SU1048581A1 - Device for clock synchronizing of process sequences - Google Patents

Abstract

1. TACT SYNC-DEVELOPMENT: CHRONIZEDIES OF Pseudo-accidental sequences, containing the first multiplier, the second multiplier connected in series, the first integrator, the threshold block, the search control unit, and the pseudo-random generator fncnj, as well as sequential / cusp-strings, as well as sequential / cusp-strings, as well as consecutively; main correlator and torus. controlled oscillator-pulse pulses, the next correlator, the torus contains the third and fourth multiply; 1and the second integrator, the output of which is the output of the next correlator, the first input: of which is the first input of the third multiplier, of which And so with the fact that, in order to reduce the time of entry into synchronism and increase the tracking of the time delay of the segment of the information flow of signals of the two-character alphabet modulated by a pseudo-random sequence, the connected reference driver, de: LITEL and the second switch, as well as two delay elements and the H1 filter, the input of which is connected to the output of the second multiplier, and the output of the low-pass filter through the first input KQ of the next correlator and directly to the first input, the first switch and the third input. The next correlator of the torus, to the fourth input of which Through the second element: 3-delays the second output of the first switch is connected, to the second input of which, e deSh1tel and second inputs connected to the output of the generator SRP vtorogokommutatora, to the second; and the third inputs of which are connected, respectively, to the output of a controlled clock pulse generator; and the second output of the search control unit, while the output of the PSP generator is connected to the first input of the first semi-igniter, the second input — which is the input of the device, and the output of the first , the multiplier is connected to the input of the driver of the reference signal and the first input of the second multiplier, to the second input of which the output of the reference signal amplifier is connected, and the subtractor is inserted into the next corrector; Odes of the third and fourth multipliers are connected, the output of the subtraction unit is connected to the input of the second integrator, the second input of the third multiplier, the first and second inputs of the fourth multiplier are the second, third and fourth inputs of the next correlator iMH respectively . Eo 2, The device according to claim 1, in order to reduce the time of entry into the synchronization: the base li of increasing the accuracy of tracking the delay time of the information flow of the signal flow. a four-character alphabet modulated by a pseudo-random sequence, a sequentially connected phase shifter, a fifth multiplier, a third integrator, a second threshold unit, the output of which is connected to the second input of the search control unit, as well as a third switch, third and fourth electrons are entered.

Description

The second and second low-pass filters, the output of which is connected via the third delay element to the fifth input, the next k1 switch, and directly to the first input. the third switch and the sixth input of the servo correlator, to the seventh and eighth inputs of which are connected directly and through the fourth delay element the first and second outputs of the third switch, to the second input of which the output of the second switch is connected, while the output of the reference signaling device is connected to the input of the phase shifter, and the output of the first multiplier is connected to the second input of the fifth multiplier, and the sixth and seventh multipliers, whose outputs are connected The third and fourth inputs of the subtractor, the first and second inputs of the seventh multiplier are the fifth and seventh inputs of the next correlator, the sixth and eighth inputs of which are the first and second inputs of the sixth multiplier, and the output of the fifth multiplier is connected to the input of the second lowpass filter.

The invention relates to radio communications and can be used in correlation tracking receivers of digital information related to secret communication systems, telemetry — television, control, etc. — using pseudo-random modulation as two and four signals. an ex-alphabet character, transmitted by an 11X through a multi-path path with variables napaMexpaM and segments of the information flow of these signals ,. A clock synchronization device of a pseudo-random sequence is known, containing a series-connected multiplier, an integrator, a threshold unit, a switch, a controlled clock generator and a pseudo-noise generator connected to the collector, and the pseudo noise noise outputs are connected to the second input of the search control unit. the generator is connected respectively to the reference inputs of the multiplier and the following correlator of the torus Gl3. However, the known device has a large time to synchronize. The closest technical solution to the invention is a device comprising a first multiplier, a second multiplier in series, a first integrator, a threshold unit, a search control unit, and a pseudo-noise generator, as well as a switch controlled by rerfepaTOp clock pulses, and the next correlator containing the third and fourth multipliers, the outputs of which are connected to the inputs of the adder, the code of which is connected to the input of the second int the vendor, as well as the third and fourth integrators. The disadvantages of this device are considerable synchronization time and low accuracy of tracking the time delay. The aim of the invention is to reduce the synchronization time and improve the accuracy of tracking the time delay of the information segment: the current of the two-character alphabet. Modulated pseudo-random sequence; reducing the time to synchronization and improving the accuracy of tracking the time delay of the information flow segment of the four-character alphabet signals modulated by a pseudo-random sequence. For this, a known clock synchronization device comprising a first multiplier, a second multiplier connected in series, a first integrator, a threshold unit, a search control unit and a pseudo-random sequence generator (PSP), and also a first switch connected in series, a follower correlator and a controlled generator clock pulses, the tracking correlator containing the third and. the fourth multipliers and the second integrator, the output of which is the output of the next correlator, the first input of which is the first input of the third multiplier, are connected in series to the reference signal conditioner, divider and second switch, as well as two delay elements and a low-pass filter to the input the output of the second multiplier is connected, and the output of the low-pass filter through the first delay element is connected to the second input of the tracking correlator and directly to the first input of the first comm to the third input of the next correlator, to the fourth

whose input through the second delay element is connected, the second output of the first switch, to the second input of which, as well as the second inputs of the splitter and PSP generator, the output of the second switch is connected, to the second and third inputs of which are connected, respectively, the output of the controlled clock generator and The second output of the search control unit, wherein the output of the PSP generator is connected to the first input of the first multiplier, the second input of which is the device input, and the output of the first multiplier is connected to the input form the world of the reference signal and the first input of the second multiplier, the output of the reference signal is connected to the input of which, the subtractor is inserted into the next correlator, the inputs of the third and fourth multipliers are connected, and the output of the subtractor is connected to the input of the second integrator, wherein the second input of the third multiplier, the first and second inputs of the fourth kernel ring are, respectively, the second third and fourth inputs of the next correlator. In addition, a fifth phase multiplier, a third integrator, and a second threshold unit, the output of which is connected to the second first input of the search control unit, are introduced into the known device, and the third switch, the third and fourth delay elements, and the second a low-pass filter, the output of which through the third delay element is connected to the fifth input of the following correlator, and directly to the first input of the third loudspeaker, attor and the sixth input of the following correlator, to the seventh and eighth inputs The first is connected directly and via the fourth delay element to the first and second outputs of the third switch, to the second input of which the output of the second switch is connected, while the output of the reference signal generator is connected to the input of the phase shifter and the output of the first multiplier for the keys to the second input of the fifth multiplier, and the following correlator is additionally introduced by the sixth and seventh interceptors, the outputs of which are connected to the third and fourth inputs of the subtraction unit, with the first and second inputs of the seventh feather miozhitel are fifth and seventh inputs servo correlator, sixth and eighth: inputs which are the first and second inputs shes; order multiplier,; and the output of that multiplier is connected to the input of the Second low-pass filter. .

FIG. Figure 1 shows the structure of the electrical circuit of the device | Clock synchronization of pseudo-random sequences of the information flow of signals of the two-character alphabet; in fig. 2 - the same for signals of the four-character alphabet; in fig. 3 is a timing diagram of the operation of the device shown in FIG. one.

0

The clock synchronization device of pseudo-random sequences (Fig. 1 contains the first multiplier 1, the second multiplier 2, the first integrator 3, the next 5 correlator 4, contains the third multiplier 5, the fourth multiplier 6, block 7 subtraction, the second integrator 8, the threshold block 9, search control unit 10, Göner-Tor 11 pseudo-random sequences (PSP, first switch 12, second switch 13, control of 14 clock pulses, low-pass filter 15, reference driver 16, first

5 delay element 17, the second delay element 18, the divider 19.

The clock synchronization device of the pseudo-random sequences (Fig. 2) contains the first multiplier 1, the second multiplier 2, the first integrator 3, the next correlator 4, containing the third multiplier 5, the fourth multiplier 6, subtraction unit 7, the second

5 integrator 8, threshold block 9, search control block .10, SRP generator 11, first switch 12, second switch 13, controlled clock generator 14 clock pulses, first filter

15 bass, driver 16. the reference signal, the first delay element 17, the second delay element 18, divider 19, the fifth multiplier 20, the phase shifter 21, the trailing correlator 4. further comprises a sixth multiplier 22, the seventh multiplier 23, the third integrator -24, the second threshold unit 25 ., the third switch 26, the second low-pass filter 27, the third delay element 28,

0 the fourth element of the holding 29.

The device (Fig. 1) works as follows.

At the first moment of time, the second switch 13 is connected to the second

5 input generator. 11 PSP and the second input of the first switch 12 output of the controlled oscillator 14 clock pulses. Under the influence of a clock pulse controlled generator

About 14 clock pulses, the SRP generator generates at its output a pseudo-random forward sequence of circular pulses, and the first switch 12, triggers at times, each time point5

Kam, lying on the boundaries and in the middle part of the intervals of generation of elements, a random code, switches the input of the second delay element 18 and the first input of the tracking correlator 4. to the output of the low-pass filter 15,

The pseudo-random pulse sequence formed at the output of the SRP generator 11 multiplies in the first multiplier 1 with the oscillation of the input radio signal sequence, resulting in, for example, phase manipulation of the oscillation of an information flow segment containing one or more information signals of a two or four characters alphabet, generates, at the output of the first multiplier 1, a sequence of radio pulses, which, when multiples of the value of SlS, where is the duration of the pseudo-random element edovatelnosti) mismatch between x sep yuntom information stream signals manipulirovannrgo phase pseudorandom sequence and the reference PN sequence corresponds to the sequence of radio signals that are obtained by phase shift keying waveform selected segment information stream source information sequence signals of one of the cyclic permutations of the original sequence psevdosluchs1ynoy. When there are mismatches close to the value multiple of the TG, the sequence of radio pulses received at the output: 1e of the first multiplier 1 is distorted by crushing, the duration equal to the fractional part of the mismatch TO,

Using the reference harmonic oscillation supplied to the second input of the second multiplier 2 and formed by the shaper of the reference signal from the output signal of the first multiplier 1, in the circuit (synchronous detector containing serially connected second multiplier 2 and low-pass filter 15, the output signals of the first multiplier 1 high frequency carrier.

The sequence of video pulses received at the output of the filter 15 of the lower clock comes through the first delay element 17 to the second and the NS of the third input of the following correlator 4, and through the first switch 12, depending on its condition, to the first input of the following correlator 4 or the input of the second delay element 18 and further to the fourth input of the next correlating torus 4,

At the output of the following correlator j4, a voltage is allocated that is directly proportional to the fractional part of the mismatch Tp, obtained as a result of the operation of multiplying the voltages fed to the first and second inputs of the following correlator 4, operation of the voltage multiplying, third and fourth. inputs of the following correlator 4, subtraction implemented using the third and fourth multipliers 5 and 6 of one multiplication result from another and integration using the second integrator 8 as a result of the subtraction allocated for the output of subtraction unit 7.

 When choosing the delay time of the first and second delay elements

17 and 18 should be borne in mind that

. the deviation of the delay time of the first and second delay elements 17 and

18 of the optimal value of the EG

 p, 25f, does not cause a shift in the temporal position of the discriminatory characteristics of the tracking correlator 4, but it leads to an undesirable narrowing of its working area.

The voltage obtained at the output of the servo correlator 4 adjusts the frequency of the pulses of the controlled oscillator to 14 clock pulses, which ensures the synchronization of the generator 11 of the clock band to the clock frequency. At the same time, using the search control unit 10, the phase of the information signal flow segment is manipulated by the phase with a pseudo-random sequence, the positive outcome of which is in the case of using a pseudo-random intrapulse phase shift keying. There is a correlation peak at the output of the signaling correlator consisting of the second multiplier 2 and the first integrator 3 connected in series. The pulse of the correlation peak triggers the threshold unit 9, the output voltage of which causes the search unit 10 command to stop the search procedure.

The rule of making a decision about the positive outcome of a phase of that information flow (Signals manipulated in phase by a pseudo-random sequence if there are several information packets in a segment is reduced to detecting a code sequence belonging to a certain set of code sequences received using the threshold block 9 the first input of the second multiplier 2 radio; 1 parcels, and the carrier in itself entered 5 transfer information about the temporary position of the pseudo random code phase shift keying.  In this case, the decision on the search result is made by the own device of the search control unit - detector, the code sequence belonging to a given set of redundant code - code sequences. information.  Entering redundancy in the information sequence is a necessary condition for the realization of segments of information signals, of which the composition is; code combinations containing information about the position of the random pseudo-random code of the phase-shift manipulation of the information sequence.  As a result of the synchronization. clock frequency and detection; phase of the pseudo-random code of the phase manipulation of the signal or segment of the information sequence of signals in the first. of the multiplier 1, the pseudo-random manipulation of the information sequence is removed, leading to an expansion of the frequency band occupied by the interference spectrum and, in practical important cases.  to the narrowing of the band occupied by the spectrum. useful composition for input actions; hesitation.  These changes in the input spectrum at the output of the first. the multiplier 1 provides high noise immunity and, reliably, the selection by means of the formation of the reference signal body 16 of the carrier frequency of the signal.  Phase detection The pseudo-random sequence of the phase manipulation of the signal is accompanied by the supply of a command signal generated at the second output of the search control unit 10 to the third (controlled input of the second switch 13) The second switch 13 disconnects from the second, 176-second 11 (second the entrance. the first cocmouthacher 12 is controlled-oscillator output 14, clock pulses and connects the output of divider 19, through which, the formation of a pulse is carried out; clock  Synchronization from the reference signal allocated at the output of the formi 16 reference signal.  At this moment, the clock frequency adjustment of the pseudo-random sequence of phase modulation and the frequency of the carrier oscillation will occur from a single voltage of its own discriminator, formed, tel.  sixteen.  the reference signal, which ensures high accuracy of tracking the time delay of the received signal length.  For nposeji uniqueness in determining the delay, the second switch 13 may.  repeatedly changing the input oscillation of the clock pulses supplied from the outputs of the controlled oscillator 14 clock pulses and divider 19 to the second input of the SRP generator 11 and the second input of the first switch 12.  Resetting the divider 19 to a state in which a temporary combination of clock pulses is provided. the frequencies allocated at the outputs divides the 19 and the controlled generator 14 of these 1 pulses is provided by the feed of the pulses to the second input of the divider 19 from the output of the second switch-13.   ,,  .   As the nepBOfx) and the second delay elements 17 and 18, the shift registers can be used. As the first multiplier 1, a phase handler containing two keys can be used, to the inputs of which an input oscillation is fed, and to the second non-inverse input of the first key and a second inverse input of the second key , a voltage is supplied from the output of the generator PSP 1, the output of the first key is connected via an inverse cascade with the first ID of the adder, the output of which is the output.  multiplier 1, and the second input is connected to the output of the second key.  An exemplary view of the radio input to the device is the second input of the first multiplier 1, shown in FIG.  3q.  Here, the signs + and the conditional form show the differences in the informative parameter of the transmission signals of the information symbols O and 1.  FIG.  3bG displays the type of pulses on.  in the output of the generator 11 PSP; - see.  3 - the same, at the third input of the following correlator of torus 4; in fig.  3t: - the same, at the fourth input of the tracking correlator 4; on / fig.  . 3 - the same, at the output of the fourth multiplier 6; in fig. .  Sv is the second input of the following correlator of torus 4; in fig.  Ц--TJO, on the first input of the tracking correlator 4; in fig.  3- - the same, at the output of a tretr of his pericuteral 5; in fig. For the same, at the output of block 7 subtraction.  . g. “T. ,, c „,, Device (FIG.  2) works with. let's guess the way.  , At the first moment in time the second.  the switch 13 connects to the second inputs of the generator 11 of the SRP, the first switch | and 12 and the third Switch 26, the output of the controlled generator is 14 clock pulses.  Under the influence of the clock pulses of the controlled generator 14 clock pulses geyrator.  11 PSP forms at its exit. the pseudo-terminal sequence of rectangular pulses, the first commutator 12, is triggered at the instants of time corresponding to the time points lying.  at the borders and in the middle part of the pseudo-random code generation elements, it produces a trans.  switching on the input of the second delay element 18 and the first input of the following correlator 4 to the output of the first low-pass filter 15 and the third switch 26, whose operation is similar to that of the first switch 1, switches the input of the fourth element, delay 29 and the seventh input of the next correlator 4 on the output of the second filter 27 low frequencies.  A pseudo-random impulse sequence, generated at the output of the SRP generator 11, multiplied in the first multiplier 1 with a fluctuation of the input p6c of the radio signal sequence resulting from, for example, phase manipulation of the oscillation of an information flow segment containing one or more information letters of a four-letter alphabet that contains one or several information letters of a 4-letter alphabet. at the output of the first multiplied 1 sequence. the radio impulse duration, which, when multiples of t | 0 (the duration of the pseudo-random sequence element of the mismatch between the information flow segment, the signals manipulated in phase by the pseudo-random sequence and the reference pseudo-random sequence, corresponds to the sequence of radio signals received by the resultant phase signal of a given number of inforbidionic packages of the initial information flow of one of the cyclic permutations of the initial pseudo-random sequence quently.  When there are mismatches close to the / T multiple of a TG, the pseudo-case of a sequence generated at the output of the first multiplier 1 is distorted by fragmentation equal to the fractional part of the mismatch.  With the help of the harmonic oscillation, supplied to the second input of the second multiplier 2 and formed by the shaper 16 of the reference signal from the output signal of the first multiplier 1, in a circuit (synchronous detector) containing serially connected second signals. The multiplier 2 and the first 15 low-pass filter remove the output signal of the first pair of four-digit alphabet characters of the first multiplier 1 wax carrier, while the signals of the second pair of even-fech alphabet do not pass to the output of the first 15 frequency filter. reference harmonic oscillation supplied from the output of the driver.  16 of the reference signal through the phase shifter 21, which is the phase rotation of the high-frequency harmonic oscillation by 7 gG / 2 rad, to the first input of the multiplier 20, in the circuit (second synchronous detector) containing the fifth connected transducer 20 and the second low-pass filter 27, output is removed from the output signal-. , the second pair of characters of the four character alphabet of the first multiplier 1 high frequency carrier is caught, while the signals of the first pair of characters of the four character alphabet do not pass to the output of the second 27 low pass filter.  The sequence of video pulses received at B) output of the second low-pass filter 27 goes through the first delay element 17 to the second and directly to the third inputs of the following correlator 4, and through the first switch 12 (depending on its state) to the first input of the next the correlator of torus 4 or the input of the second delay element 18 —and further to the fourth input of the next correlator of the torus 4.  The sequence of video pulses received at the output of the second low-pass filter 27 goes through the third delay element 28 to the fifth and directly to the sixth inputs of the servo-correlator 4, and through the third switch 26 (depending on  bridges from its ss stand to the seventh input of the tracking correlator 4 or to the input of the fourth delay element 29 and then to the eighth input of the next 1 {{relay 4).  At the output of the servo correlator 4, a voltage is allocated that is directly proportional to the fractional part of the error, resulting in; those operations re-; the multiplications of the voltages applied to the first and second inputs of the next cortex.  rel torus 4, the second operation of intermittenting the voltages supplied to the third and fourth inputs of the next correlator; 4, the third operation of surplusing the voltages supplied to the fifth and seventh inputs of the next correlator; 4, the fourth operation, voltage multiplication.  Coming to the sixth and eighth inputs of the next correlator 4, summing using block 7 subtracting the third and seventh realizable multipliers 5 and, 23 results of the first and third multiplication operations, summing up using block 7 subtracting realized by the fourth and sixth intermixes 6 and 22 the results of the second and fourths of the operations of multiplying, subtracting one result of the sum. nor from another and iitegrirvani with.  using the second integrator 8, the result of the operation of reading, extracting the output of the subtracting lock 7.  When choosing the jade shadow of the delay elements 17, 18, 28 and 29 it should be borne in mind that the deviation. the delay time of the delay elements 17, 18, 28, and 29 from the optimal value T 0.25 Tr does not cause a shift in the temporal position of the discriminatory characteristic of the next correlator 4, however, it is true. This leads to an undesirable narrowing of its work area.  The voltage received at the output of the next Co- lator 4, under 2 watches the frequency of the pulses of the controlled oscillator, is 14 clock pulses, which ensures the synchronization of the SRP generator 11 over the clock frequency.  .  Simultaneously, using a block. 10, the search control searches the phase of the information segment. signal flow, manipulated by the phase with a pseudo-random sequence, which is positive in the case of using a pseudo-random intrapulse phase mapping of the signal is shown by the Hc difference between the correlation peak at the output of the first and second signal correlators of the second sequencer of the second correlator of the second sequencer connected and serially connected fifth multiplier 20 and third integrator 24.  The impulse of the correlating zone of the peak generated in the circuit of the first correlating correlator, triggers the operation of the first threshold of block 9, and the impulse, generated in the circuit of the second signaling circuit, triggers the operation of the second threshold unit 25.  The output voltage of the first threshold block 9 or the second threshold block 25 instructs the control block 10,.  search to terminate the search procedure.  The rule of making a decision about the positive outcome of the search for the network phase of the information flow of signals.  manipulated in phase by a pseudo-ray sequence, if there are several information pieces in a segment, reduced to the detection of a code sequence.  belonging to a certain mystery of code sequences, iq nimahh by means of threshold blues | СОВ 9 and 25 hypotheses about the second cereader 2 and Second input of the second multiplier 20 arriving at the first input, and the information about the time position of the pseudo random code phase manipulation.  In this case, the decision about the search result is made by the own device of the search control control unit 10 - the code detector. a sequence belonging to a given set of code sequences of redundant coding of information.  Entering redundancy in the information sequence is not a condition for the realization of segments of the information signal flow, of which the code combinations are made, containing information 9. the temporary position of the pseudo-random phase shift keying of the information sequence, As a result of synchronization over the clock frequency and the detection of the phase of the pseudo-random code phase shift keying of the signal or segment of the information signal sequence in the first multiplier 1, the pseudo-random shift of the information sequence leading to to expand the bandwidth occupied.  by the disturbance collector and, in practically important cases, to the narrowing of the band occupied by the spectrum of the useful component of the input oscillation.  These changes in the input spectrum at the output of the first multiplier 1 provide a high level of interference.  The efficiency and reliability of the separation with shaper 3. 6 support. wow waveform.  signal carrier frequency - Phase detection pseudo-random sequence phase shift keying. the signal is accompanied by the supply of a command signal generated at the second output of the search control unit 10 to the third control input of the second switch 13.  While the second switch 13 disconnects from the second input of the generator 11 of the SRP, the second input of the first. the switch 12 and the second input of the third switch 26, the output of the controlled oscillator 14 clock pulses and connects the output of the divider 19, through which the formation of pulses of clock synchronization from the reference oscillation allocated to; the output of the translator 16 of the reference signal.  At this moment, the adjustment is on.  the clock frequency, the pseudo-radiant sequence of phase shift keying and the frequency of the carrier oscillation will be derived from the direct voltage of the own discriminator of the reference signal generator 16, which ensures a high accuracy of tracking the time delay of this 11-sequence signal.  To verify the uniqueness in determining the delay, the second switch 13 may. repeatedly changing the input oscillation of the pulse pulses.  14 clock pulses supplied from the output-controlled generator and divider 19 to the second input of the SRP generator 11, the second input of the first switch 12 and the second input of the third switch 26. Resetting the divider 19 to the state in which the clock frequency pulses, provided at the outputs of the divider 19 and the controlled generator, provide 14 clock pulses, are both baked by applying clock pulses to the second input of the divider 19-output of the second switch 13.  As elements, delays 17, 18, 28, and 29, two-bit shift registers can be used.  As the first multiplier 1, a phase manipulator containing two keys can be used, the first inputs of which are supplied with an input oscillation, and the second non-inverted input of the first key and the second inverse input of the second key are supplied with a voltage from the output of the first switch 11 . through an inverse cascade with the first input of the adder, the output of which is the output of the first multiplier 1, and the second input is connected to the output of the second key.  Thus, the clock synchronization device of pseudo-random sequences is consistently used in the receiving equipment of information transmission systems through multipath. tract with. variable parameters and limited bandwidth in organizing the transmission of information by four-letter alphabet signals and the use of pseudo-random manipulation of a segment of the initial information flow of signals.  The proposed devices provide reduced time. search for the phase of the information flow of signals of two-character and four-character alphabets, manipulated in phase by a pseudo-random sequence and containing information of one line of a television frame; increase the accuracy of tracking the signal parameters. ala; . frame and line synchronization without transmitting through the channel special signals of frame and line synchronization j; implementation of simultaneous transmission and separation on reception of information streams related to various sources of information; increase in the resistance of the radio link to organized interference; receiving a signal transmitted via a multi-path with variable parameters, one (dominant) beam transforming the signals of parasitic rays into pseudo-noise effects, which ensures the highest quality of reproduction at the reception of a television image.

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Claims (2)

1. A TACT SYNCHRONIZATION DEVICE FOR Pseudo-Random Sequences, comprising a first multiplier, a second multiplier connected in series, a first integrator, a threshold unit, a search control unit and a pseudo-random sequence generator (PSP), as well as a first connected switch, a tracking pulse generator, and a servo-controlled correlator moreover, the tracking correlator contains the third and fourth multiple and the second integrator, the output of which is the output of the tracking correlator , the first input of which is the first input of the third * multiplier, characterized in that, in order to reduce the time of synchronization and increase the accuracy of tracking the time delay of the segment of the informational signal stream of a two-character alphabet modulated by a pseudo-random sequence, series-connected reference shaper are introduced signal, divider and second switch, as well as / two delay elements and a low-pass filter, to the input of which the output of the second multiplier is connected, and (the output low-pass filter through (the first delay element is connected to (the second input of the tracking correlator and directly to the first input of the first switch and the third input / tracking correlator, to the fourth. the input of which, through the second delay element ^{1, is} connected to the second output of the first switch, to the second input of which, as well as to the second inputs of the main switch and generator, the output of the second switch is connected, to the second and third inputs of which the output of the controlled clock and a second output of the search control unit, wherein the output of the generator. The SRP is connected to the first input of the first multiplier, the second input of which is the input of the device, and the output of the first, multiplier is connected to the input of the reference signal shaper and the first input of the second multiplier, and the former input of the shaper ^ supports is connected to the second input. a signal, moreover, a subtraction block is introduced into the tracking correlator, the inputs of which are connected to the outputs of the third and fourth multiplier a ^ the output of the subtraction block is connected to the <input of the second integrator, while the second input of the third multiplier, the first and second inputs of the fourth multiplier are, respectively the second, third, and fourth inputs of the tracking correlator. I; . ·. ’ 2. The device according to claim 1, about t l and. moreover, in order to reduce the time required to enter the clock * and increase the accuracy of tracking ~ rwnrr'Ti§ over the delay time of a segment of the information flow of signals of the four-character alphabet modulated by a pseudorandom sequence, we introduced series-connected phase shifter , the fifth multiplier, the third integrator, the second threshold block, the output of which is connected to the second input of the search control block, as well as the third switch, the third and fourth elements of delay and the second Filter often m, the output of which through the third delay element is connected to the fifth input of the tracking correlator and directly to the first input of the third switch and the sixth input of the tracking, correlator, to the seventh and eighth inputs: of which the first and second outputs of the third switch are connected directly and through the fourth delay element, the second input of which the output of the second switch is connected, while the output of the driver of the reference signal is connected to the input of the phase shifter, and the output of the first multiplier is connected to the second input of the fifth sixth multiplier, and the sixth and seventh multipliers are added to the tracking correlator, the outputs of which are connected to the third and fourth inputs of the subtraction unit, while the first and second inputs of the seventh multiplier are the fifth and seventh inputs of the tracking correlator, the sixth and eighth inputs of which are the first and the second inputs of the sixth multiplier, and the output of the fifth multiplier is connected to the input of the second low-pass filter.