RU2138910C1 - Device for automatic measuring of characteristics of digital communication channel - Google Patents

Abstract

FIELD: telecommunications. SUBSTANCE: method involves use of memory unit, and first binary counter for generation of test, control and address signals in parallel code, their conversion into serial code by means of D flip-flop, third binary counter, first and second multiplexers, and electronically controlled gate, comparison of received and test information by means of comparison unit, and judging using comparison results by means of error analyzer and counting of total number of communication cycles between central and peripheral nodes by means of second binary counter, in order to measure number of missed communication loops using reverse counter, and to measure number of non-detected errors and errors which have been detected, but not corrected by communication equipment decoder. Results are displayed on digital indication board. EFFECT: possibility to measure statistic characteristics of digital communication channels. 3 dwg

Description

 The invention relates to telecommunications and can be used to measure the statistical characteristics of discrete communication channels.

 Known devices for monitoring the transmission of information (see "Metrological support of transmission systems" under the editorship of B.P. Khromogo. -M.: Radio communication, 1991 and author of the USSR USSR N 1241492 according to class H 04 B 3/46 , 1984, "Device for controlling the transmission of information").

 In these sources, to detect errors, the principle of comparing a received, previously known message with a control message, which is generated by the local generator in the measuring device, is used. In addition to the error detector (comparison circuit), the control device includes a phasing unit, which is necessary to ensure synchronous and common-mode operation of the test and control signal generators, respectively, on the transmitting and receiving sides. The process of measuring errors is carried out after a preliminary establishment of synchronism in the operation of control devices, which increases the measurement time. In addition, the result of measuring the error coefficient, which is defined as the ratio of the amount of incorrectly received information to the total amount of information transmitted, will depend not only on the accuracy of the information transmission system, but also on the quality of the monitoring device, in particular the phasing units and the stability of the reference frequencies of the generators test and control signals. As a result of this, the control device in many cases does not provide the required measurement accuracy.

 Closest to the invention in technical essence and the achieved effect is a "Device for automatically measuring the characteristics of a discrete communication channel" (see ed. St. USSR N 1149423 according to class H 04 B 3/46, 1983), containing the first adder according module two, the first input of which is connected to the first input of the first recursive register, the signal output of which is connected to the second input of the first adder modulo two, the second adder modulo two, the first input of which is connected to the first input and signal output of the second recurrent reg tra, zero counter, first comparison unit, the first information inputs of which are connected to the information outputs of the second recurrence register, a shift pulse counter, the outputs of which are connected to the decoder inputs, and four AND elements, two memory registers, the second comparison unit, clock generator, five flip-flops, two OR elements and a fifth AND element, while the second adder input modulo two is connected to the first input of the first recursive register, and the output is connected to the first input of the second trigger, information The odes of the first recurrent register are connected to the information inputs of the first memory register and to the first information inputs of the second comparison unit, the output of the first adder modulo two is connected to the input of the zero counter and to the first input of the first trigger, the second input of which is connected to the second input of the second trigger and to the first the output of the zero counter, the second output of which is connected to the first input of the first AND element, the second input of which is connected to the inverse output of the first trigger, and the third input - with the direct output of the second trigger , the output of the first element And is connected to the first input of the third trigger, the direct output of which is connected to the control inputs of the first and second memory registers and the first input of the second element And, the second input of which is connected to the second input of the first recursive register, and the third and fourth inputs are connected respectively to the inverse outputs of the fourth and fifth triggers, the reset inputs of which are connected to the reset input of the third trigger and the output of the decoder, the first input of the shift counter is connected to the output of the second element And, the output is the clock generator is connected to the first input of the third AND element, the output of which is connected to the first inputs of the first and second OR elements, the second input of which is connected to the output of the fourth AND element, and the output is connected to the second input of the shift pulse counters, the second input of the first OR element is connected to the output of the fifth element And, and the output is connected to the second input of the second recurrence register, the information outputs of which are connected to the information inputs of the second memory register, the outputs of which are connected to the second and formation inputs of the second comparison unit, the output of which is connected to the installation input of the fifth trigger, the outputs of the first memory register are connected to the second information inputs of the first comparison unit, the output of which is connected to the installation input of the fourth trigger, the direct output of which is connected to the second input of the third element And, the second input the first recurrent register is connected to the first input of the fourth element And and to the first input of the fifth element And, the second and third inputs of which are connected respectively with the inverse and the outputs of the fourth and fifth flip-flops, the last direct output connected to the second input of the fourth element I.

 The disadvantage of this device is the low accuracy of measuring the statistical characteristics of information transfer due to the fact that during the measurement it is necessary to transmit the test signal in only one direction, which violates the natural algorithm of the time diagram of the communication system, which is presented in FIG. 2, and does not take into account the actual format of the codograms of the exchange of information between the communication equipment and the terminal device.

 The unidirectional measurement scheme also does not allow measuring the transmission characteristics of information of the forward and reverse communication channels in real time. Such measurements do not provide true characteristics of noise immunity and reliability of information transmission for communication systems operating in an unsteady jamming environment, for example, for communication systems with frequency adaptation in conditions of intentional interference.

 Thus, it is advisable to measure the statistical characteristics of the information transmission system in the forward and reverse directions while preserving real protocols and codograms of information exchange (see Figs. 2, 3), as well as algorithms for the interaction of communication equipment and terminal equipment.

 To eliminate this drawback, a device for automatically measuring the characteristics of a discrete communication channel containing a first OR element connected in series, the first input of which is connected to the "Ready to receive" output of communication equipment, and the first RS-trigger, whose S-input is connected to the "Ready" output transmission of “communication equipment”, a second RS-flip-flop, the S-input of which is connected to the “Ready for transmission” output of communication equipment, the first binary counter connected in series, the installation and counting inputs of which are connected They are connected to the output “Beginning of a circulation cycle” of communication equipment and the output of “Ready to transmit” communication equipment, respectively, and a decoder connected in series to the second OR element, the first input of which is connected to the output “End of code word reception” of communication equipment, the third RS-trigger, The S-input of which is connected to the output "Start of codeword transmission" of communication equipment, and the first element And, the fourth RS-flip-flop connected in series, the S-input of which is connected to the output of "Start of code word reception" of communication equipment, and the second element And, p the fourth RS-flip-flop, the S-input of which is connected to the “Information Failure” output of the communication equipment, the third AND element, the fourth And element connected in series, the first input of which is connected to the “Start of the access cycle” output of the communication equipment, and the second binary counter, comparison unit the first input of which is connected to the "Received information" output of communication equipment, a third binary counter is connected in series, the counting input of which is connected to the output of the third element And, the first multiplexer, the second bit inputs of which are connected inens with the outputs of the first binary counter, and an electronically controlled switch, the output of which is connected to the second input of the comparison unit and is the input of the "Transmitted information" of the communication equipment, the memory unit and the second multiplexer connected in series, the second bit inputs of which are connected to the output of the third binary counter and the output is connected to the second input of the electronically controlled switch, a switch connected in series, the movable contact of which is connected to the corresponding output a decoder, an error analyzer, the second, third and fourth inputs of which are connected to the outputs of the comparison unit, the first RS-trigger and the fifth RS-trigger, respectively, the fourth binary counter and display unit, the second input of which is connected to the discharge outputs of the second binary counter, a reverse counter the subtracting input of which is connected to the first input of the first OR element, and the summing input is connected to the output of the fourth AND element, serially connected single pulse generator, the output of which is also connected to the combined second inputs of the first and second elements OR, to the installation inputs of the second, third and fourth binary counters and to the installation input of the reverse counter, and a D-trigger, the information input of which is connected to the transfer output of the second binary counter, the clock input is connected to the installation input of the first binary counter, and the inverse output is connected to the second inputs of the third and fourth elements AND, the fifth binary counter, the installation and counting inputs of which are connected to the output of a single generator pulse and S-input of the fifth RS-flip-flop, respectively, and the output is connected to the fourth input of the display unit, the third element is OR, the first input of which is connected to the "Start receiving a code word" communication equipment, the second input is connected to the output of a single pulse generator, and the output connected to the installation inputs of the fourth and fifth RS-flip-flops, the fourth element OR, the first and second inputs of which are connected to the outputs of the first and second elements And, respectively, and the output is connected to the first input of the third element And, the second input of which connected to the inverse output of the D-trigger.

 In FIG. 1 shows a block diagram of a device; in FIG. 2 shows a timing diagram of the exchange of information; in FIG. 3 - stress diagrams explaining the operation of the device.

 A device for automatically measuring the characteristics of a discrete communication channel contains the first, second and third elements OR 1.1 - 1.3, made, for example, on chips of type 1564LL1, the first, second, third, fourth and fifth RS-flip-flops 2.1 - 2.5 (for example, type 564TR2), the first, second, third and fourth binary counters 3.1 - 3.4, made, for example, on type 564IE10 chips, the first and second multiplexers, made, for example, on type 564KP2 chips, an electronically controlled switch 5, made, for example, on type 564KT2 chips reverse explicit counter 6, made, for example, on type 564IE14 microcircuits, the first, second, third and fourth elements And 7.1 - 7.4, made, for example, on type 1564LI microcircuits, memory unit 8, made, for example, in the form of a power source with voltage taps logical "0" and "1", a comparison unit 9, made, for example, in the form of an adder modulo two, a decoder 10, made, for example, on type 564ID1 microchips, a switch 11, made, for example, in the form of a switch, analyzer 12 errors, made, for example, in the form of a four-input element nta And a single pulse generator 13, for example, a G4-32 type generator, a D-trigger 14, made, for example, on a 564TM2 type microcircuit, an indication unit 15 made on seven-segment indicators with a decoder. In this case, the first OR 1.1 element is connected in series, the first input of which is connected to the "Ready for reception" output of communication equipment, and the first RS-trigger 2.1, the S-input of which is connected to the "Ready for transmission" output of communication equipment, the S-input of the second RS- trigger 2.2 is connected to the output "Readiness for transfer" of communication equipment, the first binary counter 3.1 is connected in series, the installation and counting inputs of which are connected to the output "Start of a circulation cycle" of communication equipment and to the output "Readiness of transmission" of communication equipment, respectively frater 10, a second OR element 1.2 is connected in series, the first input of which is connected to the "End of codeword transmission" output of communication equipment, a third RS-trigger 2.3, whose input is connected to the "Start of codeword transmission" output of communication equipment and the first AND 7.1 element, the fourth RS-trigger 2.4 is connected in series, the S-input of which is connected to the "Start of the code word" output of the communication equipment, and the second element And 7.2, the S-input of the fifth RS-trigger is connected to the "Information failure" output of the communication equipment, the fourth element is connected in series7.4, the first input of which is connected to the output "Beginning of a circulation cycle" of the communication equipment, and the second binary counter 3.2, the first input of the comparison unit 9 is connected to the output "Received information" of the communication equipment, the third binary counter 3.3 is connected in series, the counting input of which is connected to the output of the third element And 7.3, the first multiplexer 4.1, the second bit inputs of which are connected to the bit outputs of the first binary counter 3.1, and the electronically controlled switch 5, the output of which is connected to the second input of block 9, is compared I am the input of “Transmitted information” of communication equipment, a memory unit 8 and a second multiplexer 4.2 are connected in series, the second bit inputs of which are connected to the output of the third binary counter 3.3, and the output is connected to the second input of the electronically controlled switch 5, switch 11 is connected in series, the movable contact of which is connected to the corresponding output of the decoder 10, the error analyzer 12, the second, third and fourth inputs of which are connected to the outputs of the comparison unit 9, the first RS-trigger 2.1 and the fifth RS flip-flops 2.5, respectively, the fourth binary counter 3.4 and the indicating unit 15, the second input of which is connected to the discharge outputs of the second binary counter 3.2, the subtracting input of the reverse counter 6 is connected to the first input of the first OR 1.1 element, and the summing input is connected to the output of the fourth AND element 7.4, a single pulse generator 13 is connected in series, the output of which is also connected to the combined second inputs of the first and second elements OR 1.1 and 1.2, to the combined installation inputs of the second, third and fourth two primary counters 3.2, 3.3, 3.4 and to the installation input of the reverse counter 6, and D-trigger 14, the information input of which is connected to the transfer output of the second binary counter 3.2, the clock input of which is connected to the installation input of the first binary counter 3.1, and the inverse output is connected to the second input of the fourth element And 7.4, the installation and counting inputs of the fifth binary counter 3.5 are connected to the outputs of the generator 13 of a single pulse and the S-input of the fifth RS-trigger 2.5, respectively, and the output is connected to the fourth input of block 15 of the indication, the first input of the third element or 1.3 is connected to the output "Start receiving the code word" of communication equipment, the second input is connected to the output of the single pulse generator 13, and the output is connected to the installation inputs of the fourth and fifth RS-flip-flops 2.4 and 2.5, the first and second inputs of the fourth element OR 1.4 are connected to the outputs of the first and second elements AND 7.1 and 7.2, respectively, and the output is connected to the first input of the third element AND 7.3, the second input of which is connected to the inverse output of the D-trigger 14.

The device operates as follows. At the output of the generator 13, a single positive pulse is generated, which is fed to the installation inputs of the second, third, fourth, fifth binary counters 3.2 - 3.5, the reverse counter 6 and the S-input of the D-trigger 14 directly, to the installation input of the first RS-trigger 2.1 through the first OR element 1.1, and to the R-inputs of the second, third RS-flip-flops 2.2, 2.3 and the fourth, fifth RS-flip-flops 2.4, 2.5 - through the second and third elements OR 1.2 and 1.3, respectively. Binary counters 3.2 - 3.5, the reverse counter 6 are set to the initial state, RS-flip-flops 2.1 - 2.5 are transferred to the position of the logical "0", and the D-flip-flop 14 takes the state of the logical "1". Moreover, logical “1” voltages are generated at the inverse outputs of the first and fifth RS-flip-flops 2.1 and 2.5, which are supplied to the second and fourth inputs of the error analyzer 12, respectively, and at the direct outputs of the second, third, and fourth RS-flip-flops 2.2, 2.3, 2.4 logical “0” voltages are generated, which are applied to the control input of the electronically controlled switch 5 and the first inputs of the first and second elements AND 7.1 and 7.2, respectively. The normally open contacts of the electronically controlled switch 5 are transferred to the open state, the first and second elements And 7.1 and 7.2 do not work, and the D-trigger 14 remains in the logical state "1". At the inverse output of the D-flip-flop 14, a logic “0” voltage is generated, which, entering the second inputs of the third and fourth elements AND 7.3 and 7.4, prohibits the passage of signals arriving at their first inputs. From the output of the communication equipment of the central station, a positive pulse U ₁ (see Fig. 3a) “Beginning of a circulation cycle” (to peripheral stations) is supplied to the installation input of the first binary counter 3.1, to the first input of the fourth element And 7.4 and the C-input of the D-trigger 14. The first binary counter 3.1 is set to its initial state, and the D-flip-flop 14 is set to the logical "0" position, since a logical zero voltage is applied to its information input from the transfer output of the second binary counter 3.2, and voltage is generated at its inverse output logical logic "1", which, entering the second input of the fourth element AND 7.4, allows a positive pulse U ₁ to pass through it to the summing input of the reverse counter 8 and the counting input of the second binary counter 3.2. At the outputs of the first bits of the reverse and second binary counters 6 and 3.2, respectively, logical voltages of "1" are formed, at the remaining bit outputs of which the voltages remain equal to logical "0".

From the output of the communication equipment, a positive impulse U ₂ (see Fig. 3b) "Transmit Readiness" is supplied to the S-inputs of the first and second RS-flip-flops 2.1 and 2.2 and the counting input of the first binary counter 3.1. The first and second RS-flip-flops 2.1 and 2.2 are set to logical "1", and the unit value is fixed in the memory of the first binary counter 3.1. From the output of the first binary counter 3.1, the current value of the information goes to the second information inputs of the first multiplexer 4.1 and to the input of the selector 10 of the communication direction. From the output of the selector 10 select the direction of communication, the logical voltage "1" through the switch P11 connected to the desired output of the communication direction is supplied to the first input of the analyzer 12 errors. A logic “0” voltage is generated at the inverse output of the first RS-trigger 2.1, which, entering the third input of the analyzer 12 errors, locks it to the information transmission interval from the central station (see Fig. 2), and at the direct output of the second RS-trigger 2.2, a logical "1" voltage is generated, which is fed to the control input of the electronically controlled switch 5. The normally open contacts of the electronically controlled switch 5 are closed, connecting the output of the first multiplexer 4.1 to the second input of the comparison unit 9 and to the input "Before Vai information "communication equipment, and the output of the second multiplexer 4.2 is disabled. From the output of the communication equipment, the first positive impulse U ₃ (see Fig. 3c) “Beginning of codeword transmission” is fed to the S-input of the third RS-trigger 2.3 and puts it in the logical position “1”. At the direct output of the third RS-trigger 2.3, a logical "1" voltage is generated, which is fed to the first input of the first AND 7.1 element, the second input of which from the output of the communication equipment receives clock pulses U ₄ (see Fig. 3d). At the output of the first element AND 7.1, clock pulses U ₄ appear, which through the fourth element OR 1.4 and the third element AND 7.3 are fed to the counting input of the third binary counter 2.3 with a conversion factor N equal to the number of information bits in the codeword. The volume of the third binary counter 3.3 is filled and the current values of the output voltages in binary code are fed to the control inputs of the first and second multiplexers 4.1 and 4.2. At the output of the first multiplexer 4.1, an address code word corresponding to the address of the first communication direction is generated and is used to organize interaction between the central and peripheral stations. The address word is a service word and is not issued to the terminal equipment at reception. After receipt of a third binary counter 3.3 N of clock pulses from the output of the communication equipment through the second element OR 1.2 to the R-inputs of the second and third RS flip-flops 2.2 and 2.3, a positive pulse U ₅ (see Fig. 3d) is received words ", which translates the second and third RS-flip-flops 2.2 and 2.3 to the logical" 0 "position. At the direct outputs of the second and third RS flip-flops 2.2 and 2.3, logical "0" voltages are generated, which are fed to the control input of the electronically controlled switch 5 and the first input of the first AND 7.1 element, respectively. Normally closed contacts of the electronically controlled switch 5 are closed, connecting the output of the second multiplexer 4.2 to the second input of the comparison unit 9 and to the input of the communication equipment, and the first element And 7.1 is locked, excluding the arrival of clock pulses U ₄ to the counting input of the third binary counter 3.3. Upon receipt of the second positive pulse U ₃ (see FIG. 3c) at the S-input of the third RS-trigger 2.3, a positive voltage is generated at its direct output, which again goes to the first input of the first AND 7.1 element. The first element AND 7.1 is again triggered and a series of N clock pulses is formed at its output, which, through the fourth element OR 1.4, is fed to the first input of the third element And 7.3. Due to the presence of a logic 1 voltage at the second input of the third element And 7.3 coming from the inverse output of the D-trigger 14, a series of clock pulses U _{4 is} also formed at its output, which is fed to the counting input of the third binary counter 3.3. The current values of the third binary counter 3.3 in binary code are supplied to the control inputs of the first and second multiplexers 4.1 and 4.2, while the information inputs of the second multiplexer 4.2 from the output of memory unit 8 receive the values of logical "0" or "1" corresponding to the control code word.

When the second pulse U ₅ (see Fig. 3d) arrives from the communication equipment, the second RS-trigger 2.2 remains in the logical "0" position, and the third RS-trigger 2.3 returns to the logical "0" state. The process of forming a control word is completed. If the following pulses U ₃ , U ₄ and U _{5 are} received from communication equipment in the first exchange cycle (communication direction), the process of generating control words is repeated (see Fig. 3e). The operation of the device in subsequent exchange cycles is characterized by a change in the state of the first binary counter 3.1, the counting input of which receives pulses U ₂ (see Fig. 3b), which determine the beginning of the next exchange cycles (and, accordingly, addresses). The process of generating code words is repeated.

 The generated sequence of code words enters the communication equipment of the central station and is transmitted as a test to the peripheral station. After the end of the transmission, in accordance with the time diagram, the central station is put into the reception mode of the test formed at the peripheral station in a similar way.

From the communication equipment of the central station, a positive impulse U ₇ “Ready to receive” (see Fig. 3g) is fed directly to the subtracting input of the reverse counter 6, and to the R-input of the first RS-trigger 2.1 through the first element OR 1.1. The information recorded in the reversible counter 6 decreases by one and becomes equal to zero, and the first RS-trigger 2.1 returns to the logical “0” state and a logical “1” voltage is generated at its inverse output, which is fed to the third input of the analyzer 12 errors and allows it to work in the interval of receiving information from a peripheral station (see Fig. 2). The receipt from the communication equipment of the pulse U ₈ (see Fig. 3h) “Beginning of reception of the code word” to the S-input of the fourth RS-trigger 2.4 leads to the formation of a logical “1” voltage at its direct output, which is supplied to the first input of the second element And 7.2. At the output of the second element And 7.2, a series of N clock pulses is formed, which through the fourth element OR 1.4 is fed to the first input of the third element And 7.3, the second input of which from the inverse output of the D-trigger 14 receives a logical "1" voltage. At the output of the third element AND 7.3, a series of N clock pulses is also formed, which is fed to the counting input of the third binary counter 3.3, the output signals of which control the first and second multiplexers 4.1 and 4.2. From the output of the second multiplexer 4.2, the control sequence through the normally closed contacts of the electronically controlled switch 5 is fed to the input of the communication equipment and the first input of the comparison element 9, the second input of which receives the received information signal U ₁₀ from the output of the communication equipment (see Fig. 3k). In the case of differences between the received and generated control information at the output of the comparison unit 9, positive pulses are formed that characterize the presence of errors in the received message, which are fed to the second input of the error analyzer 12. Due to the presence of logical “1” voltage errors at all four inputs of the analyzer 12, the number of positive pulses corresponding to the number of errors in the received information is generated at its output, which are fed to the counting input of the fourth binary counter 3.4 for recording them. At the end of the reception of the first control word from the output of the communication equipment to the R-inputs of the fourth and fifth RS-flip-flops 2.4 and 2.5, through the third element OR 1.3, a positive pulse U ₉ "End of reception of the code word" (see Fig. 3i) is received, which translates them to the logical "0" position. At the same time, the passage of clock pulses through the third element AND 7.3 stops and the formation of the first control word U (see Fig. 3k) is completed, and the fifth RS-trigger 2.5 remains in the logical "0" position. The comparison of the received and control information in the following words is carried out in a similar way.

If it is impossible to correct errors in the codeword when they are detected by the decoder from the output of the communication equipment, a positive pulse U ₁₁ “Information failure” is applied to the S-input of the fifth RS-trigger 2.5 and the counting input of the fifth binary counter 3.5 (see Fig. 3l), indicating the presence of an error in the received codeword. The fifth binary counter 3.5 registers the presence of a detected error, and the fifth RS-flip-flop 2.5 is put into the logical "1" position. At the same time, a logic “0” voltage is generated at its inverse output, which is fed to the fourth input of the error analyzer 12, prohibiting the passage of signals from the output of the comparison unit 9 to the counting input of the fourth binary counter 3.4, which fixes errors not detected by the communication equipment decoder.

Upon receipt of the following positive pulses U ₁ from the communication equipment of the central station (see Fig. 3a), the process of automatic measurement of the characteristics of the discrete communication channel is repeated and completed when the second binary counter 3.2 is filled, fixing the total number of communication cycles, the volume of which is selected based on the required measurement error . At the same time, at its transfer output P, a logical “1” voltage is generated, which is fed to the information input of the D-trigger 14.

Another pulse U ₁ (see Fig. 3a) puts the D-flip-flop 14 into a logical “1” state and at its inverse output the voltage becomes equal to a logical “0”, which prevents the signals from passing through the third and fourth elements AND 7.3 and 7.4, and the measurement process stops. At the same time, in the counter 6, the summing and subtracting inputs of which received the number of pulses corresponding to the number of calls of the central station to the peripheral station and responses of the peripheral station of the central station, respectively, the number of missed communication cycles is recorded. Errors not detected by the communication equipment decoder are recorded in the fourth binary counter 3.4, and errors detected but not corrected by the decoder in the fifth binary counter 3.5. All information recorded in the counters 3.2, 3.4, 3.5 and 6 is displayed on the digital displays of the display unit 15.

 Thus, the proposed technical solution allows you to determine the true quality characteristics of the transmission and reception of information of a communication system with time division of channels in non-stationary conditions of an interference environment.

Claims (1)

 A device for automatically measuring the characteristics of a discrete communication channel, containing a first OR element connected in series, the first input of which is connected to the "Ready to receive" output of communication equipment, and the first RS-trigger, the S-input of which is connected to the "Ready for transmission" output of communication equipment, a second RS-flip-flop, the S-input of which is connected to the "Ready for transfer" output of communication equipment, the first binary counter is connected in series, the installation and counting inputs of which are connected to the "Start of the access cycle "communication equipment and to the output" Readiness for transmission "of communication equipment, respectively, and a decoder connected in series to the second OR element, the first input of which is connected to the output" End of code word reception "of communication equipment, the third RS-trigger, the S-input of which is connected to the output "Start transmitting the code word" of communication equipment, and the first element And, the second input of which is designed to receive clock pulses, are connected in series to the fourth RS-trigger, the S-input of which is connected to the output "Start of receiving the code word" apparatus communication, and the second element And, the fifth RS-flip-flop, whose S-input is connected to the "Information collection" output of the communication equipment, the third element And, connected in series to the fourth element And, the first input of which is connected to the "Start of the circulation cycle" output of the communication equipment , and a second binary counter, a comparison unit, the first input of which is connected to the “Received information” output of the communication equipment, characterized in that a third binary counter is connected in series, the counting input of which is connected to the output of the third AND element, the first a multiplexer, the second bit inputs of which are connected to the bit outputs of the first binary counter, and an electronically controlled switch, the output of which is connected to the second input of the comparison unit and is the "Transmitted information" input of communication equipment, a memory block connected in series and a second multiplexer, whose second bit inputs connected to the output of the third binary counter, and the output is connected to the second input of the electronically controlled switch, the control input of which is designed to receive voltage from the direct output of the second RS-trigger, a series-connected switch, a movable contact of which is connected to the corresponding output of the decoder, an error analyzer, the second, third and fourth inputs of which are connected to the outputs of the comparison unit, the first RS-trigger and the fifth RS-trigger, respectively, the fourth a binary counter and an indication unit, the second input of which is connected to the discharge outputs of the second binary counter, a reversible counter, the subtracting input of which is connected to the first input of the first OR element, and the sum the connecting input is connected to the output of the fourth element AND, all the information recorded in the reversible counter is displayed on the digital display of the display unit, a single pulse generator is connected in series, the output of which is connected to the combined second inputs of the first and second elements OR, to the installation inputs of the second, third and fourth binary counters and to the installation input of the reversible counter, and a D-trigger, the information input of which is connected to the transfer output of the second binary counter, clock input connected to the installation input of the first binary counter, and the inverse output is connected to the second inputs of the third and fourth AND elements, the R-input of the second RS-trigger is designed to receive a single pulse from the output of the second OR element, the fifth binary counter, the installation and counting inputs of which are connected to the output of the single pulse generator and the S-input of the fifth RS-flip-flop, respectively, and the output is connected to the fourth input of the display unit, the third OR element, the first input of which is connected to the output "Start receiving the code word" communication equipment, the second input is connected to the output of a single pulse generator, and the output is connected to the installation inputs of the fourth and fifth RS-flip-flops, the fourth OR element, the first and second inputs of which are connected to the outputs of the first and second elements And, respectively, for receiving clock pulses, and the output is connected to the first input of the third element I.

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