RU2037967C1 - Method for transmission of digital linear signals in fiber-optical transmission systems - Google Patents

Abstract

FIELD: communication devices. SUBSTANCE: method involves additional balancing of constant constituent of linear electric signal after its integration at transmitting part. Base pulse-code modulated signal is encoded according to equation f= [(m+2)·f]/m, where f is frequency of clock pulses of converted base pulse-code modulated signal, m is any non-zero integer. Encoding of additional pulse-code modulated signal is performed according to equation f_add= [(m+2)·f/m -f]/m+2,, where f_add is frequency of clock pulses of converted additional pulse-code modulated signal. At receiving part of device additional pulse-code modulated signal is encoded according to equation f_add= [(m+2)·f/m - f]/m+2 , and additional encoded pulse-code modulated signal is decoded according to equation f_dec= [(m+2)·f/m-(n-2)·f_add]/h, where f_dec is frequency of clock pulses of additional pulse-code modulated signal. Unbalance of electric linear signal is restored at receiving part of device after regeneration of linear signal. Converted additional pulse-code modulated signal is decoded in same way as decoding of converted additional pulse-code modulated signal of receiving part. Decoding of converted base pulse-code modulated signal is performed according to encoding equation of base pulse-code modulated signal of transmitting part. EFFECT: increased functional capabilities. 2 dwg

Description

 The invention relates to communication technology and can be used to transmit a digital linear signal in trunk and zonal communication lines at a transmission speed of 8.448 Mbit / s and above.

 A known method of transmitting a digital linear signal [1] which allows you to transmit together with the main information signal an additional signal. The total signal is obtained through two-stage coding. Initially, conversion to 5B6B code occurs, and in the next step, additional bits are added. In this case, the transmission rate of the additional bits is 7.7% of the total output linear signal speed.

 The disadvantages of this method include the phenomenon of propagation of errors of a linear signal due to the use of block coding. Also, the disadvantages of the analogue are the more stringent requirements for the operation of the device, a large power consumption. These disadvantages arise due to a significant increase in the transmission speed of the linear signal.

 Closest to the invention, the technical solution is a method of transmitting a digital linear signal [2] consisting in the fact that it allows transmitting, together with the main information signal, an additional PCM signal. The total linear signal is obtained through two-stage coding; the linear signal is balanced in the first stage when converted to the 7B8B code. At the second stage of coding, the linear signal is recorded in a special format with additional bits. The extra bit rate is approximately 2.2% of the total linear output signal rate.

 The disadvantage of this method is that the balance of the linear signal is carried out by encoding with a block code 7B8B and in case of distortion of any bit a packet of errors of eight bits occurs. Thus, in the prototype can be the process of propagation of errors. This disadvantage persists in the case of further combining of several signals in order to obtain a higher-speed linear signal.

 The goal is to increase the reliability of the transmitted information while maintaining the ability to transmit additional information. In addition, it allows for n-fold combining of linear signals to produce a higher-speed linear signal without additional processing.

, где f_{преобр.осн.ИКМ} частота следования тактовых импульсов преобразованного основного ИКМ-сигнала;
f_{осн.ИКМ} частота следования тактовых импульсов основного ИКМ-сигнала;
m любое целое число, не равное нулю, кодирование дополнительного ИКМ-сигнала осуществляют по формуле
f_{преобр.доп.ИКМ}

, где f_{преобр.доп.ИКМ} частота следования тактовых импульсов преобразованного дополнительного ИКМ-сигнала;
m любое целое число, не равное нулю, на регенерационной части линии связи кодирование дополнительного ИКМ-сигнала производят аналогично кодированию дополнительного ИКМ-сигнала передающей части, а декодирование преобразованного дополнительного ИКМ-сигнала осуществляют по формуле, обратной формуле кодирования дополнительного ИКМ-сигнала в передающей части, на приемной части канала связи после регенерации линейного сигнала производят восстановление разбаланса линейного электрического сигнала, декодирование преобразованного дополнительного ИКМ-сигнала производят аналогично декодированию преобразованного дополнительного ИКМ-сигнала регенерационной части, а декодирование преобразованного основного ИКМ-сигнала производят по формуле, обратной формуле кодирования основного ИКМ-сигнала передающей части.This problem is solved by the fact that by the method of transmitting a digital linear signal, including on the transmitting part, encoding the main PCM signal, encoding the additional PCM signal, multiplexing the converted main and additional PCM signals, converting the linear electrical signal to a linear optical signal, transmitting a linear optical signal on the communication line, on the regeneration part, the conversion of a linear optical signal into a linear electrical signal, the regeneration of a linear electronic signal, synchronization of the linear electrical signal with the extraction of the converted additional PCM signal, decoding the converted additional PCM signal, coding of the additional PCM signal, multiplexing of the converted additional PCM signal with a linear electric signal, converting the linear electrical signal to a linear optical signal, transmission of a linear optical signal through a communication line, and at the receiving part, the conversion of a linear optical signal to an electric signal, regeneration of a linear electric signal, synchronization of a linear electric signal with the extraction of the converted additional PCM signal, decoding the converted additional PCM signal, decoding the converted main PCM signal, after multiplexing on the transmitting part, the DC component of the linear component is additionally balanced electrical signal, the coding of the main PCM signal is carried out according to the formula
f _{Convert Primary PCM}

Where f _{preobr.osn.IKM} repetition frequency of the main clock transformed PCM signal;
f _osn.IKM frequency clock pulse repetition basic PCM signal;
m any integer non-zero, the coding of an additional PCM signal is carried out according to the formula
f _{conversion add.PCM}

, where f _{preliminarily} add PCM clock frequency of the converted additional PCM signal;
m any non-zero integer on the regeneration part of the communication line, the additional PCM signal is encoded in the same way as the additional PCM signal, and the converted additional PCM signal is decoded using the formula inverse to the additional PCM signal encoding formula in the transmitted part , at the receiving part of the communication channel after regeneration of the linear signal, the unbalance of the linear electric signal is restored, decoding the converted additional The actual PCM signal is produced similarly to the decoding of the converted additional PCM signal of the regeneration part, and the decoding of the converted main PCM signal is performed according to the formula inverse to the encoding formula of the main PCM signal of the transmitting part.

 In FIG. 1 shows a digital linear signal transmission device; in FIG. Figure 2 shows a signal distribution diagram in fiber optic transmission systems.

 The digital linear signal transmission device comprises, on the transmitting part, the main PCM signal encoding unit 1, the additional PCM signal encoding unit 2, combining unit 3, the DC signal balancing unit 4, the electrical signal to optical converter 5, the optical converter 6 on the regeneration part signals to electrical, linear signal regenerator 7, linear signal synchronization unit 8, additional PCM signal decoding unit 9, additional coding unit 10 o PCM signal, combining unit 11, electrical to optical signal converter 12, optical to electrical signal converter 13, linear signal regenerator 14, synchronization block 15, decoding unit 16, linear signal unbalance recovery unit 17, main decoding unit 18 PCM signal, communication line 19.

 A digital linear signal transmission device operates as follows.

 The main PCM signal is input to the coding unit 1 of the main PCM signal of the transmitting part, where encoding is performed. The encoding includes a number of sequential operations: converting the main PCM signal to NR2 format, frequency multiplexing (Fig. 2, a) of the linear signal, as a result of which two more bits are added to each information block consisting of m bits of the input signal.

 In parallel with this operation, an additional PCM signal is encoded, which includes the following operations: converting the additional PCM signal to NR2 format, matching the speed of the additional PCM signal with the repetition rate of the additional bits designed to transmit the additional PCM signal (Fig. 2b).

 The next step is to combine the converted primary and secondary PCM signals. As a result, at the output of the transmitting unit combining unit 3, an intermediate signal is obtained (Fig. 2, d), which is input to the balancing unit 4 of the DC component of the linear signal.

 The absence of a drift in the DC component of the signal is one of the basic requirements for a linear signal. Thus, in the received intermediate signal (figure 2, g) it is necessary to eliminate the drift of the DC component, which is inherent in any random signal.

 Balancing is as follows.

 The value of the current digital sum (MTC) of the packet m bits of the intermediate signal is analyzed and the sign of this MTC is determined. Exceeding the number of zeros over units gives a sign equal to (-) MCC, in case of excess of units over zeros in a pack of m bits, the MTC sign is respectively equal to (+) MSC.

 The next operation is to compare the sign of the MTC pack of m bits with the sign of the MCC of all previous packs that have passed in an infinitely long time. This total TCS sign is stored in the memory of the balancing unit 4 of the DC component of the linear signal. If the signs of the MTC do not coincide, a pack of m bits retains its original value. In the case of coincidence of the signs of the MTC pack of m bits is inverted, which leads to a change in the ratio of the number of units and zeros to the opposite, while the sign of the MTC pack of m bits is changed. Information about the polarity of the packet is transmitted by one of the additional bits that were entered into the format of the linear signal (Fig.2, c).

 The converted packet m bits is added to the adder of the block 4 for balancing the DC component of the linear signal, after which a new TCS sign of all past packets is determined. Next, the balancing cycle is repeated.

 After the operation of balancing the linear signal, the electric signal is converted into an optical signal by means of a corresponding converter 5 of the electric signal in the optical transmitting part. Next, the linear signal (Fig. 2, d) enters the communication line 19, in this case, the optical one, and then undergoes the reverse conversion in the converter 6 of the optical signal into an electrical regeneration part. After the conversion, the linear signal enters the regenerator 7 of the linear signal of the regeneration part, where the pulses of the linear signal are reconstructed in amplitude and phase.

 The regenerated signal is fed to the block 8 synchronization of the linear signal of the regeneration part, where the converted additional PCM signal is extracted (figure 2, e).

 After isolation, an operation is carried out to decode the additional PCM signal, as a result of which an additional PCM signal is obtained at the output of the decoding unit 9 of the additional PCM signal of the regeneration part.

 At the same time, an encoding operation is performed using the encoding unit 10 of an additional PCM signal of the regeneration part. The signal received at the output of the additional PCM signal coding unit 10 in the regeneration part, simultaneously with the linear signal received at the output of the regenerator 7 of the linear signal of the regeneration part, are combined into a single linear signal, which is obtained at the output of the block 11 combining the regeneration part. The converted additional signal (Fig. 2, g) is recorded in the same places where the selected converted additional PCM signal is located (Fig. 2, f).

 After combining in the regeneration part, the operations of converting the electrical signal to the optical one, transmission via the optical communication line 19, reverse conversion in the converter 13 of the optical signals to electrical receiving part, regeneration of the linear signal receiving part in the regenerator 14, synchronization of the linear signal with in synchronization block 15 are carried out the receiving part, decoding in block 16 decoding the main PCM signal of the receiving part.

 Thus, at the output of the additional PCM signal decoding unit 16 of the receiving part, a signal is obtained similar to that which was applied to the input of the additional PCM signal encoding unit 10 in the regeneration part or in the coding unit of the transmitting part, provided that this signal is in the regeneration part not stand out.

 Simultaneously with the output of an additional PCM signal in the receiving part, the main PCM signal is extracted. For this, the linear signal from the output of the receiver linear signal regenerator 14 is fed to the linear signal unbalance recovery unit 17, where the state of the unbalance signal is analyzed (Fig. 2, c), and the incoming information packet of m bits is either inverted or passed to decoding unit 18 main PCM signal of the receiving part without change.

 After restoration of the unbalance of the linear signal, flows c and b are eliminated (Fig. 2, c, b). As a result, at the output of the unbalance recovery unit 17, a converted main PCM signal is obtained (Fig. 2, a), which is fed to the input of the main PCM signal decoding unit 18, the output of which is the main PCM signal, the same as that entered the input unit 1 of the coding of the main PCM signal of the transmitting part.

Claims (1)

METHOD FOR TRANSMITTING A DIGITAL LINEAR SIGNAL IN FIBER OPTICAL TRANSMISSION SYSTEMS, including coding of the main PCM signal on the transmitting part, coding of the additional PCM signal, combining the converted main and additional PCM signals, converting the electrical linear signal into an optical linear signal, transmitting in communication, on the regeneration part, the conversion of the optical linear signal into an electric linear signal, the regeneration of an electric linear signal ignal, synchronization of the linear electric signal with the extraction of the converted additional PCM signal, decoding the converted additional PCM signal, coding of the additional PCM signal, combining the converted additional PCM signal with the electric linear signal, balancing the DC component of the linear signal, converting the electric linear signal into optical a linear signal, transmission of an optical linear signal through communication, and optical linear signal into an electric linear signal, regeneration of the electric linear signal, synchronization of the electric linear signal with the extraction of the converted additional PCM signal, decoding the converted additional PCM signal, decoding the converted main PCM signal, characterized in that after combining on the transmitting part the balancing is constant component of the linear signal is produced by inverting a packet of m bits of the main PCM signal in case of coincidence i are signs of the sum of all previous packets of m bits of the main PCM signal for an infinitely large period of time and packs of m bits of the main PCM signal, in case of mismatch of signs of the sum of all previous packets of m bits of the main PCM signal for an infinitely large period of time and packs of m bits of the main PCM signal, a pack of m bits of the main PCM signal is unchanged, the polarity of the sign of the packets of m-bits of the main PCM signal is transmitted as a code in the unbalance signal, packets of m bits of the main PCM signal that have been balanced, summarize after which they determine a new sign of the sum of all previous bursts of m bits of the main PCM signal for an infinitely large period of time, the polarity of the packet of m bits, the main PCM signal is determined depending on the number of single and zero pulses in the packet, the excess of the number of zeros over units in the packet gives a minus sign, the excess of a unit of units over the number of zeros gives the plus sign, balancing is performed continuously as each new packet of pulses arrives, the main PCM signal is encoded according to the formula

where f <Mv> main PCM <D> pulse repetition rate of the converted main PCM signal;
f _osn.IKM frequency clock pulse repetition basic PCM signal;
m ≠ 0 is any integer
encoding an additional PCM signal is carried out according to the formula

where f <Mv> add. PCM <D> pulse repetition rate of the converted additional PCM signal,
encoding an additional PCM signal is carried out according to the formula

and decoding the converted additional PCM signal is carried out according to the formula

where f _dop.IKM frequency clock pulse additional PCM signal;
h is an indicator of the hierarchy of PCM systems,
at the receiving part, after regeneration of the linear signal, the unbalance of the electric linear signal is restored if there is information about the inversion in the unbalance signal, decoding of the converted additional PCM signal is carried out according to the formula

decoding of the converted main PCM signal is performed according to the formula

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