SU1284003A1 - System for mutual transmission of information and service signals via single transmission channel - Google Patents

Abstract

The invention relates to communication technology. The purpose of the invention is to increase the reliability of information signal (IC) transmission. The system contains on the transmitting side: IC encoder 1, pulse converter (PI) 2, SOSTOYPTS1Y from shift register 9 and decoder 10, pulse sequence analyzer (API) 3, consisting of reversible counter 7 and decoder 8, element OR 4, source 5 service signal and key 6. At the receiving side: a linear regenerator 12, PI 13, consisting of a shift register 20 and a decoder 21, an IC decoder 14, an API 15, consisting of a reversing counter 18 and a decoder 19, an OR element 16 and a regenerator 17 service signal, as well as the communication line II .. On transmitting To its side, the encoder I encodes the incoming information flow with one of the types of the balance code. Then the command from the decoder 10, which is used to transform the IC in shift register 9, through the element III 4 enters key 6 and opens it. Key 6 prevents the IC from being repeatedly converted during transmission of a single overhead signal pulse. At the receiving side, the inverse transform of the IC is performed,. so that the decoder 14 receives the already restored IC in the specified form of the balance code. The goal is achieved by introducing encoder 1, elements OR 4 and 16, key 6 and decoder 14. The system of. 2 ,, 3 and 4 f-ly differs in the performance of PI 2 and 13 and API 3 and 15. 3 3.p. f-ly, 1 ill. (L N9 00

Description

The invention relates to communication technology and can be used to organize telecontrol and service communication in digital transmission systems using binary codes.

The purpose of the invention is to increase the reliability of the transmission of the information signal.

The drawing shows a structural electrical circuit of a system for jointly transmitting information and service signals over a single transmission channel.

Transmitter-side pulse converter 2 contains shift register 9 and decoder 10. The first, second and third outputs of shift register 9 i are connected to the first, second and third inputs of decoder 0. The fourth output of shift register 9 is the first output of pulse converter 2. The first and second outputs of the decoder 10 are connected to the first and second inputs of the shift register 9 and are the second and third outputs of the converter 2 pulses. Third

The system of joint transmission of one j, the input of the register 9 shift is per20

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On the transmit side, information signal encoder 1, converter 2, pulses, pulse sequence analyzer 3, element OR A, source 5 of service signal, key 6. The input of information signal encoder 1 is the input of the information signal (system) joint transmission of 25 one transmission channel information and service signals, and the output is connected to the first input of the converter 2 pulses, the second and third inputs of which are connected to the first The second and second outputs of the analyzer are 3 sequences of pulses, respectively. The first output of the converter 2 pulses is connected to the input of the analyzer 3 of the pulse sequence. The second and third outputs of the converter 2 pulses are connected to the first and second inputs of the element OR 4, the output of which is connected to the first input of switch 6, the second and third inputs of which 40 are connected to the first and second outputs of the service signal source 5, and the output to the fourth converter input 2 pulses.

Analyzer 3 sequences. the pulses of the transmitting side contains a reversible counter 7 and a descrambler 8, the first, second and third inputs /

which are connected respectively to the first, second and third outputs of the reversible counter 7. The first and second outputs of the decoder 8 are connected to the first and second inputs of the reversible counter 7 and are the first and second outputs of the analyzer 3 according to,; pulse sequences. The third input of the reversible counter 7 is the input of the pulse train analyzer 3.

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the second input of the converter 2 pulses, and the fourth, fifth and sixth inputs of the decoder 10 - the second, third and fourth inputs of the converter 2 pulses, respectively.

The output of the pulse converter 2 is connected via a communication line 11 to a linear regenerator 12 of the receiving side, which also contains a pulse converter 13, an information signal decoder 14, a pulse train analyzer 15, an OR 16 element connected in series, and a service signal regenerator 17, the output of which is service signal system. joint transmission of information and service signals over one transmission channel. The output of the information signal decoder 14 is the output of the information signal of a system for jointly transmitting information and service signals over one transmission channel, and the input is combined with the input of the pulse train analyzer 15 and connected to the first output of the pulse converter 13. The first and second inputs of the element OR 16 are connected to the second and third outputs of the converter 13 pulses, respectively. The output of the linear regenerator, 12 is connected to the first input of the pulse converter 13, the second and third inputs of which are connected to the first and second outputs of the pulse sequence analyzer 15, respectively.

The analyzer 15 sequence) pulses of the receiving side contains a reversible counter 18 and a decoder 19, the first, second and third inputs of which are connected to the first, second and third outputs of the reversing counter 18. The first and second outputs decipher j, the shift register 9 is first

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the second input of the converter 2 pulses, and the fourth, fifth and sixth inputs of the decoder 10 - the second, third and fourth inputs of the converter 2 pulses, respectively.

The output of the pulse converter 2 is connected via a communication line 11 to a linear regenerator 12 of the receiving side, which also contains a pulse converter 13, an information signal decoder 14, a pulse train analyzer 15, an OR 16 element connected in series, and a service signal regenerator 17, the output of which is service signal system. joint transmission of information and service signals over one transmission channel. The output of the information signal decoder 14 is the output of the information signal of a system for jointly transmitting information and service signals over one transmission channel, and the input is combined with the input of the pulse train analyzer 15 and connected to the first output of the pulse converter 13. The first and second inputs of the element OR 16 are connected to the second and third outputs of the converter 13 pulses, respectively. The output of the linear regenerator, 12 is connected to the first input of the pulse converter 13, the second and third inputs of which are connected to the first and second outputs of the pulse sequence analyzer 15, respectively.

The analyzer 15 sequence) pulses of the receiving side contains a reversible counter 18 and a decoder 19, the first, second and third inputs of which are connected to the first, second and third outputs of the reversing counter 18. The first and second outputs are the decrypt

The rator 19 is connected to the first and second outputs of the reversible counter 18 and are the first and second outputs of the pulse train analyzer 15. The third input of the reversing counter 18 is the input of the pulse train analyzer 15.

The receiving side pulse converter 13 contains a shift register 20 and a decoder 21. The first, second and third outputs of the shift register 20 are connected to the first, second and third inputs of the decoder 21. The fourth output of the shift register 20 is the output of the pulse converter 13. The first and second outputs of the decoder 21 are connected to the first and second inputs of the shift register 20 and are the second and third outputs of the pulse converter 13, and the fourth and fifth inputs of the decoder 21 are the second and third inputs of the pulse converter 13.

The system of joint transmission of information and service signals over a single transmitting channel works in the following way.

The information signal encoder 1 encodes the incoming information stream with one of the types of a batch code, for example a 5B6B code. In this case, from the output of the encoder 1 of the information signal, the code enters the shift register 9. The latter has setting inputs (first and second) and four outputs corresponding to the impulse delays of the information signal to OT, IT, 2T and 3T, where T is the value of the clock interval of the information signal. The binary service signal from the output of the source 3 of the service signal through the public key 6 enters the input of the de-encryptor 10. If the decoder 10 receives a zero binary service signal, then the information signal is transmitted via link 11 unchanged. If the decoder 10 receives a unit of the service signal, then the information signal .. is converted as follows: either the next three units of the information signal are replaced with three zeros, or three zeros are replaced with three units. However, the following three or zero units themselves are not prohibited by the ob0 algorithm.

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5B6B code, therefore, this transformation is performed only when these three units (three zeros) immediately follow the moment when the lower (upper) extreme value of the current digital sum (TCS) has been reached.

A DSL is defined as the difference between the number of ones and zeros in a coded signal, and in a 5B6B code it can take seven allowed values: from -3 to +3.

At the output of the transmitting side of the transducer's digital transducer, upon reaching, the lower (upper) extreme allowed value will take the values: -4, -5, -6 (+4, +5, +6), which is prohibited by the 5B6B code generation algorithm. Single errors will lead to the appearance of the values of TCS -4, -5, or +4, +5, so when receiving it is possible to distinguish the conversion performed in the information signal from the random error.

The conversion of the information signal is performed as follows.

From the output of the shift register 9, corresponding to the maximum delay at the ST, the information signal pulses go to the reversible counter 7, which calculates the TCS. The decoder 8 records the moments when the counter reaches 7 states corresponding to the extreme lower or upper allowed values of the TCD. The decoder 10 issues a command to one of the two setup inputs of the shift register 9, if not. its inputs receive the following pulses.

Option 1. The unit from the output of the service signal source 5, the unit from the first output of the decoder 8, which corresponds to the achievement of the lowest lower value of the TCD, the unit from each of the three outputs of register 9, the shift corresponding to the OT, IT, 2T delays.

In this case, with the decoder 10. The shift register 9 receives a command that causes each of the three outputs of the shift register 9 to be set to zero, corresponding to OT, IT, 2T delays.

Option 2. The unit from the output of the source 5 of the service signal, the unit from the second output of the decoder 8, which corresponds to the achievement of the extreme

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the upper value of the TCS, zero from each of the three outputs of the shift register 9, corresponding to the delays OT, .11, 2T.

In this case, a command is sent from the decoder 10 to the shift register 9, causing the units to be set at the corresponding three outputs of the shift register 9.

In each of these two options, the command from the output of the decoder 10, which is used to convert the information signal in the shift register 9, through the OR 4 element enters key 6 and opens it. Key 6 is entered dp in order to prevent the possibility of repeated conversion of the information signal during the transmission of one pulse of the service signal, which would make it difficult to restore the service signal at the reception. An input of the key 6 from the source 5 of the service signal is applied to the clock frequency of the service signal, which closes the key 6 with the start of the next clock interval of the service signal.

At the receiving side, from the linear regenerator 12, the received and 111 pulses are fed to the shift register 20. The pulses from the corresponding outputs of the shift register 20 are fed to the input of the reversing counter 18 and to the inputs of the decryptor 2. At one of the outputs of the decoder 21, a unit appears with the following combinations of pulses at its input:

a unit from the first output of the decoder 19, which corresponds to the achievement of the lowest lower value of the TCS; zero from each of the three outputs of the shift register 20, corresponding to OT, IT, 2T delays (in this case, the first output of the decoder 21 is set to one); unit from the second output of the decoder 19, which corresponds to the achievement of the extreme upper value of the TSC; a unit from each of the three outputs of the shift register 20, corresponding to OT, IT, 2T delays (in this case, the second output of the decoder 2 is set to one).

The pulses produced by the decoder 21 are combined in the element of GTP 16 and are fed to the service signal regenerator 17.

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The same pulses are fed to the setup inputs of the shift register 20, causing the information signal to be inversely transformed, so that the information signal in the 5B6B code is already received at the information signal decoder 14.

The outputs of the decoders 8 and 19 are connected to the inputs of the reversible counters 7 and 18 dp of blocking the counters when the upper (lower) extreme allowed value of the TCS is reached. If the decoder 8 (19) captures the achievement of the upper extreme allowed value of the TTsS, a command is sent to the input of the counter 7 (18) that prohibits addition until zero arrives at the input of the counter 7 (18), which corresponds to the subtraction, and the value of the DTs It will become less than the maximum, and the output of the decoder 8 (19) will be reset to zero.

When the lower extreme allowed value of the DSV is reached, subtraction is prohibited. These interlocks are necessary for installing the counters when turning on the receiving and transmitting parts (since at the initial moment the outputs of the counters can be in an arbitrary state), as well as for working off random errors, since the errors shift the DSVs beyond the permissible values.

To implement the conversion

35 information signal in order to transfer service information necessary,. so that the pulse frequency of the service signal is lower than the frequency with which the coincidence of conditions occurs, which is necessary. to convert the information signal (three units of succession following the achievement of the lower extreme allowed value of the TSC or three zeros following the achievement of

 the upper extreme permitted value of the TCC).

For example, when applying the code 5B6B, the clock frequency of the service signal must be less than the clock

50 frequencies of the information signal not less than 1200 times.

Claims (4)

Invention Formula j. 1. A system for joint transmission of information and service signals over a single transmitting channel, containing on the transmitter side a pulse train analyzer. thirty 40 712 the source of the service signal and the pulse converter, the first output of which is connected to the input of the pulse train analyzer, on the receiving side - a pulse train analyzer, the service signal regenerator, the output of which is the output of the service signal of the joint transmission system through one transmission channel, . serially connected linear regenerator and pulse converter, and the input of the linear regenerator is connected via a communication line with the output of the transmitting side pulse converter, I distinguish nor the reliability of the transmission of the information signal, on the transmitting side the following are connected: the unwired OR element and the key, the second j and the third - INPUTS of which are connected respectively to the first and second outputs of the signal source, and the first and second inputs of the OR element are connected respectively to the second the third output of the pulse converter; an information signal encoder is inputted, the output of which is connected to the first input of the pulse converter, and the input is the input of a joint transmission system over a single The first channel of the information and service signals, the first and second outputs of the pulse sequence analyzer are connected to the second and third inputs of the converter, the pulse generator, the key output is connected to the fourth input of the pulse converter, the OR element is entered on the receiving side, the output of which is connected with the service signal regenerator input, information signal decoder, the output of which is the output of the information signal of the system of joint transmission over one transmission channel information signals and service signals, and the input is combined with the analyzer input of the pulse sequence and is connected to the first output of the pulse converter, the second and third outputs of which are connected respectively to the first and second inputs of the Ili element, and the first and second outputs of the sequence analyzer five 0 five 0 five pulses - respectively to the second and third inputs of the pulse converter. 2. The system of claim 1, wherein each pulse train analyzer comprises a reversible counter and a decoder, the first and second outputs of which are the first and second outputs of the pulse sequence analyzer and connected respectively to the first and second inputs of the reversible counter, first, The second and third outputs of which are connected respectively to the first, second and third inputs of the decoder, and the third input is the input of the pulse train analyzer. 3. The system according to claim 1, wherein the transducer side impulse converter contains a shift register and a decoder, the first, second and third inputs of which are connected respectively to the first, second and third outputs of the shift register The fourth output of which is the first output of the pulse converter, the first and second outputs of the decoder are connected respectively to the primary and the second inputs of the shift register and are the second and third outputs of the pulse converter, the third input of the shift register is the first input. The house of the pulse converter, and the fourth, fifth, and fifth and sixth inputs of the decoder, respectively, are the second, third, and fourth inputs of the pulse converter. 4. The system according to claim 1, distinguished by the fact that the receiving side pulse converter contains a shift register and a decoder, the first, second and third inputs of which are connected respectively to the first, second and third outputs of the shift register, the fourth output of which is the first output of the pulse converter, the first and second outputs of the decoder connection, respectively with the first and second inputs of the shift register, and are the second and third outputs of the pulse converter, the third input of the shift register is the first input of the pulse converter, and the fourth and five inputs of the de- 1Phiftorator are the second and third inputs of the pulse converter, respectively. 0 0 five R  lg -f ,, g. t