SU1753602A1 - System for testing of transmission lines - Google Patents

Abstract

This invention relates to a multichannel communication technique. The purpose of the invention is to increase efficiency by using a single terminal set to control several transmission lines and to increase the accuracy of the control. The control system of transmission lines contains control signal generator 7, counters 4i-4n, band-pass filters 2i-2n, detectors, analyzer 5, multiplexer 8 and terminal 6, and, at each unattended point 9i-9n, fault sensors, a generator 11 notification signals, control unit 12 and linear signal generator 13. At the same time, the communication module 17, the analog signal demultiplexer 18, the starting drivers 19i-19n and the coupling blocks, the number of circuits from the series-connected band-pass filter, detector and counter, are equal to the maximum number in the monitored transmission lines. The control signals arriving along the linear paths 14i-14m are processed in parallel by a single terminal set to achieve the goal. 1 il.

Description

The invention relates to radio engineering and can be used to control transmission lines with both p frequency and time division channels.

The purpose of the invention is to increase the control efficiency by using one window complex to control several transmission lines and to increase the control accuracy,

The drawing shows a structural electronic circuit of the proposed system.

The control system of transmission lines contains at the served point 1 p bandpass filters, n detectors, n counters 4- | 4p, analyzer 5, terminal 6, control signal generator 7, multiplexer 8 analog signals, communication module 17, demultiplexer 18 analog signals , start drivers 19i-19i, interface blocks, and at each unattended point 91-9p-fault sensors, generator 11 of notification signals, block 12 of control, generator 13 of linear signals, in addition, remote control channels 151-15N, channels 1b1- 16s telesignalization and linear paths 14i-14m.

The system works as follows

The terminal equipment located at service point 1 monitors transmission lines, each of which contains unattended points (LLP) 9i-9r, through which m linear paths 14i-14m pass. The transmission lines are connected to a served point (GCC) 1 via remote control channels 151-15N and N channels 16- | -16y of the remote signaling system. Each of the generators 13 is tuned to a specific frequency corresponding to this LLP 9i-9n. The notification signals transmitted from the generators 13 to the remote signaling channel 16 are fed to the water of the multiplexer 8 analog signals. The switching is performed alternately under the control of commands continuously arriving at the second input of the multiplexer 8 from the output of the analyzer 5. Thus, the sequential analysis of the monitored transmission lines is carried out in accordance with the program embedded in the analyzer 5.

In the period reserved for monitoring one transmission line, the signals from the output of multiplexer 8 are fed to the inputs of bandpass filters 2i-2n. Each notification signal has a corresponding circuit from series-connected band-pass filter 2, detector 3 and counter 4.

In the event of a malfunction, one of the sensors 10i-10k of the malfunction is triggered on any NUP 9i-9n. Each of the sensors 10i-10k fault corresponds to a certain nature of the fault. Under the influence of the fault sensor, the nature of the signal of the notice at the generator output 13 changes in a certain way.

So, depending on the nature of the fault, the sinusoidal signal of the generator 14 is modulated by pulses

0 specific duration. In this case, an amplitude-modulated signal is fed to the input of the detector 3. At the output of the detector 3, which highlights the envelope, instead of a constant signal, a sequence of pulses arises at the input of counter 4. It counts the number of incoming pulses and outputs the corresponding code combination at its outputs. Account authorization is carried out

0 under the action of clock pulses from the first output of the generator 7, the Analyzer 5 records data and outputs them to terminal 6, simultaneously generating a signal to reset the counter 4, rotating them to the initial state.

When processing data from counter 4, analyzer 5 compares with the results of the analysis of the previous survey cycle and outputs only those results to terminal 6

0 characterize the change of information, i.e. transition from emergency to normal and vice versa.

The interface blocks interact with the analyzers 5 via a parallel interface including the communication module 17 at the physical level. The alarm is triggered via the interface 20 to the driver 19. From the output of the former 19, a signal is sent to the input of the analyzer 5, which calls up another control subroutine.

Analyzer 5 begins to call addresses of mate blocks 20. The analyzer 5 interacts with the blocks 20 via the communication module 17. When the request signal at the analyzer 5 input signal disappears, the address of the demultiplexer 18 arrives from its corresponding output, which performs switching

0 one input on N outputs, i.e. performs the functions inverse to the functions of the multiplexer 8. In this case, the generator 7 is connected to the transmission line, the composition of which is the damaged node. Analyzer

5 5 from the exit gives razrepeni; generator 7 to transmit control signals to the line. From the other output of the generator 7, through the demultiplexer 18, the channel 15 for the remote control of the corresponding transmission line alternately receives control signals that differ in frequency. To each controlled LPS there corresponds a control signal of a certain frequency to which the control unit 12 is tuned. When the control signal arrives at the first LLW 9i, the signal from the output of the control unit 19 starts the generator 13 connected by its outputs to the linear paths 14i-14m. The generators 13 on all the controlled LLPs are tuned to the same frequency. If the equipment is operational at the first LLO 9i, then the linear signal through the corresponding linear path enters all information inputs of the interface unit 20i. If one of the linear paths 14i-14m is damaged, a linear signal will not be sent to one of the information inputs of the interface block 20i. The address of the input block 2Ch-20i interface from the analyzer 5 through the communication module 17 are received alternately addresses of linear paths. All linear paths 14i-14m are sequentially polled to determine the magnitude of the understatement of the pilot signal from the nominal value. Analyzer 5 provides data recording and again starts polling and analyzing linear paths 14i-14m according to the presence of linear signals from LLP 9i-9m. After interrogation of all LLLs 9t-9n, the control signal from the analyzer output is canceled and data is sent to terminal 6.

Claims (1)

Claims of Invention A transmission line monitoring system containing sequentially connected bandpass filter, detector, counter, analyzer and terminal, control signal generator, the first output of which is connected to the second counter input, an analogue signal multiplexer, the first input of which is connected to the second. the analyzer output, the third output of which is connected to the input of the generator of control signals, and the fourth output - to the third input of the counter, and sensors at each unattended point faults connected to a notification signal generator, a serially connected control unit and a linear signal generator, whose outputs are connected to linear paths, the input of the control unit is connected to a remote control channel, characterized in that, in order to increase the monitoring efficiency by using one terminal set for control of several transmission lines and increase of control accuracy, are introduced at the serviced point of the chain of series-connected band-pass filter, detector and counters ka, second and third the inputs and output of which are connected respectively to the first output of the generator of control signals, the fourth output and the corresponding inputs of the analyzer, a communication module, an analog demultiplexer signals, trigger drivers and interface units, whose information inputs are connected to the outputs of the linear paths, and the address inputs to the first output of the communication module, the first input of which is connected to the first outputs of the interface modules, and the second input and output of the communication module, respectively with the fifth output and the second input of the analyzer, the second and third outputs of the interface blocks are connected respectively to the first and second inputs of the starting drivers, the first outputs of which are interconnected, and the second outputs are connected to tert The second input of the analyzer, the sixth output of which is connected to the first input of the demultiplexer of analog signals, the second input of which is connected to the second output of the generator of control signals, its outputs are connected to remote control channels, channels corresponding signal lines are connected to the second multiplexer inputs of analog signals, the output of which is connected to the inputs of all band-pass filters, and on each the unattended point the outputs of the generators of the notification signals are connected to the corresponding remote signaling channels.