SU1003364A1 - Device for monitoring digital communication channel - Google Patents

Description

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The invention relates to telecommunications and can be used to control the quality of a digital channel without interruption.

A device for monitoring a digital communication channel is known, comprising an indicator and a pseudo-error detector connected in series and a pseudo-error partial meter, the axial error detector being implemented as a main and additional demodulator whose outputs are connected to the first and second inputs of the adder, the output of which is the detector output, respectively. pseudo-usb, whose input is the combined inputs of the main and additional demodulators 1.

However, the known device does not have a high accuracy control of a digital communication channel.

The purpose of the invention is to improve the accuracy of control.

This goal is achieved by the fact that the device for monitoring a digital communication channel, containing an indicator and a serially connected pseudo-detector pseudo-pseudo-pseudo-pseudo-pseudo-pseudo-pseudo-pho todio an adder, the output of which is the output of the pseudo-device detector, whose input is the combined inputs of the main and additional demodulators, is entered in series the dongle key, the error rate meter, the calibrator and the switch, and the address driver and the memory unit connected in series, the output of the main demodulator of the pseudo error detector are connected to the signal input of the key, the control input of which

Claims (2)

15 connect with the second output of the calibrator, the third output of which is connected to the control input of the switch, the output of which is connected to the input of the pseudo-error detector, the output of the pseudo-error frequency meter is connected to the input of the address former, and the second output of the error rate meter is connected to the memory input of the memory unit, the control The input and output of which are connected respectively with the fourth output of the calibrator and with the input of the indicator. In addition, the calibrator is made in the form of a serially connected control unit, an attenuator, the second input of which is connected to the output of the noise generator, and a mixer, the second input of which through the modulator is connected to the output of the pseudo-random sequence generator, and the first. The second, third and fourth outputs and the calibrator's axo-IO house are the mixer output and the second, third and fourth outputs and the input of the control unit, respectively. The drawing shows the structural electrical circuit of the device for monitoring the digital communication channel. The device contains the main 1 and additional 2 demodulators and the adder 3 modulo two, forming a pseudo-error detector 4, a pseudo-error frequency meter 5, a frequency meter 6, an opamp side address driver 7, a memory block 8, a calibrator 9 consisting of a control block 10 , attenuator 11, generator 12 noise, mixer 13, modulator 14 and generator 15 pseudo-random sequence, switch 16, key 17 and indicator 18. The device works as follows. Before the measurements are started, the device is automatically calibrated using a pseudo-random sequence signal (bandwidth mixed with noise of known power. To do this, using a command from control unit 10, switch 16 connects the output of mixer 13 to input of demodulators 1 and 2, key 17 connects the output of main demodulator 1, with the input of the frequency meter 6 at the opto side, the attenuator 11 sets a certain level of noise from the noise generator (GS) 12 at the input of the mixer 13, and in the memory block the Record mode, the control signal from The modulator 14 modulated by the SRP signal and distorted by noise enters through the switch 16 into the pseudo-error detector, and from its output into the pseudo-error frequency meter, where the pseudo-error frequency is measured. At the same time, the signal from the output of demodulator 1 through the key enters error rate meter 6, where every bit affected by noise noise is detected, and then the true error factor is determined. The control unit for the meter count signal 6 inserts the true value of the error rate from meter 6 into whose block 8 the memory at the address formed by the address shaper 7 from the readings of the meter 5. The control unit sequentially with a discrete value depending on the required point 4 to carry, controls the attenuator, which adjusts the power of the added noise by means of the memory sensors and writes the true error values to the memory block for different signal / noise ratios. Upon filling the last cell, the control unit transfers the key and switch to the Measurement mode, and the memory block to the Reading mode. A signal arrives at the input of the pseudo-fault detector, which is processed and measured by a pseudo-fault frequency meter. From the obtained values of the pseudo-error frequency, the address driver generates the corresponding addresses of the memory block cells, by which the true value of the error rate is read. The measurement results are displayed on the indicator 18. The technical and economic efficiency of the device for monitoring the digital communication channel is to improve the control accuracy by taking into account the nonlinear dependence of the error rate on the signal-to-noise ratio in the communication channel and taking into account the change in pseudo-error parameters over time. Claim 1. Device for monitoring a digital communication channel, containing an indicator and a pseudo-error detector connected in series and a pseudo-error part meter, a pseudo-error detector as a main detector and an additional demodulator, the outputs of which are connected respectively to the first and second inputs of the adder, the output of which is The output of the pseudo-error detector, whose input is the combined inputs of the main and additional demodulators, characterized in that, in order to improve the accuracy control key, a serially connected key, an error rate meter, a calibrator and a switch and a serially connected address generator and a memory block are entered into it, the output of the main demodulator of the pseudo-error detector is connected to the signal input of the key, the control input of which is connected to the second output of the calibrator, the third output of which is connected to the control input of the switch, the output of which is connected to the input of the pseudo-error detector, the output of the pseudo-error frequency meter is connected to the input of the Atel addresses, and the second relative frequency error output meter is connected to the input of the recording unit memory, control input and output of which are connected respectively with the fourth outlet and inlet of the calibrator indikatora-. 2. The device according to claim 1, wherein the calibrator is made in the form of a serially connected control unit, an attenuator, the second input of which is connected to the output of the noise generator, and the mixer, the second $ which input through the module The torus is connected to the output of the pseudo-random sequence generator, with the first, second, third, and 1003 646 fourth outputs and the calibrator input being the output of the mixer and the second, third and fourth outputs and the input of the control unit. Sources of information taken into account for the examination 1. French Patent No. 2317823, cl. H 04 B 3/46, 1977 (prototype). fhrai if ftttffff