SU1725225A1 - Communication system simulator - Google Patents

Abstract

The invention relates to computing and communication technology and can be used to model a communication system. The purpose of the invention is to improve the accuracy of modeling the process of message corruption. To achieve this goal, four units of comparison of the pulse duration are entered into the device. In this device, the message is perceived undistorted only if most of it is not blocked by interference. 4 il.

Description

cl

WITH

The invention relates to computing and communication technology and can be used to model a communication system.

A device for simulating a communication system is known, comprising a pulse generator, successively connected a first generator of a random stream of interference pulses, a first element NOT and a first element AND, a second element of a random generator of a random stream of interference pulses, a second element NOT and a second element AND, a third, fourth, the fifth and sixth elements And, the output of the third element And connected to the second input of the first element And, the output of which is the first information output of the device, the output of the fourth element And li ne to a second input of the second AND gate, whose output is the second data output device 1.

The disadvantage of such a device is the limited functionality due to the fact that the device does not allow simulating the channel selection control process used for the transmission of messages.

The closest in technical essence to the present invention is a device for simulating a communication system comprising a pulse generator, five pulse counters, two random noise interference pulse generators, two NOT elements, six AND elements, a control unit and a display unit, in which the zeroing inputs pulse counters are connected to the installation input of the control unit and to the installation input of the device, the output of the pulse generator is connected to the counting input of the first pulse counter and the first inputs of the third, quarter th, fifth and sixth elements And, the input of the first Yu

sl th th

It is NOT connected to the output of the first generator of a random stream of impulse noise, and the output is connected to the first input of the first and second inputs of the third element I, the input of the second element is NOT connected to the output of the second generator of a random stream of interference pulses, and the output to the first input of the second and second inputs the fourth element And the second input of the fifth element And connected to the first output of the control unit, and the output to the second input of the first element And the counting input of the fourth pulse counter, the second input of the sixth element And connected to the second the control unit stroke and the output with the second input of the second element I and the counting input of the fifth pulse counter, the outputs of the first, second, third, fourth pulse counters are connected respectively to the first, second, third, fourth and fifth inputs of the display unit The outputs of the first, second, third and fourth elements I are connected respectively to the counting input of the second pulse counter, the counting input of the third pulse counter, the first input of the control unit and the second input of the control unit 2.

A disadvantage of the known device is the relatively low accuracy of modeling the process of distortion of messages by interference, due to the fact that the device does not take into account the distortion of messages partially susceptible to interference.

The aim of the invention is to improve the accuracy of modeling the process of corrupting messages.

The goal is achieved in that a device for modeling a communication system comprising a pulse generator, five pulse counters, two random noise pulse flow generators, two NOT elements, six AND elements, a control unit and a display unit in which the pulse counter zeroing inputs connected to the setup input of the device, the output of the pulse generator is connected to the counting input of the first pulse counter and the first inputs of the third, fourth, fifth and sixth elements AND, the input of the first element is NOT connected the output of the first generator of a random stream of interference pulses, and the output to the first input of the first and second inputs of the third And elements, the input of the second element is NOT connected to the output of the second generator of a random stream of interference pulses, and the output to the first input of the second and second inputs of the fourth And elements, the second input of the fifth element I is connected to the first output of the control unit, and the output to the second input of the first

element And the counting input of the fourth pulse counter, the second input of the sixth element And is connected to the second output of the control unit, and the output to the second input of the second element And the counting input of the fifth pulse counter, the outputs of the first, second, third, fourth and fifth counters pulses are connected respectively to the first, second, third, fourth and fifth inputs of the display unit, four pulse duration comparison units are introduced, the first inputs of which are connected to the output of the pulse generator, the second inputs of the first, second , the third and fourth comparison pulses are connected to the outputs of the first, second, third and fourth elements, respectively, and the outputs respectively to the counting input of the second pulse counter, to the counting input of the third pulse counter, to the first input of the control unit and to the second input of the control unit .

Figure 1 presents the structural diagram of the proposed device; Fig. 2 is a block diagram of the control unit; FIG. 3 is a block diagram of a comparison pulse duration unit; 4 shows timing diagrams for his work.

A device for simulating a communication system comprises a pulse generator 1, counters 2-6 pulses, generators 7 and 8 of a random stream of interference pulses, elements HE 9 and 10, elements 11-16, control block 17, pulse width comparison blocks 18-21, display unit 22 installation input 23.

The control unit 17 comprises a clock pulse generator 24, an OR element 25, counters 26 and 27 pulses, a comparison circuit 28 and a trigger 29.

Each of blocks 18-21 contains a shaper of .30 pulses on the leading edge, a shaper of 31 pulses on the falling edge, an adder 32, an RS flip-flop 33, an integrator 34 with a reset, a Schmitt trigger 35 and an AND 36 element.

The device simulates the process of transmitting a message on one (best) of the two available communication channels.

Before the device starts its operation, input 23, the installation input of the unit 17, and the installation inputs of the counters 2-6 receive a control signal that nulls these counters.

The operation of the device is as follows.

Generator 1 generates a sequence of pulses simulating a sequence of messages to be transmitted over a communication channel with a minimum level of interference. The number of pulses coming from the output of generator 1 is counted by counter 2.

The process of transmitting messages over the first communication channel is simulated using generator 7, elements 9, 11, 13 and 15, blocks 18 and 20, and counters 3 and 5.

The generator 7 generates a sequence of pulses with random durations and intervals following imitating a sequence of interference.

Pulses from the output of the generator 1 are fed to the first inputs of elements 13 and 15 and to the first inputs of blocks 18 and 21. In the absence of a locking signal from the first output of block 17, element 15 passes pulses to its first input to the counting input of counter 5 and to the second input of the element 11, the first input of which receives the pulses of the generator 7, logically inverted by the element 9.

Counter 5 counts the number of pulses received for service in the first communication channel.

In the presence of a locking signal from the first output of block 17, the element 15 does not transmit the pulses received at its input.

Element 11 in conjunction with block 18 simulates the process of distorting messages received on the first communication channel by interference. Element 11 transmits to the second input of block 18 that part of the pulse of generator 1, which does not coincide in time with the pulses of generator 7, thereby simulating at the second input of block 18 that part of the message arriving on the first communication channel that was not affected by interference.

Block 18 compares the total pulse duration from the output of generator 1, which arrived at the first input of block 18, with that part that came to the second input of block 18. In the case that the time of presence of a signal of a single level at the second input of block 18 differs from the pulse duration its first input by a value not exceeding a predetermined level g, block 18 forms at its output a short pulse that arrives at the counting input of counter 3. This simulates the determination of that fraction of the message duration that was exposed interference, and in case the distorted part of the message does not exceed the specified level, the decision

about undistorted transmission of this message over the first communication channel.

Block 18 (19-21) works as follows. Pulses of the generator 1 from the first

the block inputs (Fig. 4a) are fed to the inputs of the formers 30 and 31 and to the direct input of the adder 32. Pulses arrive at the inverse input of the adder 32 (Fig. 4b) from the output of element 11 (12-14). On the front lines

pulses from the first input shaper 30 generates short pulses (figv), which arrive at the S-input of the trigger 33, and on the back edges of the pulses from the first input shaper 31 generates short pulses (figg), which arrive at the R-input trigger 33 and at the first input of element 36.

At the output of the trigger 33 and at the reset input of the integrator 34, a signal is generated

(figd), logically inverse to the signal at the first input of the block.

The adder 32 generates a signal equal to the difference of the signals at its direct and inverse inputs. This signal arrives at the information input of the integrator 34. The integrator 34 at intervals of time coinciding with the pulses at the first input of the block integrates the signal received at its information input, and in the pauses between the pulses at the first input of the block, the signal at the output of the integrator 34 decreases to zero from - for the occurrence of a single level signal at its reset input.

The signal from the output of the integrator 34 (Fig. 4e) is fed to the input of the trigger 35, where it is compared with the threshold level Unop. corresponding to the permissible duration t of the distorted part of the message. If the signal at the output of the integrator 34 does not exceed the Unop level, the signal at the output of the trigger 35 and the second input of the element 36 (Fig. 4g) corresponds to logical 1 and the pulses from the output of the former 31 are passed to the output of the block (Fig. 4a). If the signal at the output of the integrator 34 exceeds the Unop level, then the signal at the output of the trigger 35 and the second input of the element 36 becomes the corresponding logical O. Restoration of the signal with a level corresponding to logical 1 at the output of the trigger 35 and the second input of the element 36 due to a delay The response time of the trigger 33, resetting the signal at the output of the integrator 34 and the triggering of the trigger 35 occurs later than the pulse of the driver 31 appears at the first input of the element 36, therefore in this case the pulses of the generator 31 at the output of the block do not pass t.

Thus, block 18 (19-21) forms a short pulse at its output only if the duration of the signals of a single level at its first and second inputs differ by an amount not exceeding t.

Counter 3 counts the number of pulses from the output of block 18, corresponding to the number of messages received on the first communication channel.

Element 13 together with block 20 generates pulses corresponding to messages that could be transmitted over the first communication channel, if they were received in it. The pulses from the output of block 20 are fed to the first control input of block 17.

Similarly, using generator 8, elements 10, 12, 14, and 16, blocks 19 and 21, and counters 4 and 6, the process of transmitting messages over the second communication channel is simulated. The number of messages received in the second communication channel is recorded by a counter 6, the number of messages received via the second communication channel is counted by 4. The second control input of block 17 from the output of block 21 receives pulses corresponding to messages transmitted over the second channel if they had entered it.

Block 17 determines the communication channel in which there is less interference (distortion). In accordance with this, from the outputs of block 17, control inputs of elements 15 and 16 receive control signals permitting the passage of signals over a communication channel with a lower noise level and prohibiting the passage of signals over a communication channel with a higher level of interference.

When the interference situation in the communication channels changes, unit 17 generates new control signals. In this case, of the two available communication channels, only the one in which the level of interference is less is used.

Block 17 works as follows.

The generator 24 generates a sequence of pulses with a frequency significantly lower than the frequency of the generator 1. The pulses from the output of the generator 24 are fed through the elements OR 25 to the installation inputs of the counters 26 and 27, and wrapped them.

Counters 26 and 27 count the number of messages that would not have been distorted during transmission over each channel, if they had arrived in these channels. From the outputs of counters 26 and 27, the codes go to the corresponding inputs of circuit 28. If the interference level is lower in the first communication channel (code in

the counter 26 is larger than the code in the counter 27), then a control signal appears at the first output of the circuit 28, setting the trigger 29 to a state where a signal corresponding to the logical 1 is set at its first output and the second input of the element 15. signals are allowed to pass through element 15 and signals are not allowed to pass through element 16. If the level of interference is lower in the second communication channel, a control signal appears at the second output of circuit 28, which sets the trigger 29 into such a state that second in During and at the second input signal 16 is set item corresponding to logic 1. When this signal is allowed to pass through the element 16 and is prohibited from passing signals through the member 15.

The outputs of the counters 2-6 are connected to the corresponding inputs of the block 22, which provides an indication of the main parameters of the simulated process.

Thus, block 22 displays the total number of messages to be transmitted (contents of counter 2), the number of messages received on the first communication channel (contents of counter 5), the number of messages received on the second communication channel (contents of counter 6), the number of messages received on the first communication channel (the contents of counter 3), and the number of messages received on the second communication channel (the contents of counter 4).

Claims (1)

The invention The device for modeling a communication system that contains a pulse generator, the first, second, third, fourth, fifth pulse counters, the first and second generators of a random stream of interference pulses, the first and second elements of the first to sixth elements And display unit and a control unit, the installed input of the control unit, which is the installation input of the device, is connected to the zeroing inputs of the first to fifth pulse counters, the output of the pulse generator is connected to the counting input of the first counter pulses and the first inputs of the third, fourth, fifth, and sixth elements AND, the input of the first element is NOT connected to the output of the first generator of a random flow of interference pulses, and the output is connected to the first input of the first and second inputs of the third element AND, the input of the second element is NOT connected to the output of the second generator of a random stream of interference pulses, and the output to the first input of the second and second inputs of the fourth And elements, the second input of the fifth Element And connected to the first output of the control unit, the output of the fifth And element connected to the second the input of the first element And the counting input of the fourth pulse counter, the second output of the control unit is connected to the second input of the sixth element And whose output is connected to the second input of the second element And to the counting input of the fifth pulse counter, the outputs of the first, second, third, fourth, n In addition, pulse counters are connected respectively to the first, second, third, fourth and fifth inputs of the display unit, characterized in that, in order to increase the accuracy of the simulation of the message corruption process, four pulse duration comparison blocks are entered into it, the first inputs of each of the comparison pulse duration blocks are connected to the output of the pulse generator, the outputs of the first, second, third and fourth elements AND are connected to the second inputs of the first to fourth comparison blocks, respectively pulses whose outputs are connected respectively to the counting input of the second pulse counter, the counting input of the third pulse counter, to the first input of the control unit and to the second input of the block management Omzo 26 FROM 21 FIG. I Fig.Z