SU1148123A2 - Device for checking amplitude-frequency response of communication channel - Google Patents

Abstract

DEVICE FOR MONITORING THE AMPLITUDE-FREQUENCY CHARACTERISTICS OF THE COMMUNICATION CHANNEL nd auth.St. No. 1046949, characterized in that, in order to increase the accuracy of control due to the correction of the frequency shift between the probe and reference signals, on the receiving side the first output of the input analyzer is connected to the second input of the equalizer through the input correction unit, made as a series-connected unit the control and corrector of the reference signal, the input and output of which are respectively the input and output of the correction.

Description

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Digital Invention The invention relates to communication technology and can be used for remote monitoring of the amplitude-frequency characteristic of communication channels without interruption of communication. According to the main auth. No. 4,46949 a device is known for monitoring the amplitude-frequency characteristic of a communication channel, which is connected in series on the transmitting side. The oscillator of the oscillating frequency control unit, the key, the signal input of KOTopo.ro are combined with the input of the control unit, and the attenuator, a. on the receiving side there is a waiting oscillator of the oscillating frequency and a series-connected correlator and display unit, as well as an input signal analyzer, with the first and second inputs and the first and second outputs of the input signal analyzer connected to the first output of the correlator, respectively; oscillator frequency generator, with the second input of the correlator of the torus. and with the combined input of the standby oscillator oscillating frequency and the second input of the display unit, and the input analyzer is designed as a blocking counter The reset output of which is connected to the reset inputs of the control signal generator, time analyzer and frequency analyzer, the first input of which is the first input of the input analyzer, the second input and the first and second outputs of which are respectively the first input and output of the control block and the first output of the control signal generator, the first input of which is connected to the first input of the time analyzer and the first output of the frequency analyzer, the second input of which is connected to the second input house shaper control signals, second and third outputs which are connected respectively to us second and third inputs of the time analyzer, first and second outputs are connected to second inputs, respectively, of the frequency analyzer and control unit is disabled ki Cl3Odnako known apparatus characterized accuracy control. The purpose of the invention is to improve the accuracy of control due to the correction of the frequency shift between the probe and reference signals. The goal is achieved by the fact that in a device for controlling the amplitude-frequency characteristic of a communication channel containing a series-connected oscillating frequency oscillator on the transmitting side, the control unit is a key whose signal input is combined with the input of the control unit and an attenuator, and on the receiving side waiting generator oscillating frequencies and series-connected correlator and. The display unit, as well as the input signal analyzer, with the first and second inputs and the first and second outputs of the input signal analyzer are connected to the first output of the correlator, respectively, to the output of the standby oscillating frequency generator, to the second input of the correlator, and to the combined input of the waiting idle oscillator frequency and the second input of the display unit, and the input signal analyzer is executed in the form of a control locking unit, the reset output of which is connected to the reset inputs of the control signaling unit, The analyzer and frequency analyzer, the first input of which is the input of the input-signal analyzer, the second input and the first and second outputs of which are respectively the first input and output of the control locking unit and the first control signal generator, the first input of which is connected to the first input the time analyzer and the first output of the frequency analyzer, the second code of which is connected to the second input of the control signal generator, the second and third outputs of which are connected respectively to the second m and the third outputs of the time analyzer, the first and second outputs of which are connected to the second inputs of the frequency analyzer and the control locking unit, respectively, on the receiving side, the first output of the input analyzer is connected to the second input of the correlator through the input correction unit, in the form of serially connected a control unit. and a reference signal equalizer, the input and output of which are, respectively, the input and output of the correction unit. Fig. 1 shows the structural electrical circuit of the proposed device 3; Fig. 2 shows the control unit and the corrector of the reference signal of the correction unit, an embodiment. The device for controlling the amplitude-frequency characteristic of the communication channel contains (figure 1) on the transmitting side, the oscillator 1 of the oscillating frequency, control unit 2, key 3 and attenuator 4, and on the receiving side - indication unit 5, correlator 6, standby generator 7 oscillating frequency, input analyzer 8; a signal consisting of blocking control block 9, frequency analyzer 10, time analyzer 11 and generator 12 control signals, correction block 13 consisting of a corrector 14 of a reference signal and control block 15,and the transmitting side is connected by a communication channel 16. The corrector 14 of the reference signal consists of (FIG. 2) equivalents of the 17 21 transposition section, keys 22-25 and elements. 26 - 29 NOT. The control unit 15 of the correction unit 13 consists of (FIG. 2) switch 30 and diodes 31 - 33. The device operates as follows. In the initial state after turning on the power, the key 3 is open. The auto-oscillator 1 of the oscillating frequency is cyclically tuned in the frequency band of the tested communication channel 16 and its probing signal with the required level is fed to the signal input of the key 3 and the input of the control unit 2. When the current frequency value changes from the minimum to the maximum, the control input is received from the control unit 2 of switch 3 from the control input unit. voltage, under the action of which the key. 3, the extreme signal with the required level and the varying frequency from the output of the auto-oscillator 1 sweeping frequency through the key 3 and the attenuator A starts to flow to the input of the controlled communication channel 16 without interrupting its normal operation. As the current value changes from maximum to minimum, key 3 opens and the voltage of the probing signal is not fed to the input of communication channel 16. Before turning on the power on the receiving side, the operator using the formative 12 control signals. 234 and the control unit 15, depending on the number of relay sections of the tested communication channel 16, sets the operation mode of the corrector 14 of the reference signal. After turning on the power at the receiving side, the input signal analyzer 8 is ready to receive information, and the waiting oscillating frequency generator 7 and the display unit 5 are ready to start. At the input of the communication channel 16, a probing signal arrives at the required level. From the output of the communication channel 16, an addetive mixture of noises from the useful and probing signals is fed to the first inputs of the correlator 6 and the analyzer 8 of the input signal. When the initial frequency component of the probing signal at the output of communication channel 16 appears, the signal at the output of correlator 6 is still equal to O, since the start of the waiting generator 7 has not yet occurred. The input signal analyzer 8 is in operation using block 9, frequency analyzer 10 and time analyzer .11 to determine the presence of a sounding signal in the monitored COMMUNICATION channel 16. The determination of the presence of the probing signal is carried out using the time-frequency method, which consists in the fact that the rate of change of the current value of the frequency of the probing signal, and hence the time intervals between the individual frequency components of the probing signal, is constant and also known a priori. Several monitored frequencies are selected (at least two) and, using knowledge of the time of occurrence of one monitored frequency with respect to another, the presence of a sounding signal in the communication channel is determined, and, using knowledge of the time intervals between the individual components of the sounding signal of a given cycle and the beginning of a new cycle of changing the frequency of the probe of the lean signal of the analyzer 8 of the input signal, predicts the time of the occurrence of the initial frequency of subsequent control cycles without taking into account the presence of Channel 16 is a phase distortion coupling. Therefore, the first cycle of the change, the frequency, of the probing signal is used by the input signal analyzer 8 to predict the appearance of the on-line frequency of the probing signal of the next cycle. After the end of the first cycle of changing the frequency of the probing signal, a new control cycle begins, which is set by the shaper 12 of the analyzer 8. Based on the information obtained during the previous cycle, the analyzer 8 of the input signal starts the block at a certain moment in time: 5 indication and the waiting generator 7 oscillating frequency by means of a pulse, which appears at the first output of the analyzer 8 input signal The reference voltage from the output of the waiting oscillator 7 of the oscillating frequency starts to flow through the second th input and the input to the input correction unit 13 the signal output analyzer 8 In block 13, the correction reference signal corrector 14 ensures slowdown of individual frequency components of the signal-stand ™ supports the same, which makes the communication passage 16 comprised between the frequency of the probing signal. As a result, the reference signal from the initial. the value of the current frequency appears. at that moment, at the second input of the correlator of the torus 6, when the first input of the correlator of the torus 6 receives a sounding signal with the same frequency value. When the oscillator 1 oscillating oscillator and the waiting oscillator 7 oscillating frequency are synchronized, the reference signal from the latter’s output through the analyzer 8 of the input signal and the block 13, the correction is fed to the second input of the correlator 6, in which the optimal processing of the transmitted through channel 16 of the probing signal takes place against the background of the noise and useful signal of the communication channel 16, which for the correlator 6 is a hindrance. The convolution of the spectrum of the probing signal in the correlator 6 occurs in a frequency band that is significantly smaller than the frequency band of the tested communication channel 16. If the modulation characteristics of the auto-oscillator 1 of the frequency frequency and the standby generator 1 of the oscillating frequency are identical and the correction made by the correction-signal correction unit 13 corresponds to the frequency distortions in the channel 16 of the communication, then the band of the corrector 6 can be one unit or ten hertz, which allows one to select a minimized probe signal from the channel noise of 16 svn. 36 Interference; b) when near; at its location, the useful signals of the 1b communication cable are provided by selecting the base B of the probing signal (B LRT, where the frequency band of the communication channel is 16, and T is the tuning time in the uF band) - which, due to the large tuning time, is chosen much more than 1. Therefore, the probing element with base B 1 and useful signals of communication channel 16, having B z. 1, are mutually compatible. Interference level from useful signals of the controlled communication channel 16 determined by the conversion factor Ex K l / Bj which, for example, at B 1000. will be just K 0.001. The output signal from the output of the correlator 6, the proportional amplitude-frequency characteristic of the communication channel 16 goes to the display unit 5. Simultaneously with the processing of information on the state This analysis of the amplitude-frequency characteristic continues the analysis of the signals coming from the communication channel 16 by the input signal aparaper 8. If, for some reason, the probe signal disappears at the output of the communication channel 16, then the input analyzer 8; by absent a certain controlled frequency at a certain moment of time, it interrupts the monitoring process. As a result, at the second output of the input signal analyzer 8, the reference voltage becomes equal to Oj processing, in the correlator 6 it stops and the information ceases to flow to the input of the display unit 5. Before starting the control, the operator sets the switch 30 (FIG. 2) of the control unit 15 to a position corresponding to the number of receivers of the monitored communication channel 16. After turning on the power through the locking switch 30 level log. 1 is applied to the input of the corresponding element 26 29 NOT of the equalizer 14, which is connected to this input of the switch 30. And through the diodes 31 - 33 to the other NO elements with a smaller number, for example, let the controlled communication channel 16 consist of three receivers plots, spda switch 30 is necessary to post; 1 -1g-t in position 3. In this c.chugae level

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added to item 27 is NOT

log

directly, but through diode 31 to element 26 is NOT. As a result, the keys 22 and 23 go to the open state, while the remaining keys 24 and 25 are still in the closed state. Thus, to pass the reference signal, the next chain is formed; equivalent to 17-19 of the receiving area and then through closed keys 24 and 25, which bypass the remaining equivalents of .20 and 21 of the received area, i.e. the path of the probing signal is equivalent to the passage of the probing signal through channel 16 of communication with three bursts in reception. The KCPTojp 14 of the reference signal, the input for one or another frequency component of the reference signal, has the same phase-frequency distortions that communication channel 16 introduces; the frequency components of the sounding signal provide a synchronous change of frequencies on the first and

eight .

the second inputs of the correlator 6, thereby narrowing its bandwidth and reducing the random component of the control error by reducing the frequency shift between the probe and reference signals.

The introduction of the correction unit 13 prevents the above frequency shift, narrows the bandwidth of the correlator 6 and improves the control accuracy. As an equivalent to the receive area, you can use the serial connection of two channel filters of this type of channel whose amplitude-frequency characteristic is to be monitored.

Thus, the introduction of a correction unit avoids the frequency shift between the reference and the probing signal and ensures an increase in the control accuracy by reducing the random component of the control error.

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Claims (1)

DEVICE FOR CONTROL OF AMPLITUDE-FREQUENCY CHARACTERISTICS OF THE COMMUNICATION CHANNEL according to ed. No. 1046949, '' characterized in that, in order to improve the accuracy of control due to the correction of the frequency shift between the probing and reference signals, on the receiving side, the first output of the input signal analyzer is connected to the second input of the corrector through the inputted correction block, made in the form of series-connected blocks control and corrector reference signal, the input and output of which are respectively the input and output of the correction unit. (rig. 1 f 1148123