SU1053315A1 - Device for measuring error factor in digital transmission systems - Google Patents

Abstract

A DEVICE FOR MEASURING THE ERROR COEFFICIENT IN DIGITAL TRANSMISSION SYSTEMS, containing serially connected driver, error signals, a selector indicator and a counter, a clock pulse generator, in order to improve the accuracy of error rate measurement while reducing the matching time. connected And chains, each of which consists of a serially connected shift register and the element And, while the information input of the shift register is connected to element stroke: And, the output of the last element And is connected to the information input of the error signal generator, the clock input of which is connected to the output of the clock generator, which is connected to the clock inputs AND of the shift registers, in addition, the input of the clock generator, the information input of the first shift register and The second input of the error selector is combined and (L are the input of the device.

Description

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The invention relates to telecommunications and can be used to measure the error rate in linear paths or terminal equipment of digital transmission systems (DSPs). A device for measuring the error rate in a DSP, containing a serially connected error signal generator, an error selector and a counter, as well as a serially connected clock generator, a phase shifter and a controlled divider, the output of which is connected to the input voltage generator and the second the input of the connections with one .signal of the signal analyzer, the input of which is connected to the output of the error selector, and the second output is connected to the second input of the phase shifter; It is that, due to even small differences oscillator frequency and the measured signal device just from time to time is in synchronism search mode, at which time the obtained values of the error rate too high to establish synchronism. In the known device for entering into synchronism, it takes 0.3 s, i.e. a sufficiently long time, that at one of the new transmission rates, for example, 8.448 Mbit / s, 2.5 million pulses will pass during this time. In addition, at large values of the error rate in the measured signal, the minimum of the meter readings indicates that the signal from the generator is in phase and measured. the signal, at which the measured value is measured, ranges from within. This circumstance also reduces the accuracy of measurements and causes unstable operation of the device. Thus, in a known device, due to a rather frequent search for synchronism and a considerable amount of time spent on it, a part of time drops out of the measurement session and, naturally, a certain amount of errors are not fixed. The purpose of the invention is to improve the accuracy of measurement of the error rate while reducing the time taken to synchronize. This goal is achieved by the fact that a device for measuring the error rate in a DSP containing a serially connected error generator, an error selector and a counter, a clock pulse generator, are connected in series and chains, each of which consists of a series-connected shift register and element And, with the information input register-. The shift offset is connected to the second input of the element I, the output of the last element I is connected to the information input of the error signal generator, the clock input of which is connected to the output of the clock generator, which is connected to the clock inputs of the shift registers, besides the input of the clock generator, the information input of the first the shift register and the second input of the error selector are combined and are the input of the device. Figure 1 shows the structural electrical circuit of the device for measuring the error rate in the EAF; 2 shows timing diagrams for his work. The device contains an error selector 1, a counter 2, a shaper 3 error signals AND shift registers 4, elements 5 and an oscillator 6 clock pulses. The device works as follows. The binary signal (Fig. 2 p (), whose error ratio is to be measured and containing a periodically repeated combination of pulses, is fed to the first input of the error selector 1, made, for example, as an OR element, and simultaneously to the input of the first shift register 4 and the input 6 clock pulse generator, made, for example, according to the LC oscillator circuit with external synchronization and an amplifier-limiter and shaper of short pulses switched on at its output, which allows to extract the sinusoidal state from the input signal the clock frequency of the measured signal and form a sequence of clock pulses from it fed to the second inputs of shift registers 4 (Fig. 28). Shift register 4 is chosen such that the binary signal at its output is delayed relative to the input one (Fig. 2a) for a time equal to the repetition period T of the combination 10 (FIG. 2b). The input and output signals from the first shift register 4 are fed to the first element, AND 5, the output of which is shown in FIG. 2. Since, apart from periodically repeated pulses 10, the presence or absence of the remaining pulses is random, it is possible to consider the probability of their presence at a given clock interval equal to R. 0.5, and the probability of periodically repeating pulses P2-1. Then, at the output of the first element, And 5, the probability of periodically repeating symbols is equal, and the rest of random symbols, –0.25. The subsequent shift, the signals are again on T in the second shift register 4 and modulo two addition in the second element And 5 gives the probability of periodically repeated signals and random, respectively: Pi (pj -If PI (PI) -0.625. After each subsequent shift by the output of the corresponding element And 5 the likelihood of a signal out of cycles, on which there are periodically (at intervals T) repeated combinations 40, decreases, tends to zero. After the fourth shift at the output of the element And 5 Pi l, 52lG after the sixth, 42 -Y, etc. With an increased likelihood of units in the original signal, for example, after the seventh shift register 4, 25.10-. Thus, after the -th shift, practically after the sixth, at the output of the element And 5 are periodically repeated (with a period T of the unit, coinciding in time with corresponding periodically repeating units in the measured signal (Fig. 2a). Therefore, the signal at the output of the 3 error signal generator received upon command from the output of the last element And 5. is in phase with the period. by repeating.-10 symbols in the measured signal. Comparison of these signals in the error selector 1, implemented as an OR element, makes it possible to output (when a linear signal is broken): error pulses (Fig. 2a), counted by counter 2. Since synchronization in this device is established very quickly, ro (almost after passing a signal through 2-3 shift registers) and later on throughout the entire measurement session is not lost, the measurement accuracy is quite high and practically does not depend on the error rate in the measured signal, since even with its magnitude is not equal to 10, the probability of units are periodically repeated emoy combination is 1-0, and 99 after the passage 4 and the shift registers periodic signal at the output of the last AND gate 5 occurs with almost the same probability. The use of the proposed device in comparison with the known one allows to increase the efficiency of the DSP, since a more accurate measurement of the error rate reduces the frequency of equipment outages due to an overestimation of the measured values of the error rate obtained using the known device. GBP 4B:

Claims (1)

DEVICE FOR MEASURING ERROR COEFFICIENT IN DIGITAL TRANSMISSION SYSTEMS, containing a shaper connected in series. error signals, error selector and counter, clock generator, characterized in that, in order to improve the accuracy of measuring the error coefficient while reducing the time of entering into its synchronism, series-connected AND chains are introduced, each of which consists of series-connected shift register and AND element wherein the information input of the shift register is connected to the input of the element And, the output of the last element And is connected to the information input of the error signal generator, the clock input of which is connected is connected with the output of the clock generator, which is connected to the clock inputs and shift registers, in addition, the input of the clock generator, the information input of the first shift register and, the second input of the error selector are combined and are the input of the device. About in io in>