SU1049915A1 - Device for simulating digital data communication channel - Google Patents

Abstract

1. A DEVICE FOR MODELING DISCRETE INFORMATION TRANSMISSION CHANNELS, comprising a random signal sensor, a random pulse generator, a comparison unit whose outputs are the first group of device outputs, a clock pulse generator whose input is the device start input, characterized by In order to extend the functionality by reproducing the mode of influence of impulsive noise on the transmitted signal, it additionally contains a frequency divider, an interval sensor, between interferences an interference duration sensor, an interference sign sensor, an interference amplitude sensor, a control unit consisting of AND connected in series and a shift register, the discharge outputs of which are connected to the inputs of the OR element, and an interfering formation unit containing two reversible counters, two dephafratores , two groups of elements AND, analog-digital converter, element OR, four elements of AND, trigger and signal conditioner, the first inputs of the first and second elements AND are combined, the second input of the first element AND and inverse the input of the second division And is combined and connected to the first input of the signal conditioner and the output of the first decoder connected by inputs to the corresponding bit outputs of the first reversible counter, the subtracting input jtOTOporb is connected to the output of the first element I, and the bit inputs are connected respectively to the outputs of the elements And first the groups, the first inputs of the elements of the first and second groups are pairwise combined and connected to the corresponding output of the analog-digital converter, the input of which is connected to the output of the element OR, the outputs of elements AND of the second group, respectively, are connected to the bit inputs of the second reversible counter, subtracting W, the main input of which is connected to the output-. the house of the second element is And, and the bit outputs of the second reversible counter are connected cp: response. to the inputs of the second decoder, the output of which is connected to the first trigger input and the second input of the signal conditioner, the third input of which is connected to the forward trigger output and the first 4 CO CO the inputs of the third and fourth elements And, the second inputs of which are connected to the first output of the driver of the I signal, and the third inputs of the third and fourth ale (eni6v And are combined, the output of the clock pulse generator CL is connected to the first input the control unit and the input of the frequency divider, the corresponding input of the emitter OR control unit is connected to the output of the frequency divider, the first start input of the random pulse generator and the first input of the first element AND of the interfering unit; the output of the OR element of the control unit is connected to the sensor input of random signals whose output is connected to the second start input of the random pulse generator and the first inputs

Description

Starting the sensor of the interval between the noises, the sensor of the duration of the interference, the sensor of the interfering noise and the sensor of the amplitude of the disturbance, the data read inputs of which are connected to the second output of the signal conditioner of the interference generation unit and the second input of the control unit And, and the output of the sensor between intervals interference, sign and amplitude P (4fs are connected respectively to the first and second inputs of the EPR element of the interference generation unit, the third input of the third element AND the interference formation unit, the second input is three block formation mode Interference outputs -Third and fourth elements And which are connected to the first and second inputs of -block with equal, respectively, the output of the pedvar bit of the shift register of the control unit is connected to the second input of the sensor for spacing of the intervals around the interference, the second inputs of the elements And the first the group of the block of formation of interference, the output of the second bit of the shift register is connected to the second input of the sensor for the duration of the interference and the second column by the inputs of the elements and the second group of the block of formation of interference, the output of the third bit shift register is connected to

the second start input of the noise sign sensor, the fourth bit output is connected to the second start input of the noise amplitude sensor, and the third and fourth inputs of the comparator unit are connected to the first and second random generator outputs, respectively, and are the second group of device outputs.

2. The device according to claim 1, of which is If the signal generator contains two elements AND, the element NOT, the delay element and the trigger, the output of the first element AND through the element NOT, and the output of the second element AND through the Eiderm element, they are connected to the corresponding trigger inputs, the inverse output of which and the output of the first element AND are the first and second outputs of the signal conditioner, the first inverse input of the first element AND and the first direct input of the second element AND gel, the second nversny input of the first AND gate and a second input of the second straight element and are combined and input vtorni formers, the third input of which is the forward input member of the first IM

The invention relates to computing and is intended to investigate the characteristics, transmission of digital information under the influence of impulse noise.

A device for simulating a signal transmission path is known, comprising a register, a keypad block, the first inputs and which are connected to corresponding outputs and inputs of a register, a block of binary adders, the inputs and outputs of which are connected to the second outputs and inputs of a block of a typed field, first triggers, inputs KOTOJWX connected to the third outputs of the keypad, and the outputs of which through low-pass filters are connected to the first inputs of the modulators, the outputs of which through the second trigger are connected to the output of the device, and watts The third inputs are connected to the outputs of the separation units. the front and rear edges of signals whose inputs through a differentiating circuit are connected to the fourth output of the keypad and the input bus of the device ij,

A device for simulating discrete transmission channels is known.

information containing a random signal sensor, the first and second random pulse generators, the setting device, the trigger and the element I, the device’s input bus being connected to the sensor inputs of random signals, the first and the SECOND generator; the random pulse tori, the first and second trigger inputs are connected to the output of the first generator, through the master device with the second input / second random generator and with the output of the second Generator, and the output is connected to the first input of the element And, the second input of which is connected to the output th sensor random signals, and output - with output line H of the device.

A disadvantage of the known devices is that when analyzing the transmissions of digital signals over a data channel, the effect on them of only fluctuation disturbances is taken into account, which reduces their functionality.

The closest to the invention in terms of a set of functional and structural features is a device for modeling discrete information transmission channels, comprising a trigger, a comparison unit, first, second and third OR elements, first and second elements of time delay, first, second, third and fourth equivalence elements. , the first and second functional converters, a clock generator, the input of which is connected to the input bus of the device, a sensor of random signals and a generator of random pulses one is connected to the sensor input of random signals and the output of the generator of pulsed pulses, the first output is with the first inputs of the first OR element and the time delay element and the first and second equivalence elements, and the second output is with the second input of the first OR element . the inputs of the second delay element and the third and fourth equivalence elements, the output of the first element OR is connected to the first inputs of the first and second functional converters, the second inputs of which are connected to the sensor output of random signals, the output of the first functional converter connected to the second inputs of the first and third elements equivalence, the output of the second functional converter is connected to the second inputs of the second and fourth elements of equivalence, the first and second inputs of the second ale This OR is connected to the outputs of the first and fourth equivalence elements, and the output is connected to the first output bus of the device and the first input of the comparison unit, the output of which is connected to the second output bus of the device and through a trigger to the third and fourth output buses, and the second input to p that output bus and the output of the third ORenta, the first and second inputs of which are connected to the outputs of the third and second elements of equivalence, respectively, and the outputs of the first and second delay elements are connected to the sixth and seventh outputs E tires device respectively 3J. However, signals carrying information in the communication channel are subject to two types of interference — operational noise and impulse ps “ex. The appearance of impulse noises is of a casual nature; in addition, parameters, eg, distributions of amplitude and noise, intervals between with negative crosses, the occurrence of positive and negative amplitudes, are distributed according to random laws. Due to interference, many Parameters are described and, therefore, it is often impossible to formulate the atomic law of the influence of impulse interferences on information system.

The known device does not allow an e-assessment of the impact of pulsating nature on the information signal, which limits its functionality (an assessment of the influence data is necessary to ensure optimum use of: the communication channel capacity).

The purpose of the invention is to expand the functionality of the device by reproducing the mode of action of impulse noise on the transmitted signal, I,.:,. :

This goal is achieved by the fact that in the device for modeling

5 discrete information transmission channels containing a random signal sensor, a random pulse generator, a comparison unit whose outputs are the first group of device outputs, a clock generator whose input is a device start input, a frequency divider added, a sensor of interference intervals , a psmeh duration sensor, an interfering sign sensor, an amplitude sensor P9mehi, a control unit consisting of a series-connected element And and a shift register, the discharge of which is.

0 is connected to the inputs of the OR element, and an interfering unit that contains two reversible counters, two decoders, two groups of AND elements, an analog-to-digital converter, an OR element, four AND elements, a trigger and a signal conditioner, the first inputs of the first and second elements AND combined, the second input of the first element And the inverse input of the second element And combined and connected to

0 to the first input of the signal conditioner and the output of the first decoder, connected input No. 1 to the corresponding bit of the outputs of the first reversible counter, the input of which is connected to the output of the first And element, and the bit inputs of the first group, the first inputs elements and the first and second groups

0 are pairwise connected and connected to the corresponding output of the analog-digital converter, the input of which is connected to the output of the OR element, outputs of the elements of the second group are connected respectively to the bit inputs of the second reversible counter, which subtracts the input of the second output And and the bit outputs of the second reversible counter are connected respectively to the inputs of the second decoder, the output of which is connected to the first input of the trigger and the second input of the signal conditioner, the third input of which о is connected to the direct trigger output and the first inputs of the third and fourth elements AND, the second inputs of which are connected to the first output of the signal conditioner, and the third inputs are the third of its and fourth elements AND are combined, the output of the generator of clock pulses is connected to the input of the element AND block the control and the input of the frequency separator, the corresponding input of the OR element of the control unit is connected to the output of the frequency divider, the first input of the start of the random pulse generator and the first input of the first element AND of the shaping unit and, the output of the OR element of the control unit is connected to the input of the random signal sensor, the output of which is connected to the second start input of the random pulse generator and the first start inputs of the noise interval sensor, the noise duration sensor, the noise sign sensor, and the noise amplitude sensor, whose data read inputs Connect to the second output of the signal conditioner of the interfering unit and the second input of the control unit AND, and the outputs of the interval sensors. between interference, duration of interference, s-naka and. the amplitudes of interference are connected respectively to the first and second inputs of the element OR of the block forming interference, the third input of the third element AND of the block forming the interference, the second input of the block trigger,. the formation of interference, the outputs of the third and fourth elements And which are connected to the first and second inputs of the comparison unit, respectively, the output of the first bit of the shift register of the control unit is connected to the second input of the sensor start of the interference intervals, the second inputs of the elements And the first group of the interference generation unit, the output of the second the bit of the shift register is connected to the second input of the sensor for the interference duration sensor and the second inputs of the elements of the second group of the block of shapes anMeMech, the output of the third bit of the register shift is connected to a second input of the mark start interference sensor, the fourth bit output and a second input connected J sensor startup noise amplitude and the third and fourth inputs of unit sravieni pervm connected respectively to the second output and the random pulse generator and a second group are output devices. In addition, the signal conditioner contains two elements AND, the element NOT, the delay element and the trigger, the output of the first element AND through the element NOT, and the output of the second element AND through the delay element are connected to the corresponding trigger inputs, the inverse output of which and the output of the first element I the first and second outputs of the signal conditioner, respectively; the first inverse input of the first element AND and the first direct input of the second element AND are combined and are the first input of the former, the second input of which is the combined second inverse of the first element AND and the second direct input of the second And element, the third input of the former the first element And, FIG. 1 is a diagram of the device in FIG. 2 is a functional block diagram of the control unit; in fig. 3 is a functional block diagram of the formation of interference; in fig. 4 shows timing diagrams explaining the interference signal distortion process; in fig. 5 is a functional diagram of the signal conditioner of the interference shaping unit. The device contains a 1-start input, 2 clock pulse generator, frequency divider 3, which is a feedback counter counting circuit up to five, control block 4, random pulse generator 5, which forms the information sequence of zero and single signal signs in the communication channel, the block of formation of interference, at the outputs of which a pulsed disturbance of positive or negative polarity is formed, the sensor 7 of random signals forming a voltage at its output, the value of which It is evenly distributed in the interval from 0 to 1, the sensor 8 is the interval of interference, designed to set the random magnitude of the distance to two adjacent impulse noise, the sensor 9 of the duration of interference, the sensor 10 of the sign of interference, the sensor 11 amplitude of interference, block 12 comparison, designed to determine the case distortion of impulse noise of a single or zero attribute of the information sequence, the first group of outputs 13 and 14, designed to record the number of distortions and zero signs of the information sequence telnosti, a second set of outputs 15 and 16 are intended for recording the total number peredavaemlh a single communication channel and null signs information sequence. Control unit 4 (Fig. 2) contains bit outputs 17, element AND 18, element OR 19, shift register 20. BLOCK 6 of forming interference (FIG. 3) contains the first 21, second 22, third 23, fourth 24 AND elements, respectively, the first 25 and second 26 reversible counters, the first 2 7 and the second 28 decoders, driver 29, trigger 30, OR element 31, the analog-to-digital converter 32, the first 33 and the second 3 group of elements AND, Sensor 8 intervals between interferences and the sensor of duration of interferences can be implemented, for example, in the form of a functional non-linear pre-exponent-type exponent with control by input and output using elements I. Sensor 10 g Such interference can be performed, for example, in the form of a three-in-1 element AND and a comparison circuit of a signal with a zero potential (n shown). The sensor, 11 amplitudes of interference can be made in the form of a series of connected nonlinear transformers of the type of exponent and a comparison circuit with control of the input and output of results Through AND elements (not shown). The shaper 29 of the signal block of the formation of interference (FIG. 5) contains the first element AND 35, the second sJie ment AND 36, the element NOT 37. the trigger 3S delay element 39 delays the input signal for two periods of the frequency of the 2 pulses. A device for simulating discrete information transmission channels operates as follows. Upon start-up of the generator 2 clock pulses, the starting potential is applied. The generator 2 gives out its output qo a sequence of rectangular pulses with a frequency 4, which is fed to the input of the divider; frequency and the first input unit 4 controls. Moreover, the divider 3 frequency divides the frequency f by. From the incoming :, the house of each multiple of five pulses from generator 2 at the output of divider 3 will be a pulse. In block 4 of the control (in Fig. 2), element I 18 is opened, since at the second input of block 4 there is a resolving potential from the first output of the block b forming itO mechanical. From the first impulse of the generator 2, the SDRD resistor 20 is activated and on its first bit output (Jy has a potential that is connected to the corresponding outputs of control unit 4. The signal from the first output of block 4 triggers a sensor 7 of a random number, and the potential taken From the output of sensor 7, TEMT has a uniform distribution on the shaft from zero to 1. The input of the reiiiierator 5 random pulses is still closed, so the potential of the detector 7 is fed to the first input of the sensor 8 and te1 va1d8 between the noise, the second and inputs have At this moment of time, the disruptive potentials from the interfering block b and the control block 4. The voltage determining the length of the distance between interferences from the output of sensor 8 goes to the second input of the block forming interferences. Through the OR 31 element, the potential generated by sensor 8 is supplied to analog-to-digital converter 32, which generates a code defining the duration of the distance to the next impulse noise in the given numerical time units, in the communication channel. This code from the outputs of the analog-digital converter through the elements opened at the sixth input-AND 33 with the potential from the output of the first bit of the register 20 of the control unit is written into the reversing counter 25. By the second pulse from the generator 2 clock pulses at the second output of the shift register 20 appears the potential that is applied to the first input and to the second bit output of control unit 4. The potential of the c-first output of block 4 again triggers the sensor 7 of a random number, and the potential developed by it this time is fed only to the first input of sensor 9 of the interference duration, the second and third inputs of which have resolving potentials from the first output of block b and the second discharge block 4 output. Sensor 9 for the duration of interference produces a potential proportional to the duration of the impulse interference. On the third impulse of the generator 2, the potential appears at the third output of register e 20 of the control unit 4, at the first and third discharge outputs 17 of which there will be potentials. From the potential at the first output of block 4, sensor 7 is triggered for the third time again, and the potential from its output is fed to the first input of sensor 10 of the interference sign, the second and third inputs of which have resolving potentials from the first output of block b and the fourth output of block 4. At the output of the sensor 10 will be zero potential, if the interference signal has a positive sign. If the sensor 7 is abunded by a single potential, this corresponds to a negative interference. The sign of impulse noise developed by sensor 1B (negative potential or positive interference) in the form of a zero positive potential is applied to the solid input of the jamming unit b. For the fourth pulse of the generator 2, the pulse will be at the fourth output of the register 20, therefore,

on the first and fourth bits of the output 17 of block 4 there will be potentials. The potential from the first output of block 4 triggers sensor 7, and the random voltage from its output is supplied to this clock only at the input of sensor 11. Amplitude, interference, on the second and third inputs of which there are resolution potentials pt of the first output of block 6 and n the output of block 4, respectively.

Sensor 11 detects a random voltage value of the amplitude of a pulse noise. If the cam 11 generates a single signal, which corresponds to the exceeding the maximum trigger level of the receiver's threshold device, then the trigger 30 of the block b is transferred to the single state. If the amplitude of the interference is such that it does not distort the transmission. signal, i.e. the amplitude is less than the threshold level, then the sensor 11. Fails a zero potential and trigger 30 remains in a single state.

Comparison unit 12 implements a comparison of the arising interference, either positive or negative polarity, with the information signals 1 and O, with 1 being transmitted by impulse, a-O - by the absence of impulse in the channel with & zi The timing diagram (in this case, the representation of the overlap of the potech on the information signal is shown in Fig. 4. Obviously, 1 is distorted, if there is a pulse interference at the same time and with an amplitude greater than that of the receiver, i.e. a greater 0.5 voltage signal Uc. is induced in place (a time VOf if, at this moment, time is interfered with by a positive field of magnitude and with an amplitude greater than

O, 5Uc. Existing from these assumptions, further consideration is given to the operation of the device.

In between the end of the fourth pulse of the generator 2 and the beginning of the fifth pulse, the signal generator j29 is activated and the potential disappears at its second output. It happens as follows. From the signals from the first or second outputs, element 36 is triggered, and after a time equal to two cycles of operation of generator 2, the trigger 38 is transferred to the unit state; there will be no potential at its zero output. The lack of potential at the first output of the unit 6 prohibits the operation of the control unit 4 and sensors 8-11 "

With the appearance of the fifth pulse, and subsequently a multiple of five

pulse, the output of the generator 2 triggers a frequency divider 3, and its output will be pulses that determine the time units for the appearance of information pulses for the generator TOpa 5 random pulses and the appearance of interference in the communication channel for block 6 of the interference. ,

The output pulse of the divider .3 is fed to the second input of control unit 4, and through the element MLN 19, the first output of unit 4, the sensor 7 is started. In this case, the random voltage generated by it is applied only to the second input of the generator (torus 5. Random signal generator generates an information sequence of zeros and units, and with a unit of information there is a potential at the first output, and at zero information there is a potential at the second generator 5.

: At the same time, the pulses of the divider 3 are fed to the first input of block 6 and through the open first element I 2 are fed to the input of the first reversible counter 25, counting to zero the number available in it, determining 19 the distance before the occurrence of interference in the KaHcLTie connection . As soon as this number is read, i.e. in the counter 25, there will be zero, then the following triggers: the decoder 27, and its output will have a zero potential, which closes the element And 21, opens the element And 22 and opens the element And 35 of the signal conditioner 29, i.e. it is considered that the channel; communication was interrupted with a duration; the code of the magnitude of which is recorded in the second reversible counter 26 i In this case, the third element, element 23, is disconnected from the second output of the signal generator 29 if the positive sign is interrupted and its level exceeds the level of threshold device or the fourth element AND 24 / if the interference is of a negative sign and its level meets the conditions set out for the 1st condition. The pulses of the divider 3 are now fed to the input of the counter-input sensor 26, reading its code to zero. Moreover, all the time when the counter code 26 is read, the potential at the second or third outputs of block 6 will be at a level of interference greater than the threshold level. As soon as a zero combination appears in the counter 26, the decoder 28 is triggered and flips the trigger 30 to the zero position, which is considered as the moment of termination (loss) of interference in the communication channel.

In addition, in the signal generator 29, the signal at the output of the element 35 disappears, the signal at the output of the element 37 appears, and the trigger 38 is moved to the zero state.

a signal appears at the first output of the interference generating unit 6, and the described interference formation njpouecc in the communication channel by the control unit 4, the sensor 7 and the sensors 8 - 1L repeats.

Comparison unit 12 establishes the effect of interference on the informational sequence of zeros and ones in the following way. Beli on the third entrance comes potential from the first. generator output 5, corresponding to the unit in the communication channel, then. Obviously, this unit can be suppressed by negative interference of greater amplitude than the threshold of the receiver. That is, if a potential arrives at the Second input from the third output of block 6, then a unit of information is suppressed, and instead of the unit At -. The driver accepts a null information symbol. Obviously, a positive signal in this case does not change the reception of the unit (information symbol. If the fourth input is supplied from the second output of the generator 5, then this corresponds to the presence of zero signal in the channel, which can be distorted and incorrect recognized by the receiver as a unit with positive interference with an amplitude greater than the receiver threshold, i.e., if at this moment in time the first input receives a potential from the second output of block 6, then this is considered by comparison unit 12 as zero distortion. Obviously, a negative interference does not affect the receiver's recognition of the zero signal feature.

When a single information sign is distorted at the first output 13, and when the zero sign is distorted, the second output 14 will have the potentials that are sent to the recording devices, the data on the number of zero and single information signs are removed from the third 15 and the fourth 16 outputs.

0

The technical and economic efficiency of the device according to the known is estimated as follows.

In a known device, a flux disturbance is investigated 5 with flu, causing distortion if its energy suppresses a single signal or induces it instead of zero. In the proposed device, the effect of impulsive noise on the information

0 sequence, which allows to significantly improve the quality of information transfer.

Indeed, without assessing the influence of impulsive noise, we choose

5, the coding method is obviously not optimal, and the code length Oi in this case will be greater than the optimal length n, having an estimate of the influence of impulse noise, we choose the code optimal

0 length P. This will allow to increase the speed of transmission to the Communication channel from the value of R to a greater value of R2 to transmit more information, to increase the efficiency

5 utilization of the communication channel. The effectiveness of the proposed device may be evaluated by the formula

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Claims (2)

1. DEVICE FOR SIMULATING DISCRETE INFORMATION CHANNELS, comprising a random signal sensor, a random pulse generator, a comparison unit, the outputs of which are the first group; the device’s outputs, the clock generator, the input of which is the device’s start-up input, characterized in that, in order to expand the functionality by reproducing the mode of influence of pulsed noise on the transmitted signal, it additionally contains a frequency divider, a sensor of the intervals between the noise, an interference duration sensor , an interference sign sensor, an interference amplitude sensor, a control unit consisting of AND elements connected in series and a shift register, the bit outputs of which are connected to the input s OR and noise shaping unit comprising two reversible counter, two decoder, the two groups of AND gates, analog-to-digital converter, an OR, a four?. And the element And, the trigger and the signal conditioner, the first inputs of the first and second elements And combined, the second input of the first element And _{x the} inverse input of the second Element And · combined and connected to the first input of the signal conditioner and the output of the first decoder connected to the inputs of the corresponding the outputs of the first reversible counter, subtracting the input. which is connected to the output of the first AND element, and the bit inputs are connected respectively to the outputs of the AND elements of the first group, the first inputs of the AND elements of the first and second of the first group are paired and connected to the corresponding output of the analog-to-digital converter, the input of which is connected to the output of the OR element, the outputs of the And elements of the second group are respectively connected to the discharge inputs of the second _ counter, subtracting the main input of which is connected to the output of the second AND element and the bit outputs of the second reversible counter are connected respectively to the inputs of the second decoder, the output of which is connected to the first input of the trigger and the second input of the signal conditioner, the third input of which о is connected to the direct output of the trigger and the first inputs of the third and fourth elements AND, the second inputs of which are connected to the first output of the signal generator, and the third inputs of the third and fourth elements AND are combined, the output of the clock generator is connected to the first input of the element AND of the control unit and the input frequency divider, the corresponding input of the OR element of the control unit is connected to the output of the frequency divider, the first input of the random generator start (pulses and the first input of the first element AND of the formation unit exe, the output of the OR element of the control unit (connected to the input of the random signal sensor, the output of which is connected to the second input of the random pulse generator and the first inputs. start of the interval between interference sensor, the duration of the interference sensor, the sign of the interference sign and the sensor is the interference amplitude, data read input which are connected to the second output of the signal conditioner of the interference generating unit and the second input of the AND element of the control unit, and the outputs of the sensors of the intervals between the interference, duration of the interference, sign and amplitude and the interference is connected respectively to the first and second inputs of the OR element of the interference generating unit, the third input of the third element AND the interference generating unit, the second input of the trigger of the interference generating unit, the output of the third and fourth elements And which are connected to the first and second input of the comparison unit, respectively, the output of the first the discharge category of the shift register of the control unit C07 is single with the second input of the start of the sensor of the interval between the noise, the second inputs of the elements And the first group of the block generating interference, the output of the second the shift register is connected to the second input of the interference duration sensor and the second inputs of the elements of the second group of the interference generating unit, the output of the third category of the shift register is connected to the second input of the interference sign sensor, the fourth discharge output is connected to the second input of the sensor start, the interference amplitude, and the third and the fourth inputs of the comparison unit are connected respectively to the first and second outputs of the random pulse generator and are the second group of outputs of the device. 2. The device according to π. 1, characterized in that the signal conditioner contains two AND elements, an NOT element, a delay element and a trigger, an output of the first AND element through an NOT element, and an output of the second AND element through a delay element connected to corresponding inputs of the trigger, whose inverse output and the output of the first element And are respectively the first and second outputs of the signal conditioner, the first inverted. the first input of the first element And and the first direct input of the second element And are combined and are the first input of the shaper, the second inverse input of the first element And and the second direct input of the second element And are combined and are the second input of the shaper, the third input of which is the direct input of the first element I.