RU173927U1 - DEVICE FOR MODELING A COMMUNICATION SYSTEM - Google Patents

Abstract

The objective of the utility model is to simulate the transmission of information on a circular network from the main station to N subscribers in an interference environment with a majority processing mode of message transmission repeats. The pulse generator 4 generates pulses that are fed to the input 9 of the And element of each branch, and fills the third pulse counter 5, the second pulse counter 10, which sends an overflow pulse to the S-input of the RS-trigger 2 and then to the input of the fourth pulse counter 3. The generator a random flow of error pulses 7 generates pulses that, having passed the 8th element, DO NOT arrive at the 9th AND element of each branch. The impulse, which passed the 9th element And, enters the counting input of the fifth counter 11 and accumulate in it. When the number of pulses in the fifth counter 11 is equal to the threshold, it is reset to zero, and the overflow pulse from it goes to the first pulse counter 1 of each branch, the number of which is displayed on display unit 6.

Description

The utility model relates to computer technology, namely, communication technology and can be used to simulate the transmission of information over a circular network from the main station to N subscribers in an interference environment with a majority processing mode of message transmission repeats.

A device for modeling a communication system containing a random pulse flow generator, two triggers, four pulse counters, a pulse generator, an element NOT, the output of which is connected to the control input of the element And, the output of which is connected to the first input of the first trigger, the output of which is connected to the input of the first a pulse counter and an indication unit, wherein the output of the pulse generator is connected to the inputs of the second and third pulse counters, the first input of the second trigger and the information input of the And element, the output to The second pulse counter is connected to the second input of the second trigger, the output of which is connected to the input of the fourth pulse counter and the second input of the first trigger, the output of the random pulse stream generator is connected to the input of the element NOT, the outputs of the first, third, and fourth pulse counters are connected to the corresponding inputs of the display unit ( SU No. 1059577, class G06F 15/20, publ. 07.12.1983).

The disadvantage of the analogue is the lack of a majority mode of processing message retries.

The closest in technical essence solution is a device for modeling a communication system containing a message pulse generator, five pulse counters, an RS trigger, an AND element, a random error pulse stream generator, a NOT element and an indication unit, the output of the first pulse counter connected to the first input of the display unit, the output of the message pulse generator is connected to the inputs of the second and third pulse counters, the first input of the AND element and the R-input of the RS-trigger, the output of which is connected to the input of the fourth count a pulse counter whose output is connected to the second input of the display unit, the third input of which is connected to the output of the third pulse counter, the overflow output of the second pulse counter is connected to the S-input of the RS flip-flop, the output of the random error pulse generator through the element is NOT connected to the second input of the element And, the counting input of the fifth pulse counter is connected to the output of the And element, the RS-trigger output is connected to the zeroing input of the fifth pulse counter, the output of which is connected to the input of the first pulse counter (RU No. 2045775, MP G06F 17/00, publ. 10/10/1995).

The disadvantage of the prototype is the inability to simulate bringing information from the main station to N subscribers.

The objective of the utility model is to provide the ability to bring information on a circular network from the main station to N subscribers in an interference environment with a majority processing mode of message transmission repeats.

The essence of the utility model is that in a device for modeling a communication system containing a message pulse generator, five pulse counters, an RS trigger, an AND element, a random error pulse stream generator, an NOT element and an indication unit, the output of the first pulse counter being connected to the first input of the display unit, the output of the message pulse generator is connected to the inputs of the second and third pulse counters, the first input of the And element and the R-input of the RS-trigger, the output of which is connected to the input of the fourth impu x, whose output is connected to the second input of the display unit, the third input of which is connected to the output of the third pulse counter, the overflow output of the second pulse counter is connected to the S-input of the RS flip-flop, the output of the random error pulse generator through the element is NOT connected to the second input of the AND element , the counting input of the fifth pulse counter is connected to the output of the And element, the output of the RS-trigger is connected to the zeroing input of the fifth pulse counter, the output of which is connected to the input of the first pulse counter, N-1 first counts are entered pulse counters, N-1 fifth pulse counters, N-1 AND elements, N-1 HE elements, and the first pulse counter is connected in series with the fifth pulse counter, AND element and NOT element, forming one of N parallel branches, each of which is connected through the input of the element NOT with the generator of a random stream of error pulses, but through the output of the first pulse counter with an indication unit.

The novelty lies in the fact that the device for modeling a communication system provides the ability to bring information on a circular network from the main station to N subscribers in an interference environment with the majority processing mode of message transmission repeats due to the introduction of N-1 first pulse counters, N-1 fifth counters pulses, N-1 elements AND, N-1 elements NOT.

Analysis of the known technical solutions in the studied area and related areas allows us to conclude that there are no signs in them that are similar to the essential distinguishing features in the claimed device.

In FIG. 1 shows an electrical block diagram of a device for modeling a communication system.

A device for modeling a communication system contains a first pulse counter 1, RS-trigger 2, a fourth pulse counter 3, a pulse generator 4, a third pulse counter 5, an indication unit 6, a random pulse generator 7, 8 element NOT, 9 element AND, the second pulse counter 10, the fifth pulse counter 11, and the output of the pulse generator 4 is connected to the input of the second pulse counter 10, to the input of the third pulse counter 5, the R-input of the RS-trigger 2 and the first input 9 of the And element of each of the N branches, which from contains in series 8 element NOT, 9 element AND, fifth pulse counter 11, first pulse counter 1, while the output of the random error pulse generator 7 is connected to the inputs of all 8 elements NOT, and the outputs of all first pulse counters 1 are connected to the corresponding inputs of the block indicator 6, the output of the RS-flip-flop 2 is connected to the input of zeroing of the fifth pulse counter 11 of each branch and to the input of the fourth pulse counter 3, the output of which is connected to the second input of indicator block 6, the third input of which is connected to For the network pulse counter 5, the output of the second pulse counter 10 is connected to the S-input of the RS-trigger 2.

The device operates as follows.

The pulse generator 4 generates a sequence of pulses simulating the messages issued to the communication channel, each message being represented by a series of K pulses, each of which simulates the repetition of a message during transmission.

The second pulse counter 10 and RS-trigger 2 are designed to simulate a sequence of messages in which each message is transmitted only once. The number of repetitions K of each message is set by changing the volume of the second pulse counter 10.

The pulse generator 4 fills the second pulse counter 10, the capacity of which is the number K-1. The k-th pulse resets the contents of the second counter 10, the overflow pulse at the output of which goes to the S-input of the RS-flip-flop 2, setting it to a single state. At the output of the RS-trigger 2, a pulse appears, which is fed to the input of the fourth pulse counter 3, counting the number of transmitted messages.

The random error pulse generator 7, as well as the 8th element and the 9th AND element in each branch simulating the specific direction of the communication system "central station - subscriber", are designed to simulate the error flows that occur in the communication channel.

The pulse from the pulse generator 4, simulating the next repeat of the transmitted message, is fed to the first input 9 of the And element of each branch. The stream of pulses generated by the generator of a random stream of error pulses of errors 7 also enters each branch, where it is fed to input 8 of the element NOT.

If a pulse appears at the output of a random stream of error pulses 7 at the output of the 9th element And the first pulse from the pulse generator 4 and then passes through the 8th element NOT and arrives at the second input 9 of the And element, it will inhibit the appearance of a pulse at its output thereby simulating the distortion or loss of a given message repetition in the process of its transmission in all simulated communication directions. If, however, no pulse arrives from the output of the random pulse pulse generator 7, then the next pulse from the pulse generator that simulates the repetition of the message will pass through element 9 I.

The fifth pulse source 11 is designed to simulate the process of majority repetition processing on each receiving side of the communication system. The capacity of the counter 11 is set equal to the threshold for decision-making during majority processing of repetitions and is (K / 2 + 1) for K even and (K + 1) / 2 for K odd. At the beginning of the transmission of each message represented by K replays, the pulse from trigger 2 resets the fifth pulse counter 11 of each branch.

Pulses imitating repetitions of messages that have successfully passed through the communication system, from the output of the 9th element And of each branch, are received at the counting input of the fifth counter 11 and accumulate in it. When the number of pulses in the fifth counter 11 is equal to the threshold, the fifth counter 11 is reset, and the overflow pulse from it enters the first pulse counter 1 of each branch. Thus, the correct message is modeled on the communication system from the main station to N subscribers. If the other repetitions of this message pass through the communication system without distortion, then the fifth counter 11 starts counting their number, but its overflow will never happen in this case, since the number of remaining repetitions is less than the capacity of the counter 11. At the end of the last repetition of the next message, the impulse from the output of the RS-trigger 2, the fifth counter 11 will be reset to zero and it will be prepared for processing repetitions of the next message.

If, due to distortions in the communication system in the fifth counter 11 for K repetitions, the number of pulses is less than the threshold, then it will be reset to the Kth repetition of the next message from the RS trigger 2 without issuing a pulse to the first counter 1. Thus, the message is not modeled on the communication system.

It must be emphasized that an impulse arrives at the first counter only if (K / 2 + 1) repetitions at K even and (K + 1) / 2 repetitions at K odd are correctly received from K repeats displaying one message.

The outputs of the first pulse counter 1 of each branch, as well as the third 5 and fourth 3 counters are connected to the corresponding inputs of the display unit 6, which is intended to indicate the main parameters of the simulated process. Thus, the display unit 6 displays the number of primary messages N _o , counted by the fourth counter of pulses 3, the number of repetitions received in the simulated communication system N _p , counted by the third counter of pulses 5 and the number of messages correctly communicated to all subscribers N _ab.j , counted by the first pulse counter 1.

Based on these parameters, you can determine the probability of message delivery to each subscriber of the communication system:

R _dov. = N _ab.j / N _o .

The value of the number of repetitions N _p you can evaluate the reliability of the obtained simulation results.

Claims (1)

A device for modeling a communication system comprising a message pulse generator, five pulse counters, an RS trigger, an AND element, a random error pulse stream generator, a NOT element and an indication unit, the output of the first pulse counter connected to the first input of the indication unit, the output of the message pulse generator connected to the inputs of the second and third pulse counters, the first input of the And element and the R-input of the RS flip-flop, the output of which is connected to the input of the fourth pulse counter, the output of which is connected to the second input of the bl an indication window, the third input of which is connected to the output of the third pulse counter, the overflow output of the second pulse counter is connected to the S-input of the RS flip-flop, the output of the random error pulse generator through the element is NOT connected to the second input of the element AND, the counting input of the fifth pulse counter is connected to the output of the element And, the output of the RS-trigger is connected to the zeroing input of the fifth pulse counter, the output of which is connected to the input of the first pulse counter, characterized in that N-1 of the first pulse counters are introduced into it, N-1 of the fifth impulse counters, N-1 elements AND and N-1 elements NOT, and the first pulse counter is connected in series with the fifth pulse counter, element AND and element NOT, forming one of N parallel branches, each of which is connected through the input of element NOT to the generator random stream of error pulses, and through the output of the first pulse counter with an indication unit.

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