SU1309069A1 - Device for reception and transmission of digital information - Google Patents

Abstract

The invention relates to digital communication systems and can be used in multichannel information transmission systems. The aim of the invention is to increase the reliability of control through the implementation of end-to-end monitoring of the entire path and automatic localization of the place of occurrence of a malfunction. The device contains transmitting channels I, each of which Contains transmitters, 2, 7 and encoder 3, synchronous generators 4, 6, 11, 12, 15, compaction block 5, simulator 8 signals, switches 9, 13, receiver 10, block 14 of channel separation , receiving channels 16 containing a decoder 17, a switch 18 and a receiver 19. The device also contains a fault localization unit 20, a display unit 21. The device additionally provides the possibility of automatic localization of faults according to the results of end-to-end control of channels. Thereby, the reliability and completeness of the control is achieved, since control covers almost all blocks of the device from input to output; in addition, almost all faults in the system are detected and a check for the stability of the failure over time is provided. 1 hp f-ly, 2 ill. 2 tab. i CO I-: r iiir r 3ii- - with о о со о OD CO

Description

The invention relates to digital communication systems and can be used in multichannel information transmission systems.

The purpose of the invention is to increase the reliability of control and expand functionality by determining the location of the fault.

FIG. 1 shows a functional diagram of the device; in fig. 2 - functional block diagram of the localization of the fault.

The device (Fig. 1) contains the transmitting channels 1, each of which contains the second transmitter 2 and the encoder 3, the first synchronizing generator 4, the compaction unit 5, the third synchronizing generator 6, the first transmitter 7, the signal simulator 8, the second switch 9, the first receiver 10, sync selector 11, second synchro generator 12, first switch 13, channel separation unit 14, fourth clock generator 15, receiving channels 16 containing decoder 17, third switch 18 and second receiver 19, fault location unit 20 and display unit 21.

Block 20 localization of faults (Fig. 2) contains the first element And 22, the third element And 23, shaper 24 pulses, the second element And 25, the clock 26, the register 27, the first 28, the second 29 and the third 30 counters, the third 31, the first 32 , the fourth 33 and the second 34 triggers, the second 35 and the first 36 decoders, the delay element 37, the third 38, the fourth 39, the second 40 and the first 41 elements OR, the fourth 42, the second 43, the first 44, the third 45 and the fifth 46 elements , fourth element and 47.

The device works as follows.

In the transmission path, to the inputs of N transmitters 2 of the tolerance control signal, analog communication signals (telephone, sound broadcasting, television, etc.) are input through the input slots. In the respective communication signal encoders 3, analog-to-digital conversion and digital coding of the information signal is carried out together with the tolerance control signal. Each of the N encoders 3 communication signals from the first clock generator 4 receives a control signal with a clock frequency equal to the desired time sampling frequency of the corresponding communication signal. From the first outputs of N encoders 3 communication signals, digital communication signals (for example, in the form of a parallel digital code — for television — an eight-bit parallel code) are sent to the first N inputs of block 5, to the second N inputs of which from N encoders 3 communication signals The corresponding control signals are received at a clock rate of incoming digital communications signals to its first N inputs. In block 5, the compilation of a group digital stream (GPC) is carried out by

Sealing digital signals at its input. In the same block, for example, the generation and input of frame synchronization signals and the conversion of a signal from a parallel code to a serial one are carried out in a GPO. The clock signal of the serial code, which arrives at the third input of the compaction unit 5, is formed in the third synchronous generator 6 from the clock frequency signal, which arrives at one of the first inputs of the compaction unit 5. From the first output of the compaction unit 5, the HCP signal is fed to the first input of the transmitter 7, the second input of which receives the clock signal of the serial code from the second output of the compaction unit 5. Transmitter 7, for example, scrambles the GCP, protects the GPC from errors, and matches the characteristics of the digital signal with the communication channel (channel coding).

The linear signal formed in transmitter 7 is fed to the first output on the communication line. At the far end of the link, a similar device is included.

In the reception path, a linear signal received from a similar device from the second input of the communication line is fed through a com.mutator 9 to an input of receiver 10, into which, for example, linear signal decoding, error detection or correction, and descrambling of the centralized signal are performed. . WITH

The output of the receiver 10 of the GPC is fed through the switch 13 to the first input of the channel separation unit 14. In addition, the SCP is fed through a sync selector 11 to the input of the second synchronous generator 12, where a signal of such a frequency of the serial

code, synchronous and in-phase with the received PSC. This signal is fed through the switch 13 to the second input of the channel separation unit 14 and through the fourth synchronizing generator 15 to the third input of the channel separation unit 14. In the fourth clock generator 15, N control signals are generated with a clock frequency of digital signals taken from the output of the channel separation unit 14. From the first N outputs of block separation section 14, the digital communication signals TY are received through N switches 18 to the first inputs of the corresponding N decoders 17 communication signals, to the second inputs of which through N switches 18 from the second outputs of block 14, control signals are received with a clock frequency of corresponding digital signals. communication signals. In the N decoders 17, digital decoding and digital-to-analog conversion of the information signal are carried out together with the tolerance control signal. Information signals of communication through N receivers 19 of the tolerance control signal arrive at the output regions, and from the second output N receivers 19 of the tolerance control signal N digital signals characterizing the performance of the corresponding communication channels (logical "1 - unacceptable degradation of the received communication signal; logical "O is a normal signal), are fed to the corresponding N inputs of the malfunction localization unit 20, the first three outputs of the malfunction localizing unit 20 in a certain order form digital These switching signals (logical "1) of switches 9, 13, and 18 establish the appropriate loops. The first input of the switch 9, which enters the reception path, through the simulator 8 is fed a linear signal from the output of the transmitter 7. The loop N 1 installed by the switch 9 when a logical "1" arrives at its second input from the block 20 transmitter 7 output (i.e. from the output of the transmission path) through simulator 8 to receiver input 10. Simulator 8 can be, for example, a passive circuit with attenuation and amplitude-frequency characteristic similar to the corresponding characteristics of the cable regeneration chastka (e.g., data transmission rate in the line 140 Mbit / s imitation cable segment length EP 4 3 km).

The first and second inputs of the switch 13 from the first and second outputs of the compaction unit 5 receive the GPC and the control signal with a clock frequency of the serial code, respectively. Loop N 2, set by switch 13, when logical 1 1 arrives at its fifth input from block 29, supplies the GPC and control signals from the first and second outputs of the compacting unit 5 to the first and second inputs of the channel separation unit 14.

The fourth and fifth inputs N of the commutators 18 from the first and second outputs N of the encoders 3 of the communication signals, respectively, receive digital communication signals and control signals with a clock frequency of the digital communication signals. The first to Nth loops, installed by the N switches 18, when logical "I" arrives at their fifth inputs from block 20, provide the corresponding digital communication signals and control signals from the first and second outputs N of the coders 3 to the communication signal the first and second inputs of the decoders 17 of the communication signals.

Fault localization unit 20 by installing in a certain order of loops provides localization of faults in one of the (2N + 5) functional blocks of the transmission or reception path, as well as in the communication line. This takes into account the direction of transmission in which an unacceptable reduction in transmission quality is detected.

The localization of the fault begins (When a logical "1 for the third

device input from a distant digital transmission and reception device (failure in the direction of transmission of information from this digital transmission and reception device to the distant one), receiving logical "1 from the second output of at least one receiver 19 (failure in the direction of reception of information by this digital transmission and reception device from the far).

In this case, at the third output of the fault localization unit 20, a logical < 1 > is formed, which is fed to the third output of the device for transmission to a remote similar device.

The first output and the second input serve for transmitting and receiving the linear information signal of the GCP and can be arranged, for example, along coaxial tubes of the KMG-4 cable. The third output and the third input of the device are used to transmit and receive fault localization signals (between this and the remote devices) and can be organized, for example, along symmetrical pairs of KMG-4 cable. The localization of faults begins with the installation of a loop N 1, which does not open until the defective unit is found and replaced. The signal from the third output of the unit 20, which sets the loop N 1 using the switch 9, is also fed to the input of the display unit 21, providing an indication of the device's transition to the fault localization mode. When the loop N 1 is opened, the indication stops. If after installing the loop N 1 at the second output of one or more receivers 19 of the tolerance control a logical "1 occurs (indicating an unacceptable reduction in the quality of transmission), a loop of N 2 is established. If at the second output of all receivers 19 of the tolerance control a logical" O The fault localization unit 20 decrypts the faulty blocks: either the transmitter 7 or the receiver 10 with the sync selector 11 and the second synchronizing generator 12. Next, the N 2 loop is disconnected (the N 1 loop remains installed) and at the second outputs Cove recovered ie.mni- 19 signals that there is observed at the loop N 1. According to one output unit 20 on the display unit 21 is supplied to a logic "1 to indicate out-of. Straw block (s) or line. The display pref {) appears after the replacement of the failed block (s).

If, after installation of the N 2 loop, the logic levels on the second outputs of one or more receivers 19 have not changed, the N 2 loop is opened and the loops from the first to the Nth are established. If a logical "O" occurs at the second output of all receivers 19, in the fault localization unit 20, the defective blocks are deciphered; either the compaction unit 5 with the third synchronizing generator 6, or the separation unit 14 of the channels with the fourth synchronizing generator 15. Next, the previously installed loops from the first to the Nth are disconnected (loop N 1 remains installed) and at the second outputs of the receivers 19 the signals that were observed there the installation of loop N 1. In one of the outputs of block 20, block 21 is supplied with a logical < 1 > to indicate the aforementioned logged out block (s). The indication stops after replacing the failed block (s).

If, after installing loops with numbers from the first to the N-ro, the logic levels on the second outputs of one or several receivers did not change, in the fault localization unit 20, the defective blocks of the corresponding channels are deciphered:

These inputs, at the output of the first element OR 38, a logical < 1 > is formed, which, through element 22, allows the pulse counter 29 to operate, which is necessary to check the stability of the received failure time. If during the S-clock of the control signal received from the synchronization generator 26, the logical "1 is saved at the second input of the counter 29, the logical" 1 which passes through the element OR 40 to the input D- trigger 31, while at its output a logical "1. The appearance of the logical “1 at the output of the D-flip-flop 31 means that a steady failure was detected according to the results of the end-to-end control in the receiving part of the proposed device and it is necessary to proceed to localize the faults. This signal through the third output goes to a device located on the far

either the coders of 3 communication signals from the transmitter to the 20 end of the line, more specifically to those of the 2 tolerance control, or the sync block 20 for fault localization. The analog generator 4, or the decoders 17 of the communication signals with the receivers 19 of the tolerance control. The clock 4 is considered faulty if the degradation of the transfer

a logical signal in the event of the end-to-end control device tripping at the far end of the line arrives at the second input of block 20, at the input of the element OR 40, and the fault is detected in all N channels. Further, 25 localization of faults in this

thirty

device. The same signal (logical "1) goes through the element NOT 46 and the third element I 22 to the input of the counter 29, setting it to the initial state and forbidding it, but its operation. Thus, if the malfunction is registered not on this, but on the far device, on this device the loop N 1 is disconnected and repeated localization of the malfunctions is blocked until the fault on the causative indicator is cleared by the information device.

The accident about the line on which Block 20 does not accept this device information during the localization process. health functions as follows.

When a logical "1" occurs at the output of the D-flip-flop 31, the signal from the output of the OR 38 element is recorded in the D-flip-flop 33. If the logical "1 is written to the D-flip-flop 33, a fault has occurred in the information receiving path from the remote device to this one. This path includes the direction of transmission and reception, respectively, of the far and given devices, as well as

Admission control control is a well-known 5 line of communication. If, in the D-flip-flop 33, the automatic tolerance locking is controlled by the logical "O, fault is air, for audio broadcast signals, there is a nickel in the information transmission path from the data transmitter of the tolerance control unit to the remote one. This path of the CDC I and the receiver of the tolerance signals includes the directions of transmission and reception of the control of the CDC-2.

all loops except the first one open, as in the previous case. The indication and termination of the indication by the block 21 of the failed block (s) are carried out as in the previous case. If a fault in this and a distant device is not detected, the fault localization unit 20 at its fourth outputs generates a logical < 1 > which is fed to the display unit 21. The implementation of the transmitters 2 and the receivers 19 of the tolerance control signals may be different depending on the type of the transmitted communication signal. For example, for a television signal, a known device for generating and inserting signals of test lines can be used as a transmitter of 2 tolerance control signals, and a signal 40 as a receiver 19

Block 20 fault localization works as follows.

To the N inputs of the OR element 38 of the fault localization unit from the second outputs of the corresponding N receivers 19 are corresponding to the given and distant devices, as well as the communication line. The information recorded in the D-flip-flop 33 is used to decrypt (in accordance with Table 1) the failed block in the decoder 35. Logical "1 from the output of the D-flip-flop 31 posunals of the tolerance control is fed to N digit-55 fed to the input of the switch 9 and installed signals that characterize the N 1 loop, as well as allow the appropriate communication channels. The data written in the D-flip-flop 32 and the register

When entering the logical "1 to one of 27. In addition, this signal through the element

These inputs, at the output of the first element OR 38, a logical < 1 > is formed, which, through element 22, allows the pulse counter 29 to operate, which is necessary to check the stability of the received failure time. If during the S-clock of the control signal received from the synchronization generator 26, the logical "1 is saved at the second input of the counter 29, the logical" 1 which passes through the element OR 40 to the input D- trigger 31, while at its output a logical "1. The appearance of the logical “1 at the output of the D-flip-flop 31 means that a steady failure was detected according to the results of the end-to-end control in the receiving part of the proposed device and it is necessary to proceed to localize the faults. This signal through the third output goes to a device located on the far

0 end of the line, more specifically on the same block 20 fault location. Ana-

the end of the line, more specifically on a similar block 20 fault localization. Ana-

a logical signal in the event of the end-to-end monitoring device triggers at the far end of the line arrives at the second input of block 20, at the input of the element OR 40, to clear the connection. If the D-flip-flop 33 records the logical "O", a fault has occurred in the transmission path of information from this device to the remote one. This path includes transmission and reception directions.

respectively, this and the far devices, as well as the communication line. The information recorded in the D-flip-flop 33 is used to decrypt (in accordance with Table 1) the failed block in the decoder 35. Logical "1 from the output of the D-flip-flop 31 is fed to the input of the switch 9 and the set 25 is fed to the input of the pulse counter 28, allowing it to work, and through the element NOT 43 and the element I 22 is fed to the input of the counter 29 pulses. If there is a logical " O on the input of the pulse counter 29, it is reset to the initial state and its further operation is prohibited. Through periods of a control signal from the synchro generator 26 to the input of the pulse counter 28, a logical ' 1 input to the first input of the decoder 36 is generated at its first output (the th digit of the counter). At the second output of the second decoder 36 (operating in accordance with Table 2) forms the logical "1. When a logical "1" occurs at the second output of the decryptor 36, D-flip-flop 32 records the signal arriving at its input from the output of the OR 38 element through the NOT 45 element. If logical "1 is recorded in the D-flip-flop 32, a fault has occurred on the far device. D-flip-flop 32 records the result of end-to-end monitoring of channels when setting loop N 1, i.e. The result is the control of this device only. Logical 1 from the output of the D-flip-flop 32 through the OR element 41 enters the input of the b-flip-flop 31, a logical "O" arises at its output, which through the AND 25 element enters the input of the pulse counter 28, returning it to its initial state. Thereby, block 20 returns to its original state. If a logical "O" is written to the D-flip-flop 32, a malfunction has occurred on this device, therefore it is necessary to continue troubleshooting. Logical ' 1 from the output of the decipheror 36 is fed to the input of the switch 13, thereby setting loop N 2. This loop remains closed for periods of the control signal received from the clock 26 to the input of the pulse counter 28. During this time, end-to-end monitoring of the N channels is carried out, the results of which from the corresponding outputs of the receiver 19 are fed to the inputs of the fault localization unit 20. At the end of the monitoring interval, a logical "O" is formed at the first output of the pulse counter 28 of the pulses N 2, and logical "1" is generated at the second output of this counter (the output of (k- | -1) th digit). In this case, at the second output of the decoder 36, a logical " O is formed; at the first, a logical " 1. If during the formation of the logical "1" at the first output of the decryptor 36, the first N inputs of the decoder 35 receive digital signals with a logic level of "O, logical one" is formed at one of the (2N- | - - | -5) outputs of the decoder 35. Digital signals (2 N + 1)

ten

20

imputa on its output when a switch occurs at the output of the decimator 36 and when the logical "O from the output of the element OR 39 arrives at its first input. The (2 N + 5) bit bit is a parallel code combination from the output of register 27, containing logical "1 in one of the bits and logical" O in the other bits and is fed to the input of block 21, where the faulty block is indicated. In this case, a fault is indicated either to the receiver 10 (if there is a logical "1 at the output of the D-flip-flop 33), or at the transmitter 7 (if there is a logical" About at the output of the D-flip-flop 33). Logic "1 from one of the outputs of the register 27 through the element OR 39 is fed to the input of the imaging unit 24 pulses, prohibiting its operation, to the input of the AND 47 element, as well as through the NOT 42 element and the And 48 element - to the input of the pulse counter 28, setting it back to its original state and banning its operation. Thus, only the slot N 1 remains closed.

If during the formation of the logical "1 at the output of the decoder 36, at least one of the N first inputs of the decoder 35 is 25, a digital signal with a level of" I goes to the register 27 at the moment of the appearance of a short pulse at the output of the driver of the pulse 24 is written zero (2 S + 5) -ti bit code combination. This means that troubleshooting should continue. Through periods of a control signal from the synchro generator 26 to the input of the pulse counter 28, a logical ' I signal is generated at its first output, arriving at the input of the decipheror 36. At the first output of the decoder 36, a logical ' O signal is generated. At the same time, logical "1 are formed at one or several outputs of the deciphering device 35, which are written to the register 27 at the moment of the appearance of a short pulse at the upstream side of the driver 24. The pulse shaper 24 generates a short pulse at its output when a switching signal occurs. "0 at the first output of the decrypter 36 and when a logical" O from the output of the element OR 39 arrives at its input. With a logical < 1 > one or more outputs of register 27, an indication of a faulty block (s) is made. If at the moment of forming the logical "O at the first output of the decimator 36, the first N inputs of the resolver 35 receive digital signals with a logic level" 0 indicating failure of the compaction unit 5 with the third sync generator 6 (with a logical "O at the output of the D-flip-flop 33), or

35

40

45

50

the outputs of the descrambler 35 are recorded in b55 "C block 14 of the division with the fourth sync register 27 at the time of the appearance of the short generator 15 (with a logical" 1 per

pulse at the output of the driver 24 named output D-flip-flop 33). If at the moment of for. Pulses. The latter forms a short-term logical "About at the output

0

imputa on its output when a switch occurs at the output of the decimator 36 and when the logical "O from the output of the element OR 39 arrives at its first input. The (2 N + 5) bit bit is a parallel code combination from the output of register 27, containing logical "1 in one of the bits and logical" O in the other bits and is fed to the input of block 21, where the faulty block is indicated. In this case, a fault is indicated either to the receiver 10 (if there is a logical "1 at the output of the D-flip-flop 33), or at the transmitter 7 (if there is a logical" About at the output of the D-flip-flop 33). Logic "1 from one of the outputs of the register 27 through the element OR 39 is fed to the input of the imaging unit 24 pulses, prohibiting its operation, to the input of the AND 47 element, as well as through the NOT 42 element and the And 48 element - to the input of the pulse counter 28, setting it back to its original state and banning its operation. Thus, only the slot N 1 remains closed.

If during the formation of the logical "1 at the output of the decoder 36, at least one of the N first inputs of the decoder 35-5 will receive a digital signal with a logic level" I, in register 27 at the moment of the appearance of a short pulse at the output of the driver, 24 pulses are written zero (2 S + 5) -ti bit code combination. This means that troubleshooting should continue. Through periods of a control signal from the synchro generator 26 to the input of the pulse counter 28, a logical ' I signal is generated at its first output, arriving at the input of the decipheror 36. At the first output of the decoder 36, a logical ' O signal is generated. At the same time, logical "1 are formed at one or several outputs of the deciphering device 35, which are written to the register 27 at the moment of the appearance of a short pulse at the upstream side of the driver 24. The pulse shaper 24 generates a short pulse at its output when a switching signal occurs. "0 at the first output of the decrypter 36 and when a logical" O from the output of the element OR 39 arrives at its input. With a logical < 1 > one or more outputs of register 27, an indication of a faulty block (s) is made. If at the moment of forming the logical "O at the first output of the decimator 36, the first N inputs of the resolver 35 receive digital signals with a logic level" 0 indicating failure of the compaction unit 5 with the third sync generator 6 (with a logical "O at the output of the D-flip-flop 33), or

five

five

0

On the first N-inputs of the decoder 35, one or more digital signals are received with a logic level of "1"; one or more encoders indicate a 3 communication signals (with a logical "O at the output of the D-flip-flop 33), or one or more decoders 17 communication signals (with a logical "I at the output of the D flip-flop 33). If at the time of formation of the logical "O at the output of the decoder 36 on

tormented time enough to trigger the receivers 19 and enter the device’s operating mode after opening the loop N 1. In addition, it is necessary to take into account the temporal mismatch of the operation of blocks 20 in devices at this and the far end, due to the asynchronous synchronizers 26 and the final digital signal transmission time between the blocks 20. With the output of the D-flip-flop 34 logic

all inputs of the decoder 35 are logged; 10 is fed to the display unit 21 and through the electrical "1 and the output of the D-flip-flop 33 is logical" O, the failure of the first clock generator 4 is indicated (the first clock generator 4 ensures the operability of all communication signals 3) . Logic "1 from one of the outputs of the register 27 through the element OR 39 enters the input of the driver of 24 pulses, prohibits its operation, to the input of the element AND 47, as well as through the element NOT 42 and the element And 25 - to the input of the pulse counter 28, sets it to baseline and prohibit its operation. Thus, only loop N 1 remains closed. This loop is closed until the fault has been eliminated.

After elimination of the malfunction at the output of the element OR 38, the logical “O” is formed, which through the element 45 and the element 47 comes to the input of the counter of 30 pulses, allowing its operation. Through M periods of the control signal from the synchro generator 26 to the input of the pulse counter 30, a logical "L" is formed at its output, which through the OR 41 element sets the D flip-flop 31 to the logical "O" state. In this case, the loop N 1 is opened, the outputs of the register 27 are set to the logical state "O, the indication stops and the fault localization unit 20 returns to the initial state. If, when the receivers 19 of the fault localization unit 20 are triggered in this and the far devices, the fault is not detected, the element 23, the D-flip-flop 34 and the delay element 37 will decide on the line failure. In the absence of a malfunction, a logical "1 is formed at the output of the element I 50 and recorded in D-flip-flop 34 when there is a logical" 1, at its input (from the element OR 38) and when passing the signal from the output of the decoder 36 through the delay entry element 37 of the D-flip-flop 25. The delay element 37 provides a delay in the switching time of the signal arriving at its input from the output of the decoder 36.

The need for delay due to the following. Recording information in the D-flip-flop 34 must be done through a certain inment NOT 44, the element 22 and 22 to the input of the counter 29 pulses, prevent its operation. When the link is restored to serviceability, a logical "O" is generated at the output of the OR 38 element, which is fed to the input of the D-flip-flop 34, setting it to the logical "O" state. Thus, the indication of the link failure is stopped and the pulse counter 29 is prepared for operation. Thus, block 20

The 2Q fault location returns to its original state.

The technical and economic effect of the use of the proposed device as compared with the known one is associated with enhanced functionality and increased reliability of monitoring the device for digital transmission and reception of communication signals, since it is additionally possible to automatically locate faults based on the results of end-to-end monitoring of channels. Thus, in comparison with the known device, greater reliability and completeness of control is achieved, since the control covers almost all units of the device from input to output, in addition, almost all system failures are detected and a check for the stability of failure is provided, greater accuracy of fault localization, since In a known device, a failure in the path is detected, only starting from the entrance of the compacting unit (TV entry points

40 digital signal test; line parameters are monitored separately (channel parameter control unit), and fault localization is not provided.

thirty

35

45

Claims (2)

1. A device for receiving and transmitting digital information, containing an encoder in each transmitting channel, the first encoder outputs of each transmitting channel are connected to the corresponding first inputs of the compression unit, the first output of which is connected to the first input of the first transmitter, the output of which is the first output of the device , the first synchronous generator, the outputs of which are connected to the nerve inputs of the respective coders of each transmitting channel, the first receiver, the output of which through the synchronous selector is connected to the input of the second on the clock. tormented time enough to trigger the receivers 19 and enter the device’s operating mode after opening the loop N 1. In addition, it is necessary to take into account the temporal mismatch of the operation of blocks 20 in devices at this and the far end, due to the asynchronous synchronizers 26 and the final digital signal transmission time between the blocks 20. With the output of the D-flip-flop 34 logic  enters the display unit 21 and through the element 44, the element 22 and 22 to the input of the pulse counter 29, preventing its operation. When the link is restored to serviceability, a logical "O" is generated at the output of the OR 38 element, which is fed to the input of the D-flip-flop 34, setting it to the logical "O" state. Thus, the indication of the link failure is stopped and the pulse counter 29 is prepared for operation. Thus, block 20 fault localization is returned to its original state. The technical and economic effect of the use of the proposed device as compared with the known one is associated with enhanced functionality and increased reliability of monitoring the device for digital transmission and reception of communication signals, since it is additionally possible to automatically locate faults based on the results of end-to-end monitoring of channels. Thus, in comparison with the known device, greater reliability and completeness of control is achieved, since the control covers almost all units of the device from input to output, in addition, almost all system failures are detected and a check for the stability of failure is provided, greater accuracy of fault localization, since In a known device, a failure in the path is detected, only starting from the entrance of the compacting unit (TV entry points digital test signal; line parameters are monitored separately (channel parameter control unit), and fault localization is not provided. 45 Invention Formula 1. A device for receiving and transmitting digital information, containing an encoder in each transmitting channel, the first encoder outputs of each transmitting channel are connected to the corresponding first inputs of the compression unit, the first output of which is connected to the first input of the first transmitter, the output of which is the first output of the device , the first synchronous generator, the outputs of which are connected to the nerve inputs of the respective encoders of each transmitting channel, the first receiver, the output of which through the synchronous selector is connected to the input of the second sync generator. eleven a channel separation unit, a signal simulator, an indication unit and a decoder in each receiving channel, characterized in that, in order to increase the reliability of control and enhancement of functionality by determining the location of faults, the third and fourth synchro generator, the first and second switches are introduced into it, the fault localization unit, the second transmitter in each transmitting channel and the switch and the second receiver in each receiving channel, the output of the second transmitter in each transmitting channel, are not connected to the second input of the terminal Ser, the second outputs of which are connected to the corresponding second inputs of the sealing unit, the first and second outputs of which are connected respectively to the first and second inputs of the first switch, and the second output is connected to the second input of the first transmitter, the third and fourth inputs of which are connected respectively to the output of the second clock generator and the output of the first receiver, the second output of the encoder of one of the transmitting channels through the third synchronization generator is connected to the third input of the compression unit, the output of the first transmitter through and The signal mititor is connected to the first input of the second switch, the output of which is connected to the input of the first receiver, the first and second outputs of the first switch are connected respectively to the pee input of the channel separation unit and the combined second input of the channel separation unit and the input of the fourth synchro generator, the outputs of which are connected to the corresponding third inputs the channel separation unit, the first and second outputs of the channel separation unit and the first output of the fault localization unit are connected respectively to the first The second, second and third switch inputs of each receiving channel, the fourth and fifth inputs of which are connected respectively to the first and second outputs of the encoders of the corresponding transmitting channels, on each receiving channel the first and second outputs of the switch are connected respectively to the first and second inputs of the decoder whose output is connected with the input of the second receiver, the first outputs of the second receivers of each receiving channel are connected to the corresponding first inputs of the fault localization unit, the second, third and fourth The outputs of which are connected respectively with the fifth input of the first switch, the combined first input of the display unit and the second input of the second switch and the corresponding second inputs of the display unit, the inputs of the second transmitters of each transmission channel, the third input of the second switch, the second input of the fault localization unit are respectively the first, the second and third inputs of the device, the outputs of the second receivers each 10 ts 20 25 09069 12 The second receiving channel and the third output of the fault localization unit are the second and third outputs of the device, respectively. 2. The device according to claim 1, characterized in that the fault localization unit contains a synchronous generator, counters, decoders, triggers, a register, a pulse shaper, AND elements, OR elements, NOT elements and a delay element, the output of the synchronous generator is connected to the first inputs of the first and second and the third counters, the first and second outputs of the first counter are connected respectively with the first and second inputs of the first decipher, the first and second outputs of which are connected respectively with the combined first inputs of the second decipher and pulse generator and. united by the first input of the first trigger and the input of the delay element, the output of which is connected to the first input of the second trigger, the output of which through the first element is NOT connected to the first input of the first element And, the output of the first or second trigger, connected to the first input of the first element OR, the output of which is connected to the first the input of the third trigger, the output of which is connected to the combined first inputs of the second element AND register, and the fourth trigger, the second input of the first trigger and through the second element is NOT connected to the second input of the first The first element And the first input of the third element And, the output of the third element And connected to the second input of the second trigger, the output of the first element And connected to the second input of the second counter, the output of which is connected to the first input of the second element OR, the output of which is connected to the second input of the third trigger , the output of the third element OR is connected to the combined second input of the fourth trigger, the third inputs of the first element AND and the second trigger and through the third element is NOT connected to the second input of the first trigger and the first input ohm of the fourth element AND, the output of which is connected to the second input of the third counter, the output of the third counter is connected to the second input of the first OR element, the output of the fourth trigger is connected to the second input of the second decipher, the outputs of which are connected to the corresponding second inputs of the register, the outputs of the register are connected to corresponding inputs of the fourth element OR, the output of which is connected to the combined second inputs of the pulse former and the fourth element AND, and through the fourth element is NOT connected to the second input a second AND gate whose output is connected to a second input of the first counter, the pulse shaper output is connected to the third input of the register, the output of the fifth element is coupled to the fourth input of the first and second input tre30 35 45 50 55 the second AND elements, the combined respective inputs of the third OR element and the third inputs of the second decoder are the first inputs of the block, the combined inputs of the NOT element and the second input of the second OR element are the second input of the block, the first and second outputs of the first decoder are respectively the first and the second outputs of the block, the outputs of the register and the second trigger are the fourth outputs of the block, the output of the third trigger is the third output of the block. Table 1 From line 25 5k / j blot 6 blocks 21 b / yku2 1 FIG. Z S / ioKuM 9, 21