SU1104670A2 - Bipulse regenerator - Google Patents

Abstract

BIMULAR REGENERATOR auth.St. No. 892742, characterized in that, in order to monitor the regeneration error rate, the D-trigger and the error counter are entered in series with the output of the pulse generator connected to the counting trigger input via the coincidence input, the D-trigger of the Trigger is connected with the output of the pulse selector, the C input of the D-trigger, is connected to the output of the clock signal generator, and the second input of the matching element is connected to the additional output of the pulse selector. 4 about: -h

Description

The invention relates to telecommunications and is intended for use in digital transmission systems with electrical and optical cables. According to the main author. No. 892742, a bi-pulse regenerator is known, which contains a series-connected drive and a gating unit, whose outputs are connected to the trigger trigger inputs, as well as sequentially connected a grounding unit connected to both drive outputs, a differentiator unit, a pulse selector, a clock generator and a gate driver. , the output of which is connected to the k auxiliary input of the gating unit, while the output of the clock generator is connected to the auxiliary input of the village Pulses and through the inverter are connected to the input of the farm1) pulse generator, the output of which is connected to the counting input of the trigger CO However, the known device does not allow remote control of the error rate (main parameter) of the regenerator, as well as the total error rate of the chain of regenerators installed in digital transmission system. Unlike transmission systems with electrical cables, where remote monitoring of the state of the parameters of the generators can be performed over additional pairs of cables, the insertion of copper pairs into optical cables will deprive them of their main advantage. The purpose of the invention is to provide control of the error rate of regeneration. To achieve this goal, a bi-pulse regenerator containing a series-connected drive and a gating unit, whose outputs are connected to the installation inputs of the trigger, as well as a series-connected rectifier unit connected to both outputs of the drive, differentiation unit, pulse selector, clock generator and gate driver. pulses, the output of which is connected to the auxiliary input of the gating unit, and the output of the clock generator is connected to the additional an input of the pulse selector and through an inverter connected to the input of the pulse generator, the output of which is connected to the counting trigger input, serially connected D-trigger and error counter are inputted, while the output of the pulse shaper is connected to the counting trigger input through the input match element, D input D Trigger is connected to the output of the pulse selector, C input of the Trigger is connected to the output of the sync signal generator, and the second input of the coincidence element is connected to the additional output of the pulse selector. . FIG. Figure 1 shows a structural electrical circuit of a bi-pulse regenerator; in fig. 2 - shows time diagrams for the operation of the device. The bi-pulse regenerator contains a drive 1, a rectifying unit 2, a differentiating unit 3, a pulse selector 4, a shaper 5 sync signal: Nala, a sampler 6 of gating pulses, a strobe block 7, an inverter 8, a shaper 9 pulses, a coincidence element 10, a trigger 11, D - trigger 12, counter 13 errors. Bi-pulse regenerator works as follows. The signal passed through the cable in the regeneration section (Fig. 2a) is fed to accumulator 1, where the optimal filtration of the bi-pulse signal is performed. Direct and inverse stresses of FIG. 25, b at the outputs of accumulator 1 in rectifying unit 2 create two pulse sequences. Their negative transitions (changes in voltage from a positive value to zero), identified by differentiating unit 3 (Fig. 21), jointly act on the selector 4 of pulses, the voltage at whose output (Fig. 2 E) is set by trigger pulses to zero state T / 2. In this case, the time selection of periodic pulses (caused by transitions of a bi-pulse signal in the middle of clock intervals) is performed, since random transitions at the boundaries of clock intervals are separated from periodic transitions to distances T / 2, and the inertia of the selector 4 pulses is T / 2 . T. Therefore, at the output of the selector 4, a periodic sequence of pulses is created, from which the driver 5 of the clock signal creates a clock signal (Fig. 26). Connecting the output of the synchro shaper 5 to the auxiliary input of the selector 4 saves the clock signal phase when the pulse frequency is disturbed by noise. From the positive transitions of the clock signal in the former 6, a periodic sequence of gating pulses is created (Fig. 2), with which at the edges of the clock intervals at maximum voltages of the useful signal at the outputs of accumulator 1 in the gating unit 7, the biopulse elements are received for receiving signal on the clock interval. At negative voltages at the first half-cycle interval and positive at the second, at the first output of accumulator 1, positive voltages are created, leading to a decision at the first output of the strobe unit 7 (Fig. 2 3). The positive element of the bi-pulse signal is positive voltages at the boundaries of the clock intervals are formed at the inverse output of the accumulator 1 and decisions are made at the second output of the gating unit 7 (Fig. 2 and). In the inverter 8, the phase of the clock signal changes (Fig. 2k and therefore a periodic sequence of pulses located in the middle of the clock intervals is created at the output of shaper 9 (Fig. 2n. At positive voltages at the inverse output of the selector 4 (Fig. 2 LA through The coincidence element 10. These pulses (Fig. 2n) are applied to the counting input of the trigger 11 and create transitions in the regenerated bi-pulse signal in the middle of the clock intervals (Fig. 2o). The first decisive signals to the first installation input of the trigger 11 o, at its second installation input — the second decision signals of the gating unit 7, and at the counting input — the pulses of the element 10 allow the biopulse signal to be restored at the output of the trigger 11 (FIG. 2 o). The constant sign of the bi-pulse signal is the presence of two opposite-polarity pulses within the clock interval, which characterizes the occurrence of an error. In this case, the selector 4 does not operate and the zero voltage at its inverse output (Fig. 2m) in the element 10 coinc. spinning prohibits respective pulse shaper 9 pulses. Therefore, at this clock interval, the state of trigger 11 in the middle of the clock interval (Fig. 2 o) does not change and the polarities of the pulses in the regenerated bi-pulse signal do not change (the bi-pulse condition of the signal is violated). Due to this, the error found in the intermediate regenerator is recorded in its output signal. The control of the total coefficient, the chain errors in series with the intermediate regenerators is carried out in the terminal regenerator with the help of the D-trigger 12 and the error counter 13. In the absence of errors (biopulse violations in the received signal), the output of the selector 4 periodically | is set to zero states. Their effect on the D input of the D trigger 12 at positive transitions in the voltage of the shaper 5 of the sync signal at the C input of the trigger translates it into a permanent zero state. On error, i.e. in the absence of a transition in the middle of the clock interval in the received signal, the selector 4 does not work, which creates a positive voltage at the D input of the trigger 1 2 at the moment when the positive transition of the driver 5 of the pulses appears at the C input. Therefore, at the output of D-flip-flop 12, a positive pulse of duration T (Fig. 2 p) is formed, which is determined by the time between two positive transitions of the signal at the C input created by the pulse shaper 5. The positive pulses of the trigger 12 are summed up in the error counter 13 errors and, when averaged over a certain time, allow the error rate to be determined. The biopulse violation in the output signal of each intermediate regenerator reflects both its own errors and the errors of the previous regenerators. Counting them in the final regenerator gives the total error rate.

Thus, maintaining the ultimate potential noise immunity of receiving and regenerating signals, the independence of the formation of a clock signal from the statistical properties of the transmitted digital information, the proposed bi-pulse regenerator allows digital transmission systems to organize remote monitoring of the error rate without using additional copper pairs and service channels.

Claims (1)

Bi-Pulsed Regenerator No. 892742, characterized in that, in order to ensure control of the regeneration error coefficient, a series-connected D-flip-flop and an error counter are introduced into it, while the output of the pulse shaper is connected to the counting input of the trigger through the input matching element, the p-input of the p-trigger is connected with the output of the pulse selector, the C-input of the D-trigger is connected to the output of the clock driver, and the second input of the coincidence element is connected to the additional output of the pulse selector. 1 f