SU507948A1 - Device for controlling the number of errors in discrete information transmission channels - Google Patents

Description

one

The invention relates to telegraph communication, namely to devices for monitoring the number of errors in the channels for transmitting discrete information.

A device for monitoring the number of errors in discrete information transmission channels is known, which contains an input node, parallel connected circuits measuring additive interference and interruptions, while the circuit is out-,. the measurement of additive noise consists of a series-connected amplifier, a linear detector, an amplitude selector, and the break measurement circuit consists of a series-connected amplifier, a linear detector, a low-pass filter, an amplitude selector and an inverter, as well as an automatic gain control node, an OR circuit, display nodes and a generator of quantum pulses connected to the first inputs of the circuits I.

However, the known device lacks control accuracy.

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

For this, the output of the input node is through

the amplifier is connected to the first input of the multiplier, and through a multiplier and low and high frequency filters to the inputs of amplifiers of each aforementioned circuit, the output of the amplitude selector of the circuit for measuring additive interference through the pulse width former, the output circuit of the intermittent measuring circuit , the first cxeNiy And to the input of the first display unit, and the output of the second circuit And is connected to the input of another display unit, while the output of the amplifier measuring the breaks through the node The gain is connected to the second input of the amplifier for measuring additive interference.

In addition, the automatic gain control unit is made in the form of a linear detector, a low-pass filter and a control unit connected in series.

The drawing shows a block diagram of a device for monitoring the number of errors in the channels for transmitting discrete information.

The mixture of signal and interference from the communication channel is fed to the input node 1, which is designed to implement a parallel high-impedance connection to the communication channel. A bandpass filter can be installed in the input node, similar to the receiving filter in the signaling device. To the input node .connected multiplier 2, performed, for example, on a balanced scheme. One input of the multiplier is directly connected to the input node, and the other, through which the reference signal is fed into the multiplier, through amplifier 3. A low-frequency filter 4 and a high-pass filter 5 are connected to the output of the multiplier. The output of the filter 4 is connected to an additive noise measurement circuit, comprising an amplifier 6, a linear detector 7, an amplitude selector 8, and a pulse width driver 9. The output of the filter 5 is connected to a pause measurement circuit, containing an amplifier 10, a linear detector 11, a low frequency filter 12, an amplitude selector 13, and an inverter 14. The outputs of the measurement chains for additive noise and interruptions, viz. the output of inverter 14 jn 9, connected to the OR circuit 15. In addition, the inverter output is connected to one of the inputs of the second circuit AND 16, The output of the OR circuit is connected to the input of the first circuit AND 17. The generator 18 of quantizing pulses is connected to the inputs of the first and second Circuits I. The outputs of the And circuits are connected separately to display units 19 and 20. The output of amplifier 10 is connected to an automatic gain control unit 21 containing a linear detector 22, a low frequency filter 23 and a control unit 24, such as an indirectly heated thermister. The output of the control unit 24 is connected to the control input of the amplifier 6. The device operates as follows. Multiplier 2 operates in a linear system mode with variable parameters. As the reference signal is an amplified mixture of signal and interference, the multiplier dry detects coherent (synchronous) detection In the region of the difference frequency equal to zero, the constant component of the signal is allocated to which additive noise interferences are superimposed. The linear relationship between the signal-to-noise ratio at the input and output of the multiplier makes it possible to determine errors by fluctuations in the amplitude of the interference. The interference voltage allocated to the output of the filter 4 is proportional to the interference power due to the multiplication operation. Oscillations due to signal fluctuations, such as 5,484 spurious amplitude modulation, are superimposed on the DC component of the signal. Since the power of such fluctuations is many less than the power corresponding to an erroneous reception, the error in estimating the number of errors will be insignificant. The amplified interference voltage is detected and fed to the amplitude selector 8. The threshold in the amplitude selector is set equal to the threshold signal-to-noise ratio for Gaussian noise for this type of receiver, with false alarm and missed probability of 0.5. The shaper 9 of the pulse duration when the threshold level is exceeded by a disturbance generates a pulse of duration equal to the average duration of the emission at the level of Gaussian noise. At the output of the interruption measurement circuit, a pulse of the same polarity is formed as in the additive interference circuit. The duration of the pulse is equal to the duration of the break. At the output of the filter 5, the signal-to-noise ratio is higher than that in the channel; in addition, the filter bandwidth is always greater than the channel filter bandwidth. which provides a faster transition during a break. It was established that during a break in the multichannel path, errors are also caused by the effect of transitional interference from neighboring channels, which has an additive character. EE) Tom the pulses from the measurement circuits are combined with the OR 15 circuit, from the output of which the total pulse signal arrives at the I 17 circuit. To the second input of the circuit comes from the generator 18 a pulse waveform of the meander type, the speed of which is similar to the speed of the useful signal, the positiveness of the positive and the negative signal in the sequence is 0.5. Typically, when transmitting decimal signals, this ratio is observed. Therefore, the pulse sequence plays the role of gating pulses and a simulator of the useful signal. In the case of coincidence of the polarities of the pulses from the measuring circuits of interferences and interruptions with the pulses of the meander-type sequence, error signals appear at the outputs of the circuits 16 and 17. Error signals are recorded by display nodes 19 and 20, which may be conventional, for example electromechanical, pulse counters. Display node 19 registers errors from additive noise and interruptions. Display unit 2O records errors only from interruptions. Thus, differentiation of the causes of errors is ensured. When the level fluctuates, the threshold signal / interference ratio must remain unchanged within certain limits. Moreover, the linear dependence of the signal-to-interference ratio increments at the output of the amplifier 6 should be maintained. The fulfillment of these conditions is ensured by the automatic gain control unit. After straightening in the linear detector 22 and averaging in the low-pass filter 23, a DC signal proportional to the mixture of signal and interference enters the control unit 24, for example, an indirectly heated thermometer. The operating circuit of the thermistor is connected to the control circuit of amplifier 6. Thus, the transfer ratio of amplifier 6 varies in proportion and linearly with respect to changes in the signal level in the channel. Moreover, with an increase in the level of gain, amplifier 6 decreases, and with decreasing it increases. The threshold signal-to-noise ratio at the input of the amplitude selector 8 remains unchanged within certain limits.

Claims (2)

1. A device for monitoring the number of faults in discrete information transmission channels, containing an input node, parallel-connected measurement chains for additive interference and interruptions, while the circuit measured by additive interference consists of a series-connected amplifier, a linear detector, an amplitude selector, and a circuit for measuring interruptions out consistently connected amplifier, linear low-pass filter detector, amplitude selector and inverter, as well as an automatic gain control node, an OR circuit, indication nodes and a quantizing pulse generator connected to the first inputs of the AND circuits, characterized in that, to improve the control accuracy, the output the input node is connected via an amplifier to the first input of the multiplier, and through a multiplier and low and high frequency filters to the amplifier inputs of each mentioned circuit, the output of the amplitude selector of the measurement circuit is addit interruptions through the pulse shaper, OR, to the second input of which the output of the intermittent measuring circuit inverter is connected, the first AND circuit to the input of the first display node, and the output of the second AND circuit to the input of another display node, while the output of the amplifier measuring interruptions through the automatic gain control unit is connected to the second input of the amplifier for measuring additive interference. 2. The device according to claim 1, characterized in that the automatic gain control unit is made in the form of a linear detector, a low-frequency filter and a control unit connected in series.