SU1035811A1 - Device for monitoring data transmitting channel - Google Patents

Abstract

1. A DEVICE FOR MONITORING A DATA TRANSMISSION CHANNEL, containing a serially connected demodulator, an error protection receiving unit, a test sequence receiver, a decision unit, the output of which is connected to the second input of the test sequence receiver, the third input of which is connected to the output of the demodulator, as well as sequentially the connected timer, the test sequence sensor and the transmitting error protection unit, the second output of which is connected to the second timer output, the first entering the imer and the second input of the test sequence sensor are interconnected, and the third and fourth, the sensor inputs of the test sequence are combined respectively with the second and third inputs of the timer, o t and l and y, with the aim of increasing the accuracy of control and localization 1 |; and faults; a repeater of code combinations, the first repeater of modulated signals and the second repeater of modulated signals whose output is connected to the input of the demodulator, and the control are entered into it The timer output group, the fourth and fifth output groups of which are connected respectively to the control inputs of the codeword repeater and the first repeater of the modulated signals, to the information input of which the output of the codeword repeater is connected via the modulator, the output of the transmitting protection block from the errors is connected to information input repeater code combinations. . 2. The device according to claim 1, from l and that, that the repeater of the code combinations contains the first trigger connected in series | control, the first element AND, ret c of the shift offset, the second element AND, and the first element OR, the second input of which pod.g is full to the output of the third element AND, one of the inputs of which is the information input of the codeword repeater and the other input is connected to the first WTO output A control trigger, the second output of which is connected to the second input of the second element AND, the output-QO of the first element OR is connected to the second input of the first element AND, and the second output of the shift register is connected to the second input of the second control stage. 3. The device according to claim 1,; distinguished by the fact that the repeater of the modulated signals contains pos. consequently, the third control trigger, the fourth AND element, the delay line, the pulse driver, the fourth control trigger, the fifth AND element, and the second OR element,

Description

the output of which is connected to the second input of the fourth element I, and the second delay line is connected to the first input of the sixth element AND whose output is connected to the second input of the second element OR, the second output of the fourth control trigger is connected to the second input of the sixth element I, and another input p That element is the information input of the modulated signal repeater.

The invention relates to radio engineering and can be used to monitor, locate faults and statistical analysis of data transmission channels.  A device for controlling data transmission channels is known, which on the transmitting side contains serially connected test signal generator and transmitting part of data transmission equipment, and on the receiving side serially connected receiving part of data transmission equipment, block. interfaces, an electronic computer or other devices that perform the functions of comparing and processing information. A disadvantage of the known device is the difficulty of localizing the Non-corrupted data transmission channel blocks, which requires the introduction of additional circuits into separate ones. blocks or organizations of loops.  It is also known a device containing de-modulators connected in series, an error protection receiving unit, a test sequence receiver, a decision unit, the output of which is connected to the second input of the test sequence receiver, the third input of which is connected to the output. demodulator, as well as a serially connected timer, a test sequence sensor and a transmitting Error Protection Unit, the second input of which is connected to the second timer output, the first timer input and the second input of the test sequence sensor are interconnected, and the third and fourth sensor inputs the test sequence is combined with the second and third inputs of timer C, respectively.  The disadvantage of this device is limited diagnostic capabilities, which consist in the impossibility of localizing the faulty data transmission channel blocks.  The purpose of the invention is to improve the accuracy of control and localization of faults.  This goal is achieved in that a device for controlling a data transmission channel containing a demodulator connected in series, an error protection receiver unit, a test sequence receiver, a decision unit, the output of which is connected to the second receiver input of the test sequence, the third input of which is connected to the output of the demodule torus, as well as a serially connected timer, a test sequence sensor and a transmission error protection unit, the second input of which is connected to the second output timer, the first timer input and the second sensor input of the test sequence are combined, and the third and fourth sensor inputs of the test sequence are combined respectively with the second and third inputs of the timer, entering 1y the code pattern repeater, the first modulated signal repeater and the second modulated signal repeater, the output of which is connected to the input of the demodulator, and the control inputs are connected to.  the third group of timer outputs, the fourth and fifth groups of the outputs of which are connected respectively to the control inputs of the code pattern repeater and the first repeater of the modulated signals, to the information input of which the code combination repeater output is connected through the modulator, the output of the transmitting error protection block is connected to information input repeater code combinations.  In addition, the codeword repeater contains, in series, the first control trigger, the first element AND, the shift register, the second element AND, and the first element OR the second input of which is connected to the output of the third AND element, one of the inputs of which is the information input of the code combination repeater, and the other the input is connected to the first output of the second control trigger, the second high output of which is connected to the second input of the second element AND, and the output of the first element OR under kg to the second input of the first ele cient And, the second register output ha of translations connected to second input vtorrgo control trigger.  In this case, the modulated signal repeater contains a third control trigger connected in series.  The fourth And element, the delay line, the pulse shaper, the fourth control trigger, the fifth And element, and the second OR element, the output of which is connected to the second input of the fourth And element, and the second output of the delay line connected to the first input of the sixth And element, the output of which is connected to the second input of the second element OR, the second output of the fourth control trigger is connected to the second input of the sixth element AND,. and the other input of the fifth element I is the information input of the repeater of the modulated signals.  7 The drawing shows the electrical circuit of the device for controlling the data transmission channel.  The device contains a sensor 1 test sequence, a timer 2, the transmitting unit 3 protection against errors, a repeater And code combinations, shift register 5, the second control trigger 6, the third element And 7, the second element And 8, the first element And the first control trigger 10, the first element OR 11, modulator 12, first repeater 3 modulated signals, delay line 1, pulse generator 15 fourth three | - control ger 1b, fifth element AND 17 sixth element AND 18, fourth element AND 19 third control trigger 20, second element OR 21, second for 22 vtoritel modulated signals.  demodulator 23, error protection receiving unit 24, test sequence receiver 25, decision unit 26.  Consider the operation of devices, and in two modes: monitoring the functioning of the channel, searching for a faulty data link channel block -.  When using the first mode, the Start-1 control signal is sent to the Start-1 input 27 of the sensor 1 of the test sequence and timer 2.  According to this signal, sensor 1 begins to form test code collisions, at the same time timer 2 sends a signal to control zero triggers 6, 10, 16, 20 and similar triggers of the second repeater 22 modulated signals that set the triggers to zero state.  As a result, elements 7 and 17 and a similar element of the second repeater 22 (5 are open with positive potentials taken from the zero outputs of the flip-flops, and elements 8, 9, 18 and 19 and similar elements of the second repeater 22 will be closed with negative potentials removed from the unit trigger outputs.  The code combination formed by the sensor 1 enters the error protection transmitting unit 3, where it is encoded with an error-resistant code, and then through the AND 7 element and the first element OR 11 of the repeater j of the code combinations arrive at the input of the modulator 12. In the modulator, the frequency spectrum of the incoming input pulses is converted in accordance with the implemented modulation method.  The modulated signal from the output of the modulator 12 is fed through the fifth element AND 17 and the second element OR 21 of the first repeater 13 modulated signals into the communication channel.  On the receiving side, the modulated signal from the output of the communication channel similarly passes through the corresponding AND element and the OR element of the second repeater 22 of the modulated signals and enters the input of the demodulator 23, which extracts the code combination encoded by the error-correcting code, and delivers it to the receiving protection unit 2 from errors and into the receiver 25 test sequence.  The latter coordinates the demodulator and the error protection block with the decisive block 2b and interimly stores the incoming information.  Then, upon request from the decision block, code combinations with the signs of the output of the demodulator or the output of the receiver of the anti-fault block of the protection unit enter the decision block 26.  In the error protection unit 2k, the code pattern is decoded and checked for errors.  In the case of error detection and impossibility, the receiving unit 2k generates a signal for re-issuing the code combination, which is then transmitted according to the received data transmission method via the feedback channel to the transmitting unit 3 for protection against errors.  If, after a specified number of repetitions, uncorrectable errors continue to be detected, then the error protection receiving unit 2k issues a test sequence to the receiver 25, and then through it to the resolving unit 2b a channel failure signal sends data.  In decision block 26, the coded noise tolerance code of the code combination, delivered from the demodulator 23, is compared with the reference code combination stored in the key of the decision block.  In the event that the code combination coincides with the reference one, and the receiving unit 2k outputs to the decision unit 2b a fault signal of the data transmission channel, the decision unit generates a signal about the failure of the receiving unit 2k.  If the code combination does not coincide with the reference one, then the decision block generates a channel failure signal in the area before the receiving error protection block 2k.  In case of failure to detect errors, the receiving unit 2 generates a signal to issue the next test code combination from the transmitting unit 3 of protection against errors.  At the same time, the decoded code combination is fed to the receiving unit 2 for protection against errors, to the receiver 25 of the test sequence, and from there, on request, to the resolver unit 26, where it is compared with the original primary code combination.  In the case of coincidence of code combinations, the information from the receiving unit 2kf is erased, and the decision unit begins polling the receiving unit 2 to receive the following code combinations.  If the primary code combination resulting from the decoding is not the same as the reference decisive block, it generates a signal that 2 errors were undetected by the receiving unit when decoding the error-correcting code combination.  The data link fault signals are output to the recording and display devices and are used to decide whether to search for a faulty data link block.  In this case, the second device operation mode is used.  To transfer the control unit to the second mode, the Stop signal is first fed to the input 29, the transferring sensor 1 of the test sequence and the timer 2 are reset, and then the Start 28 signal is applied to the input 28, the starting sensor 1 and the timer 2 for the second operation mode .  Timer 2 generates the signals that are sent to the up-.  equip the input of the transmitting unit 3 protection against errors and set it in a state ready to receive code combinations, on the single inputs of control triggers 10 and 20, and a similar control trigger of the second repeater 22 modulated signals.  The flip-flops are thrown into single states, with the result that And 9 and 19, and a similar And And second repeater 22 element, are opened up with positive potentials taken from single outputs.  Sensor 1 forms the first test. the code combination, which, after being encoded by the error-correcting code in the transmitting unit 3, enters the repeater 4 code combinations.  In the repeater k bit, the code combination K passes through the element AND 7 and the first element OR 11 to the output and simultaneously through the feedback circuit through the element 9 to the input of the shift register 5.  The shift register 5 provides a delay of -split the day code combination K for a time equal to or longer than its passage to the input of the modulator 12.  As the code combination passes through the shift register 5, the terminal bits of the register are given a signal at the single input of the second control trigger 6, which is translated to a single state.  As a result, the negative potential taken from the zero output of the second trigger 6 closes the element And 7, and the positive potential from the single output opens the element And 8.  After this, the code combination from the shift register 5 through the second element AND 8 and the first element OR 11 is repeatedly outputted at the output of the code pattern repeater k and then will be repeated as it passes through the feedback circuit through the shift register 5.  To eliminate synchronization breaks and interruptions in the operation of the data channel, it is necessary to select the corresponding output of the shift register 5, the signal from which determines the output off moment of the transmitting unit 3 connecting the output of the repeater feedback circuit t using And 7 and 8 elements.  The code combination is repeated N times.  The end point of the repetitions is determined by applying a signal from the output of timer 2 to the zero input of the first control trigger 10,.  Trigger 1 triggers and closes the negative potential from the single output element I 9, thereby breaking the feedback circuit.  Thus, the element AND 9 should be open for a period of time t (n – i – y, where T is the transit time of the g-bit code combination along the feedback circuit.  Then, with a delay from the output of timer 2, a signal is applied to the zero input of the second control trigger 6, which transforms e <5 to the zero state.  1rigger b is triggered, closes the element AND 8 and opens the element AND 7, the circuit is ready for feeding from the output of the transmitting unit 3 of the new code combination.  The sequence of n code combinations of QC obtained as a result of repetitions. . . K is converted in modulator 12 into a modulated signal M (QC. . . K), which is fed to the input of the repeater 13 modulated signals.  In repeater 13, the signal passes through the open fifth element AND 17 and the second element OR 21 and is fed to the input of the communication channel.  At the same time, the signal enters through the covered, fourth element 19 to the input of the 1-line delay.  The delay line provides a signal delay on time equal to or greater than the transit time of the signal M (QC. .  . K) / y on the input channel of the communication channel.  After a time sufficient for the signal M to pass through the open fifth element I 17, a control signal arrives from the end links of the delay line 1A at the input of the pulse shaper 15.  Shaper 15 generates a pulse sufficient to trigger the trigger and applies it to the single input of the fourth control trigger 16, which is turned into a single state.  As a result of this, the fifth element H 17 is closed by the negative potential removed from the zero output of the trigger 16, and the sixth element And 18 opens with a positive potential from the single output.  Thereafter, the signal AND from the delay line through the sixth element AND 18 and the second element OR 21 is repeatedly outputted at the output of the repeater 13 and will then repeat, passing through the feedback circuit through the delay line.  Modulated signal M {KK. . . is repeated m times.  The end point of the repetitions is determined by applying a signal from the output of timer 2 to the zero input of control trigger 20, which is triggered and closes the fourth element And 19, with a negative potential from a single output.  thus breaking the feedback loop.  Thus, the element AND 19 must be open for a period of time - T (t -1; T2, where c2 is the transit time of the signal M through the feedback circuit.  Then, with a delay from the output of timer 2, a signal is applied to the zero input of the fourth control trigger 16.  The trigger 16 is activated, closes the sixth element And 18. and opens the fifth element And 17, the circuit is ready for supplying from the output of the modulator 12 a new modulated signal. The resulting m repetitions of the modulated signal C MM. . . M, passage through the communication channel, is subject to possible distortion of Mo. As a result, a distorted signal occurs at the output of the communication channel, (NM. . . M), which is fed to the input of the second repeater 22 modulated signals.  The latter, functioning in a similar way, repeats / in 13 modulated signals, repeats the signal K times and supplies it to the input of demodulator 23, which converts the modulated signal. .  L, in a sequence consisting of nmSl code combinations. .  . TO.  . , TO. p, Each code combination K in the general case is different from the original code combination K as a result of possible errors in the data transmission channel. Moreover, if the error is transmitted by the transmitting unit 3 for protection against errors, then this error will be repeated in all nm P code combinations of K-, mainly in the same bits, t. e.  hm, 2 times.  If modulator 12 introduces an error, it will be repeated in the same bits and groups of code combinations F. r {K. (2. . .  K ,, F2 - {Mn 2--2hl- / me {nn -ntl nm -n + 2 nfnej r. e, t6-rae.  If the communication channel introduces an error, it will be repeated in the same bits in groups of code combinations lri 2 2tiw} e {nn e-fim + i nmP-hm + 2 - Time) t. e. .  P times  If the demodulator 23 makes an error, then the probability of repeating it in one and the same bits of the code combinations K, or the listed groups, rn and 8 times, respectively, is very small.  The code combinations K from the output of the demodulator 23 are fed to the input of the receiver 25 of the test sequence, from where they are then entered into the decision block 26 upon request.  At the same time, the code combinations arrive at the receiving unit 2 of protection against errors.  The receiving unit decodes the code combinations and, in the event of an error, generates a signal for transmission over the feedback channel to re-issue the code combinations from the transmitting unit 3, and in the case of non-detection of errors, it generates a signal to issue the next code combination.  However, the repeated code combination from the transmitting unit 3 will not be transmitted through the data transmission channel through the closed elements AND 7 and the similar element And repeater 22, and sensor 1 will not generate the following code combination by this time due to the absence of a signal from the timer.  The code combinations Kj entering the decider 26 are subjected to arr. This is done according to the following rule.  At the first stage, each 2-bit bottom code combination K, bitwise, is summed modulo 2 with the reference CODE to “ination K” stored in the computer memory.  As a result of the summation, code combinations of K, i.e., 1,2, are obtained. . .  jhrnC, containing units in those bits where errors occurred, t. e.  there were inconsistencies in the K- and K.  The remaining bits will be zeros.  Then code combinations A are bitwise algebraically summed with each other, resulting in a z-bit of code, the combination where and.  - the number of errors in the code combinations K, i 1,2.  . . . nme.  The obtained numbers are compared with the threshold values of the PTVs and, if.   nm decider unit 26 generates a fault signal of the transmitting unit 3 protection against errors.  The value of 4 is chosen based on statistical data on possible x-error transformations in data overload channels.  In the ideal case, if there are no repeated errors in the same bits, then rZ 0.  At the second stage, bitwise summation modulo 2rn-bit groups of code combinations F, F2 «occurs. ", Ff" g with the reference group li code, combinations r {QC. . . K5.  As a result of the summation, code combinations of B are obtained. J F. jQF, i 1,2, o. .  , mp, containing units in those bits. Already, errors occurred.  Then the code combinations Bj, bitwise, are algebraically summed with each other, as a result of which the following code is obtained: gpd, codeword 2, where 2i and BZJ-M errors, bit of codeword groups, G | i 1,2 ,. . . ,  The obtained numbers are compared with the threshold values of m K pfl e-L2B in the case if td - d, then decision block 26 generates a signal that the modulator 12 is faulty.  At the third stage, bitwise summation modulo 2parameter groups of code combinations H-j, H2, occurs. . .  fHg with the reference group hm of code combinations H {KK. . . Kj.  As a result of the summation, C code combinations are obtained. J N. ®H, i 1,2. . . c, containing units, in those bits where errors occurred.  Then c. Code combinations.  bitwise algebraically - are summed up with each other, as a result of which the codeword r 1 2 is obtained and the t-bit of the code r 1 2 - JПРтт where 3j is the number of errors in the category of groups of code combinations P.  1 1,2 ,. . . , city  The obtained numbers are compared with the threshold values of the AND and the AND-E in the case, if the linking unit 2b generates a signal about the health of the communication channel.  In the event that none of the above conditions for the malfunction of the data transmission channel elements are fulfilled, and as a result of comparing the code combinations with the reference errors, the calculator generates a fault signal for the demodulator 23-.  If errors are not detected, and the receiving unit, to 2 protection against errors, generates an error signal, which is input through the receiver 25 of the test sequence, into the resolver unit 26, then the latter generates a fault signal of the receiving unit 2 error protection.  After a time sufficient to control the data channel using the first test code combination, timer 2 sends a signal to the input of sensor 1 of the test sequence to form the next code combination.  At the same time, the timer sends a signal to the control input of the transmitter 1 11 of the error protection unit 3, setting the transmitter to readiness for encoding and transmitting the new code combination received from sensor 1.  Further, the operation of the control device is repeated until all has been searched. possible code combinations generated by sensor 1, or data on faults of data transmission channel blocks will not be received.  To control a hebratic data channel, it is necessary to use similar devices when transmitting information in the opposite direction.  .  .  The proposed control device can be assembled on typical elements and nodes produced by our industry.  Timer.  2 is an electronic device comprising a pulse generator of a reference frequency, a counter of these pulses, and a decoder, pod. ; Zh1chenny to the outputs of the counter bits.  To obtain a control signal at the required time, it is sufficient to connect to the corresponding output of the decoder.  As a decision block 26, a micro-computer can be used that has sufficient memory or speed for storing and processing incoming code combinations.  Thus, the proposed control device makes it possible to detect the location of malfunction of individual data transmission units without using special control circuits or loops embedded in the blocks, which increases the efficiency of operation and restoration of data transmission systems.

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Claims (3)

1. DEVICE FOR MONITORING A DATA-TRANSFER CHANNEL, comprising a series-connected demodulator, an error protection receiver unit, a test sequence receiver, a decision unit, the output of which is connected to the second input of the test sequence receiver, the third input of which is connected to the demodulator output, as well as a series-connected timer , a test sequence sensor and a transmitting error protection unit, the second output of which is connected to the second output of the timer, the first input of the timer - the second input of the probe of the test sequence is interconnected, and the third and fourth, the inputs of the probe of the test sequence are combined with the second and third timer inputs, characterized in that, in order to improve the accuracy of monitoring and localization of faults, a repeater is inserted into it code combinations, the first modulated signal repeater and the second modulated signal repeater, the output of which is connected to the demodulator input, and the control in $ odes is connected to the third 'group in timer strokes, the fourth and fifth group of outputs of which are connected respectively to the control inputs of the code combination repeater and the first modulated signal repeater, to the information input of which the code repeater output is connected via a modulator, and the output of the error protection transmitting unit is connected to the information input of the code repeater combinations 2. The device according to claim 1, characterized in that the code combination repeater comprises in series a first control trigger, a first AND element, a shift register, a second element AND a first OR element, the second input of which is connected to the output of the third AND element, one of the inputs of which is the information input of the repeater ^from code combinations, and the other input is connected to the first output of the second. horn control trigger, the second output of which is connected to the second input | LED for the second AND element, with the output of the first OR element connected to the second input of the first AND element, and the second shift register output of the sub-'O keys to the second input of the second three ”- control mode. 3. The device according to p. ^ Characterized in that the modulated signal repeater comprises a third control trigger, a fourth AND element, a delay line, a pulse shaper, a fourth control trigger, a fifth AND element and a second OR element, the output of which is connected to the second input of the fourth AND element, and the second output of the delay line is connected to the first input of the sixth AND element, the output of which is connected to the second input of the second OR element, the second output of the fourth control trigger is connected to the second input of the sixth element And, and the other input of the fifth element And is the information input of the repeater of modulated signals.