RU114801U1 - DEVICE FOR MODELING MASS SERVICE SYSTEMS - Google Patents

Abstract

A device for simulating queuing systems containing a trigger, a group of N elements AND, where N is equal to the number of channels, a group of N generators of random pulses and N is an input OR element, the outputs of the AND elements of the group are connected, respectively, to the trigger inputs of the generators of random pulses of the group, outputs which are the outputs of serviced requests of the device, characterized in that a group of N AND elements with an inverse input, a group of N OR elements, a group of N-1 triggers and an AND element, the first input of which is connected to the output of the N input element OR, from the first to the Nth inputs of which are connected to the outputs from the first to the Nth group by triggers, respectively, the input of the device of the i-th group (i = 1, 2, 3, ... N) is connected to the first input of the OR element of the i-th group, the output of the OR element of the i-th group is connected to the combined first inputs of the AND element and the AND element with the inverse input of the i-th group, the output of the trigger of the i-th group is connected to the combined second input of the element nta AND and the inverse input of the AND element with the inverse input of the i-th group, the generator input of the i-th group is connected to the first trigger input of the i-th group, the second trigger input of the i-th group is connected to the output of the generator of the i-th group, the second input OR the i-th group (i = 2, 3, ... N) is connected to the output of the AND element with the inverse input of the (i-1) -th group, the output of the AND element with the inverse input of the N-th group is connected to the second input of the AND element, the output of which connected to the second OR element of the 1st group.

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 a queuing system [SU No. 1325561 A1, class G06F 15/20, 1987.07.23], comprising an application flow generator, an incoming application counter, a denied service application counter, a random time delay unit, a reverse busy channel counter , a reverse counter of the queue length, four AND elements, three prohibition elements, two OR elements.

A disadvantage of the known device is the limited use in electronic modeling for the study of real queuing systems for servicing an inhomogeneous incoming task stream.

A device for simulating queuing systems [SU No. 1275461 A1, class G06N 7/08, 10/25/1984], containing a group of elements And, the first inputs of which are the information inputs of the device, and the outputs of the elements And are connected respectively to the inputs of the start of random pulse generators of the group the outputs of which are the outputs of the served requests of the device, the trigger, the first and second elements of OR, the outputs of the elements AND groups are connected to the inputs of the first OR element, the output of which is connected to the first input of the trigger, the output of which is under it is connected to the second inputs of AND elements of the group, the outputs of the random pulse generators of the group are connected to the inputs of the second OR element, the output of which is connected to the second input of the trigger.

The disadvantage of this device is that when the servicing device (one generator) is busy, the incoming applications of any flow refuse to service, and they are lost, although at that time all the generators, except one, are free.

The technical result is the ability to service requests received at the input of the device at the time of servicing the servicing device, if at least one of the generators (channels) is free.

The technical result is achieved by the fact that in a device for modeling queuing systems containing a trigger, a group of N And elements, where N is equal to the number of channels, a group of N random pulse generators and an N-input OR element, the outputs of the AND elements are connected respectively to the inputs start of random pulse generators of the group, the outputs of which are the outputs of served requests of the device, an additional group of N elements AND with an inverse input, a group of N elements OR, a group of N-1 triggers and electronic AND gate, the first input of which is connected to the output of the N-input OR element, from the first to the Nth inputs of which are connected to the outputs from the first to the Nth group by triggers, the input of the device of the i-th group (i = l, 2, 3 , ... N) connected to the first input of the OR element of the i-th group, the output of the OR element of the i-group is connected to the combined first inputs of the element And and the element And with the inverse input of the i-group, the output of the trigger of the i-group is connected to the combined second the input of the element And and the inverse input of the element And with the inverse input of the i-th group, the input of the generator of the i-th group with dinen with the first input of the i-th group trigger, the second input of the i-group trigger is connected to the output of the i-group generator, the second OR of the i-group (i = 2, 3, ... N) is connected to the output of the AND element with inverse the input of the (i-1) th group, the output of the AND element with the inverse input of the Nth group is connected to the second input of the And element, the output of which is connected to the second OR element of the 1st group.

The introduction of these additional elements and the sequence of their connection allows us to provide the possibility of servicing requests received at the input of the device at the time of servicing the servicing device, if at least one of the generators (channels) is free.

Figure 1 - presents the functional device.

A device for modeling queuing systems (Fig. 1) contains a group of N elements And 1 ₁ ... And 1 _N , where N is equal to the number of channels, a group of N triggers 2 ₁ ... 2 _N , a group of N random pulse generators 3 ₁ ... 3 _N , a group of N-1 elements AND 4 ₁ ... 4 _N-1 with an inverse input and a group of N-1 elements OR 5 ₁ ... 5 _N-1 .

A device for modeling queuing systems (Fig. 1) contains group 1 of N elements And, where N is equal to the number of channels, group 3 of N random pulse generators, N-input element OR 6, group 4 of N elements AND with inverse input, group 5 of N elements OR, group 2 of N triggers and element And 7, the outputs of the elements And 1 of the i-th group are connected respectively to the inputs of the start of the generators 3 random pulses of the group of the i-group, the outputs of which are the outputs of the served requests of the device, the first input element And 7 is connected to the output N-I one element OR 6, from the first to the Nth inputs of which are connected to the outputs respectively from the first to the Nth group of 2 triggers, the input of the device of the i-th group (i = 1, 2, 3, ... N) is connected to the first input of the element OR 5 of the i-th group, the output of the element OR 5 of the i-th group is connected to the combined first inputs of the element And 1 and the element And 4 with the inverse input of the i-group, the output of the trigger 2 of the i-group is connected to the combined second input of the element And 1 and the inverse input of the element And 4 with the inverse input of the i-th group, the input of the generator 3 of the i-th group is connected to the first input of the trigger 2 of the i-th group Py, the second input of the trigger of the 2nd i-th group is connected to the output of the generator 3 of the i-th group, the second input of OR 5 of the i-th group (i = 2, 3, ... N) is connected to the output of the And 4 element with an inverse input (i- 1) group, the output of the AND 4 element with the inverse input of the Nth group is connected to the second input of the And 7 element, the output of which is connected to the second OR element of the 51st group.

Verbal model of the device.

One service device receives a group of service request flows. All service requests have the same priority. An incoming application of any flow is accepted for service if at least one of the generators is free. Applications of any flow received at the time of busy servicing all the generators are denied service, and they are lost. The time interval for servicing applications is random and distributed according to the law, depending on the number of application flows.

The device (figure 1) works as follows. In the initial state, all N flip-flops 2 are set to a position in which at their outputs connected to the second inputs of the corresponding elements AND 1 ₁ ... 1 _N there is a high potential. All elements And 1 ₁ ... 1 _N for their first inputs are open.

The device works on each channel in the same way when a pulse (one service request) arrives from any of its inputs.

For example, the application comes from the first input of the device. The pulse from the first input of the device passes through the OR element 5 _{1 of the} first group, the open element And 1 _{1 of the} first group and starts the generator 3 ₁ random pulses of the first group (first channel), at the same time this pulse goes to the first input of the trigger 2 _{1 of the} first group, at the output which is set low potential, which closes on the second input element And 1 _{1 of the} first group. In this case, after the end of the service, the pulse is issued from the output of the random pulse generator 3 _{1 of the} first group, which is fed to the first output of the device and to the second input of the trigger 2 _{1 of the} first group. The trigger 2 ₁ overturns and the second element And 1 _{1 of the} first group receives a high potential, which allows the reception of the next service request on the first channel.

In the prototype device [SU No. 1275461 A1, class G06N 7/08, 10/25/1984], only one application can be served at a time. In the inventive device can simultaneously be served N applications received from any of its input.

Suppose that during the service of the application in the first channel to the i-th (i = 2, 3, ..., N) device through the OR element 5; i-group received a request for service. If the i-th channel is free, then at the second input of the element And 1; i-th group will have high potential and the application is accepted for service in the same way as when the application was received in the first channel.

If the i-th channel is busy with maintenance, then at the second input of the element And 1 _{i of the} i-th group there will be a low potential and the application to this channel will not be accepted for service. In addition, the application from the i-th input of the device simultaneously enters the first input of the And 4 _i element with the inverse input of the i-th group (i = 2, 3, ..., N-1), the second inverse input of which receives low potential from the output trigger 2 _i i -th group. In this case, the element And 4 _i ; with the inverse input of the i-th group it turns out to be open and the application through the OR element of the 5 _{i + 1} (i + 1) -th group goes to the input of the (i + 1) -th channel. If the (i + 1) -th channel is free, then the application is accepted for service by the (i + 1) -th channel.

If the (i + 1) th channel is also occupied by the service, then the application arrives through the AND 4 _{i + 1} element with the inverse input of the (i + 1) th group and the OR element of the 5 _{i + 2} (i + 2) th groups on the first input of the element And 4 _{i + 2} with the inverse input of the (i + 2) -th group and then to the input of the (i + 2) -th channel.

If the (i + 2) -th channel turns out to be occupied by the service, then the application likewise arrives at the input of the (i + 3) -th channel and so on up to the N-th channel.

If the N-th channel is busy, then the application through the open AND 4 _N element with the inverse input of the N-th group goes to the second input of the And 7 element, the first input of which receives a high potential from the output of the N-input OR element 6. From the output N-input element OR 6 high potential is issued only if at least one of the N triggers 2 is in a position in which a high potential is output from its output, i.e. at least one of the generators is not currently servicing the application (at least one of the channels is free). The pulse from the output of the AND 7 element is supplied to the first input of the OR element 5 ₁ of the 1st group and then the process of searching for a free channel will continue.

If all the channels at a given moment in time are busy servicing the applications received, then the output of the OR 6 element gives a low potential and an impulse through the And 7 element to the first input, the OR 5 ₁ element of the 1st group does not arrive and the newly received application is lost.

Thus, the device provides the possibility of servicing applications received at the input of the device at the time of servicing the servicing device, if at least one of the generators (channels) is free.

Claims (1)

A device for modeling queuing systems containing a trigger, a group of N AND elements, where N is equal to the number of channels, a group of N random pulse generators and N is an input OR element, the outputs of the AND elements are connected respectively to the start inputs of the random pulse generators of the group, the outputs which are the outputs of the served applications of the device, characterized in that it additionally includes a group of N elements AND with an inverse input, a group of N elements OR, a group of N-1 triggers and an element And, the first in One of which is connected to the output of the N - input element OR, from the first to the Nth inputs of which are connected to the outputs from the first to the Nth group by triggers, the input of the device of the i-th group (i = 1, 2, 3, ... N) connected to the first input of the OR element of the i-th group, the output of the OR element of the i-th group is connected to the combined first inputs of the And element and the And element with the inverse input of the i-group, the output of the trigger of the i-group is connected to the combined second input of the And element and the inverse input of the element And with the inverse input of the i-th group, the input of the generator of the i-th group is connected to the first trigger input of the i-th group, the second input of the trigger of the i-th group is connected to the output of the i-group generator, the second input of the OR of the i-group (i = 2, 3, ... N) is connected to the output of the AND element with an inverse input (i -1) -th group, the output of the AND element with the inverse input of the Nth group is connected to the second input of the And element, the output of which is connected to the second OR element of the 1st group.