first input of the first element And, the output of which is connected to the first input of the first trigger, the start input of the first pulse generator with a random the tracking interval and controlling the second input of the pulse generator with a random interval, the output of the first pulse generator with a random interval following is the first output m and devices connected to the first input of the third AND gate and a second

2

the input of the first trigger, the first output of which is connected to the second input of the first element I, and the second output connected to the control input of the prohibition element, the information input of which is connected to the output of the second element I, and the output connected to the second input of the second trigger and through the limiting diode to the output of the third element And the start input of the second pulse generator with a random interval, the output of which is the second output of the device and connected to the first input of the second trigger, the first output of which Inonii to a second input of the third AND gate and a second output connected to one of the inputs of the second AND gate, the other input of which is input to the low priority applications are L23e

The disadvantage of this device is the impossibility of modeling the process of functioning of the servicing device under the conditions of occurrence of malfunctions and restoration of its working capacity.

The purpose of the invention is to expand the functionality of the device by taking into account the process of failures and restoration of the servicing device.

The goal is achieved by the fact that a device containing two pulse generators with a random spacing interval, three AND elements, two triggers, a prohibition element and the first separating diode, and the output of the first AND element is connected to the trigger input of the first generator

40 pulses with a random interval of 5, the output of which is the output of the high priority of the device and connected to the first input of the second element I, the second input of which is connected to the first output of the first trigger, the second output of which is connected to the first input of the third element I, the second input of which is an input for a low priority device, the input for which a high priority is the first input of the first element, the second input of which is connected to the first output of the second trigger, the second output which is connected to the control input of the prohibition element whose infarmaodon input is connected to the output of the third element AND, and the output through the first separating diode with the output of the second element AND and the start input of the second pulse generator with a random interval following which the output is wok of high priority of the device, a failure generator and a recovery generator are added, each of which is designed as a pulse generator with a random following interval, and ten separators diodes, the output of the fault generator with, is connected through the second divider diode with the first input of the first trigger, the output of the first element, And through the third and fourth isolating diodes is connected respectively to the first input of the second trigger and the control input of the second pulse generator with a random interval following, the device start input is the input of the failure generator, connected to the output of the recovery generator, the output of the failure generator is connected to the input of the recovery generator, the output of which is The fifth splitter diode is connected to the second input of the first trigger, the output of the fault generator is connected to the control input of the first pulse generator with a random following interval And through the sixth and seventh split diodes respectively to the first input of the second trigger and control input of the second pulse generator owls with a random spacing interval, the output of which through the eighth isolating diode is connected to the second input of the first trigger, the output of the prohibition element through the nine separating diode is connected to the first input of the first flip-flop, the input device run through tenth separator .ny diode coupled to a second input of the second flip-flop, a first output of the pulse generator with random intervals separating sequencers through eleventh diode connected to the second input of the second flip-flop. The model of operation of the device is as follows. Two random flows for servicing go to one serving device. Applications for service with a lower priority are accepted for service in the absence of a request with a higher priority. For those of the same priority, received at the moment of the servicing device being busy, the service is denied. If the application with a higher priority is received during the service period of the application with a lower priority, then the service with a lower priority is terminated, and the service is submitted with a higher priority. After the servicing device is released, the service with a lower priority service is resumed. With the onset of the servicing device failure, none of the applicants for service are accepted until the device is restored and the service of the priority applications resumes. and the serviced applications are lost. The drawing shows a structural diagram of the proposed device. The device contains input for wok high 1 and low 2 priority, the first 3 and third 4 elements And, the second 5 and first 6 triggers, prohibition element 7, the first separation diode 8, the second element And 9, the first 10 and second 11 pulse generators with random following interval, generator 12 failures, generator 13 restorations, eleventh 14, third 15, tenth 16, sixth 17, fifth 18, seventh 19, fourth 20, eighth 21, ninth 22 and second 23 separation diodes, start input 24 . Service threads on inputs 1 and 2 are random pulse sequences, the intervals between which are distributed according to certain (different or the same) laws.

The service model of the device is the generators 10 and 11. The distribution of random pulses at the outputs of the generators 10 and 11 is the same, since they simulate the same device.

The generators 12 and 13 pulses at their outputs set respectively the moments of the onset of failure and restoration of the servicing device. These generators are similar to generators 10 and 11.

The time interval from the moment of launching the generators to the appearance of impulses at their output is random and is distributed according to the accepted laws of servicing the stock, failures and restoration of the servicing device.

The device can operate in three modes: servicing low priority requests, servicing high priority requests, servicing the highest priority requests received during the low priority request service period.

Regardless of the device operation mode, the failure of the service device leads to the loss of the serviced application, if such a device was present at the time of the failure, and the loss of all newly submitted applications.

The device works as follows.

In the initial state, in all three modes after the arrival of the signal at the start input, the triggers 5 and 6 are set to the position where there is a high potential at the outputs connected to the And 3 and 4 elements. In this case, there is no voltage at the control input of element 7, and this element is open.

Service for low priority wok.

The pulses from the input 2 through the element 7 and the diode 8 start the generator 11, and the trigger 6 through the diode 22 is switched to the position at which the element 4 is open until the end of the service of the incoming application. The applications received at that time from input 2 are not accepted for service and are lost. After the end of the service, the pulse from the generator output 11 is

It goes to the output of the device and, via diode 21, moves trigger 6 to the position at which element 4 is opened. Servicing a high priority order.

The impulse from input 1 through the open element And 3 starts the generator 10 and through the diode 15 translates the trigger 5 into a state in which a high potential is removed from the element 3 and the voltage is applied to the control input of the inhibit element 7. In this case, the calls received from the input 1 are lost, since the AND 3 element is closed, and the requests from the input 2, the I 4 pass through, are not accepted for service, as the 7 element is closed. After the termination of the service and the appearance of a pulse at the output of the generator 10 and at the output of the device through the diode 14, the circuit is reset to the initial state - elements 3 and 7 are opened.

Servicing a high priority wok received in a period of time. Service servicing a low priority wok. , For low priority from input 2 through open element 7, the generator 11 starts up and the trigger 65 trips. At the same time, the element 4 is closed, and the second potential is fed to the second input of the element 9 from the output of trigger 6.

For higher priority received from input 1 before generator 11 ends, generator 3 starts up generator 10, sets generator 11 to its initial state through diode 20 (termination of service for low-priority applications is simulated) and triggers trigger This closes element 3 and prohibition element 7. In such a state, the scheme is maintained until the end of service of the application with high priority. After the appearance of a pulse at the output of the generator 10 (termination of the service of the highest priority application), trigger 5 is tilted, opening elements 3 and 7. At the same time, the same impulse passes through

element AND 9, at the second output of which there is a resolving potential from trigger 6 for starting the generator 11. This simulates repeated maintenance of low priority applications interrupted by the receipt of a high priority application. Until the end of service, trigger 6 holds AND 4 7.1 in a closed cocToifHHH, and AND 9 in an open one. After the appearance of a pulse at the output of the generator 11, the circuit returns to the initial state. The arrival of a high priority application from input 1 until the end of generator 11 operation is again interrupted by servicing / low-priority application generator 11 is set to its initial state by a pulse from the output of the IZ element. The operation of the device is repeated in a similar manner. Simultaneously with the impulse input to the start-up of the device, it starts up with the generator 12 and begins the simulation of the process of failure and restoration of the servicing device.

at the output of the generator 12, the generator 13 starts up, sets in the initial state any of the generators 10 or 11 that are in operation (if the application is serviced). The application that is serviced is lost. At the same time, this pulse through diodes 17 and 23 sets the triggers 5 respectively.

It is in the expansion of its functional capabilities and simulation of real queuing systems, the servicing devices of which in practice have finite values of reliability indices. This can significantly affect the functioning of such systems. 2 and 6 in a state in which high potential is removed from the second inputs of the And 3 and 4 elements — none of the newly submitted applications are served as the inputs of the device are closed. The impulse at the output of the generator 13 (the device is restored) starts the generator 12, and through diodes 16 and 18, respectively, flip-flops 5 and 6 tilt. Elements And 3 and 4 open the circuit to the initial state and are ready for service to the inputs to inputs 1 and 2. high and low priorities. When the requisition is received for service, the considered operation modes of the device repeat again. Technical and economic efficiency from the introduction of the device

Claims (1)

DEVICE FOR SIMULATING THE APPLICATION SERVICE PROCESS, containing two pulse generators with a random interval, three AND elements, two triggers, an inhibit element and a first diode, the output of the first AND element is connected to the start input of the first pulse generator with a random interval, the output of which is the output applications of high priority of the device and is connected to the first input of the second element And, the second input of which is connected to the first output of the first trigger, the second output of which is connected to the first input of the third AND element, the second input of which is the input of low priority applications of the device, the input of the highest priority applications of which is the first input of the first And element, the second input of which is connected to the first output of the second trigger, the second output of which is connected to the control input of the inhibit element, information input which is connected to the output of the third element And, and the output through the first isolation diode - with the output of the second element And and the start input of the second pulse generator with a random interval Follow-up, the output of which is the output of applications of low priority of the device, characterized in that, in order to expand the functionality of the device by taking into account the failure and recovery processes of the service device, it additionally contains a failure generator and a recovery generator, each of which is made in the form of pulse generators with a random interval, and ten isolation diodes, and the output of the fault generator is connected through the second isolation diode to the first input of the first Tr the output of the first element And through the third and fourth isolation diodes, respectively, connected to the first input of the second trigger and the control input of the second pulse generator with a random interval, the input of the start of the device is the input of the fault generator connected to the output of the recovery generator, the output of the fault generator is connected to the input recovery generator, the output of which through the fifth isolation diode is connected to the second input of the first trigger, the output of the fault generator is connected to the control the input of the first pulse generator with a random interval and through the sixth and seventh isolation diodes, respectively, to the first input of the second trigger and the control input of the second pulse generator SU. and the output of the first pulse generator with a random interval through the eleventh isolation diode is connected to the second input of the second trigger.