RU1787278C - Device for synchronizing seismic signal sources - Google Patents

Abstract

Usage: geophysical technique used during seismic exploration, namely, synchronous control of seismic signal excitation sources. The inventive device comprises a trigger unit, a modulator, a radio transmitter, a radio receiver, a sequence element regenerator, a clock selector, a clock generator, a general reset generator, a synchronization check unit, an input and generated sequence matching check unit / a synchronization sequence generator is made in the form ternary sequence generator. A multiplexer, a pseudo-random sequence of numbers, and a clock phase synchronizer are introduced into the device. 2 s.p. crystals, 1 tab .; 7 ill.

Description

The invention relates to a geophysical technique used in seismic surveys, and in particular to devices for synchronously controlling seismic signal excitation sources.

A device for the correlation selection of time stamps, consisting of a communication line, command and control points, each of which contains a code signal sending unit, a character determination unit, random access memory, a character multiplier, a negative product counter, a positive product counter and an adder . The extraction of a command signal in this device is achieved by introducing blocks providing correlation processing of the received signal and using a sweep signal generator as a block for sending a code signal.

A disadvantage of the known device is the insufficiently high noise immunity with a high level of interference in the radio channel, which leads to frequent non-triggering of the source due to non-isolation of the command pulse.

Known equipment for time synchronization of seismic exploration, consisting of half-kits for the master and slave seismic stations and including radio transmitting and receiving devices, and each half-set has a time stamp storage unit containing a reference oscillation generator, a frequency divider, and a tag former

XJ 00 VI

to

Xi 00

GO

time, synchronization circuit, AND element, comparison circuit, switching element, memory unit, second switching element, control signal generator and inverter.

A disadvantage of the known device is the high demands placed on the relative stability of the generator for HbYx support. What: it complicates the technical implementation of the device.

The closest in technical essence to the invention is a device for synchronizing sources of seismic signals, containing, on the transmitting side, a trigger circuit, an M-sequence generator, a radio transmitter, and on the receiving side a radio receiver, a symbol regenerator, a symbol counter, a match circuit, a key, a shift register , adders modulo two, a counter of coincidences, two triggers and a clock generator.

A disadvantage of the known device is its low noise immunity due to the non-ideality of the periodic autocorrelation function of the synchronizing code and its low significance, which requires an increase in the time required for synchronization.

The aim of the invention is to increase the noise immunity.

The goal allows ultimately to increase the productivity of seismic exploration due to a more reliable launch of sources of seismic vibrations and to reduce the time spent on synchronization. The goal is achieved by the fact that in a device for synchronizing sources of seismic signals containing a serially connected trigger unit, a synchronization sequence generator, a modulator, a radio transmitter, as well as a radio receiver, a sequence element regenerator, a clock selector, a clock generator, a common driver reset, block checking the entry into synchronism, block matching the input and generated sequences and the output bus, while the output of the radio connected to the input of the regenerator of the sequence elements, the first output of the check block. input $ synchronism is connected to the first input of the check block of the input and generated sequences, the first input of the check block of synchronism is connected to the output of the common reset generator, the first and second outputs of the check block of input and

the generated sequences are connected respectively to the first input of the common reset driver and the enable input of the clock selector, and the output of the clock selector is connected to the output bus, a multiplexer, a pseudo-random number sequence generator and a clock phase synchronizer are introduced, and a clock generator

0 sequence is made in the form of a ternary sequence generator, while the first output of the sequence element regenerator is connected to the first input of the multiplexer, the second input

5 of the synchronization check unit and the first input of the phase synchronizer of the clock pulses, the second output of the sequence element regenerator is connected to the second input of the multiplexer and the third

0 by the input of the synchronization checker, the third output of the sequence element regenerator is connected to the second input of the common reset driver, the first output of the clock

5 is connected to the second input of the clock phase synchronizer, the first and second outputs of the pseudo-random sequence of numbers are connected to the third and fourth inputs, respectively

0 of the multiplexer and the fourth and fifth inputs of the synchronization checking unit, the second output of the clock generator is connected to the first input of the pseudo-random sequence generator (5), the third input of the common reset driver, the sixth input of the synchronization checking unit and the second input of the input matching unit and generated sequences, the first and second outputs of the multiplexer are connected respectively to the second and third inputs of the generator of the pseudo-random sequence of numbers Ate, the bit outputs of the pseudo-random sequence of numbers are connected to the inputs of the clock selector, the output of the clock phase synchronizer is connected to the input of the clock, and the second output of the check unit

0 synchronization input is connected to the control input of the multiplexer and the third input of the matching check block of the input and generated sequences.

Also in the sync device

5 sources of seismic signals, the ternary sequence generator contains a clock pulse generator, a sequence length generator, two shift registers, an adder modulo three, an AND element, an OR element, and a one-shot oscillator, the output of which is connected to the enable inputs for parallel recording of the first and second shift register information, the generator output clock pulses connected to the first input of the element And, the second input of which is connected to the output of the shaper length of the sequence, the input bus of the generator the other sequence is connected to the input of the single-vibrator, to the first input of the OR element, to the input of the clock generator and to the first input of the sequence length former, the second input of which is connected to the output of the AND element and the second input of the OR element, the clock inputs of the first and second shift registers are connected with the output of the OR element, the bit outputs of the shift registers are connected to the input of the adder modulo three, the first output of which is connected to the information input of the first shift register and the first output bus ternary sequence generator and an information input of the second shift register is connected to the second output of the modulo adder output bus vrvtoroy three ternary sequence generator.

In addition, in a device for synchronizing seismic signal sources, the modulo three adder contains a switch, a two-bit adder, an I element, and two EXCLUSIVE OR elements, while the adder input three-bit buses are connected to the inputs of the switch, the outputs of which are connected to the bit inputs adder, the first bit output of the adder is connected. to the first input of the first element EXCLUSIVE OR and the first input of the element And, the second bit output of the adder is connected to the first input of the second element EXCLUSIVE OR and the second input of the AND element, the output of which is connected to the second inputs of the first and second elements EXCLUSIVE OR, the transfer output of the adder is connected to its transfer input, the output of the first element is EXCLUSIVE. OR is connected to the first output bus of the adder modulo three, and the output of the second element is EXCLUSIVE OR connected to the second adder output bus modulo three.

In FIG. 1 shows a block diagram of a device for synchronizing sources of seismic signals; in FIG. 2 is a structural diagram of a ternary sequence generator; in FIG. 3 is a diagram of a regenerator of sequence elements; in FIG. 4 is a diagram of a clock phase synchronizer; in FIG. 5 - circuit block check

entering synchronism; in FIG. 6 is a schematic diagram of a block matching the input and generated sequences; in FIG. 7 is a diagram of the driver of the General reset. The device for synchronizing sources of seismic signals (Fig. 1) contains a start block 1, a synchronization sequence generator 2, made in the form of a ternary sequence generator.

0 news, modulator 3, radio transmitter 4, radio receiver 5, regenerator 6 of sequence elements, multiplexer 7, generator 8 of a pseudo-random sequence of numbers, clock selector 9,

5 clock phase synchronizer 10, clock generator 11, synchronization check unit 12, general reset generator 13, input and generated match check unit 14

0 sequences and the output bus 15. In the device for synchronizing the sources of seismic signals, the output of the trigger unit 1 is connected to the input of the generator 2 of the synchronization sequence,

5, the first and second inputs of the modulator .3 are connected respectively to the first and second outputs of the synchronization sequence generator 2, the output of the modulator 3 is connected to the input of the radio transmitter 4. Output 0 of the radio receiver 5 is connected to the input of the regenerator 6 of the sequence elements, the first output of which is connected to the first input multiplexer 7, the first input of the clock phase synchronizer 10

5 pulses and the second input of the synchronization check unit 12. The second output of the regenerator 6 elements of the sequence is connected to the second input of the multiplexer 7 and the third input

0 of synchrocheck block 12. The third output of the regenerator b of the sequence elements is connected to the second input of the generator 13 of the total reset, the third and fourth inputs of the multiplexer 7

5 are connected respectively to the first and second outputs of the pseudo-random sequence of numbers generator 8 and, respectively, to the fourth and fifth inputs of the synchronization check unit 12. The first and second outputs of the multiplexer 7 are connected respectively to the second and third gatherings of the generator. 8 of a pseudo-random sequence of numbers, the bit outputs of the generator 8 of the pseudo-random 5 sequence of numbers are connected to the bit inputs of the clock selector 9, the enable input of which is connected to the second output of the matching sequence of the input and generated sequences. First entry

the common reset driver 13 is connected to the first output of the input and generated sequences matching unit 14. The output of the clock selector 9 is connected to the output bus 15. The first output of the clock generator 11 is connected to the second input of the clock phase synchronizer 10, the second output of the clock generator 11 connected to the first input of the generator 8 of the pseudo-random sequence of numbers, the third input of the generator 13 of the general reset, the sixth input of the block 12 for checking synchronism and second an input unit 14 checks matching between the input and the generated sequences. The input of the clock generator 11 is connected to the output of the clock phase synchronizer 10, the output of the general reset driver 13 is connected to the first input of the synchronization check unit 12. The first output of the synchronization check unit 12 is connected to the first input of the input and generated sequences matching unit 14, the third input of which is connected to the control input of the multiplexer 7 and the second output of the synchronization check unit 12.

The synchronization sequence generator 2 (Fig. 2) is made in the form of a ternary sequence nerator and contains an input bus 16, a clock pulse generator 17, a sequence length generator 18, the first and second shift registers 19 and 20, element 21, element 22, one-shot 23, the adder 24 modulo three, the first and second output buses 25 and 26. The sequence length generator 18 comprises an RS flip-flop 27, a pulse counter 28, and an And 29 element. The adder 24 modulo three contains a switch 30, a two-bit adder 31, an element And 32 and dv and the element is EXCLUSIVE OR 33, 34.

In the ternary sequence generator, the output of the one-shot 23 is connected to the inputs for enabling parallel recording of information of the first and second shift registers 19 and 20, the output of the clock generator 17 is connected to the first input of the element And 21, the second input of which is connected to the output of the generator 18 of the sequence length. The input bus 16 of the ternary sequence generator is connected to the input of the single-shot 23, with the first input of the OR element 22, with the input of the clock generator 17 and with the first input of the generator 18 of the sequence length, the second input of which

connected to the output of the AND element 21 and the second input of the OR element 22. The clock inputs of the first and second shift registers 19 and 20 are connected to the output of the OR element 22,

the bit outputs of the shift registers 19 and; 20 are connected to the inputs of the adder 24 modulo three, the first output of which is connected to the information input of the first shift register 19 and the first output

0 bus 25 of the ternary sequence generator, and the information input of the second shift register 20 is connected to the second output of the adder 24 modulo three and the second output bus 26 of the ternary sequence generator.

In the adder 24 modulo three (Fig. 2) the bit input bus connected to the inputs of the switch 30, the outputs of which are connected to the bit inputs of the adder

0 31. The first bit output of the adder 31 is connected to the first input of the first EXCLUSIVE OR element 33 and the first input of the AND 32 element, the second bit output of the adder is connected to the first input of the second EXCLUSIVE OR 34 element and the second input of the And 32 element, the output of which is connected with the second inputs of the first and second elements EXCLUSIVE OR 33 and 34. The transfer output of the adder 31 is connected to its transfer input, the output of the first element of the EXCLUSIVE OR 33 is connected to the first output bus of the adder 31 modulo three, and the output of the second element is EXCLUSIVE OR 34 is connected to the output bus vto5 swarm adder 24 modulo three.

In the shaper 18 of the length of the sequence (Fig. 2), the first input bus is connected to the input of the unit

0 state of the trigger 27 and the installation input of the 0 pulse counter 28, the second input bus is connected to the clock input of the pulse counter 28, the output of the trigger 27 is connected to the output bus of the driver

5 is the length of the sequence, the bit outputs of the pulse counter 28 are connected to the inputs of the element And 29, the output of which is connected to the input of the installation in the zero state of the trigger 27.

0 The regenerator 6 of the sequence elements (Fig. 3) contains an input bus 35, two inverter amplifiers 36, 37 on the operational amplifiers x, two key elements 38; .39 transistors, two

5 single vibrator 40,41, with inputs for starting and prohibiting operation, an OR element 42 and three output buses 43, 44, 45. The input bus is connected to the input of the first amplifier inverter, the output of which is connected to the input of the first key element and the input of the second amplifier an inverter whose output is connected to the input of the second key element. The start input of the first one-shot is connected to the output of the first key element, the start input of the second one-shot is connected to the output of the second key element. The output of the first one-shot is connected to the first output bus, the first input of the OR element and the inhibit input of the second one-shot, the output of the second one-shot is connected to the second output bus, the second input of the OR element and the inhibit input of the first one-shot, the output of the OR is connected to the third output bus.

The clock phase synchronizer 10 (Fig. 4) contains the first and second input buses 46 and 47, the pulse counter 48, the first and second drivers 47 and 50, the I 51 element and the output bus 52. The first input bus is connected to the input of the first driver, output which is connected to the input of the installation in O of the pulse counter and the first input of the element I. The second input bus is connected to the clock input of the pulse counter, the output of which is connected to the input of the second driver. The output bus is connected to the output of the And element, the second input of which is connected to the output of the second driver. In this case, the front edge of the pulse former is used as the first driver, and the one-shot is used as the second driver.

The synchronization check unit 12 (Fig. 5) contains six input buses 53-58, a comparison element 59, a pulse counter 60, three AND elements 61, 62, 63, a driver 64, two elements NOT 65, 66, an OR element 67, the first and second output buses 68 and 69. The first input bus is connected to the first input of the OR element, the output of which is connected to the input of the pulse counter setting О. The second and fifth bus inputs are connected to the bit inputs of the comparison element, the output of which is connected to the input of the first element NOT and the first input of the first element I. The sixth input bus is connected to the input of the driver, the output of which is connected to the equality input of the codes of the comparison element and the first the input of the second element I. The output of the first element And is connected to the clock input of the pulse counter, the output of which is connected to the input of the second element NOT,. The output of the first element is NOT connected to the second input of the second element And, the output of which is connected to the first input of the third element And and the first output bus. The second input of the OR element is connected to the output

the third element And, the second input of which is connected to the second input of the first element And, the output of the second element is NOT and the second output bus. As a driver in the synchronization check unit 12, a pulse leading edge driver is used.

Block 14. Checking the coincidence of the input and generated sequences (Fig. 6)

0 contains three input buses 70, 71, 72, two elements And 73, 74, two counters 75, 76 pulses, element NOT 77, the first and second output buses 78 and 79. The third input bus is connected to the inputs of the installation O

5 first and second pulse counters. The second input bus is connected to the first input of the first AND element, the output of which is connected to the clock input of the first pulse counter. The first input bus is connected to the clock input of the second pulse counter. The output of the first pulse counter is connected to the input of the element NOT, the output of which is connected to the second input of the first element And, the second output bus and per.

5th input of the second element AND, the second

the input of which is connected to the output of the second

pulse counter. First exit bus

connected to the output of the second element I.

Shaper 13 General reset (Fig.

0 7) contains three input buses 80, 81, 82, AND element 83, driver 84, pulse counter 85, element NOT 86, element OR 87 and output bus 88. The first input bus is connected to the first input of the element

5 OR, the second input bus is connected to the input of the driver, the third input bus is connected to the first input of the AND element, the output of which is connected to the clock input of the pulse counter. The output of the formed bodies is connected to the input of the installation O of the pulse counter, the output of which is connected to the input of the element NOT. The second input of the OR element is connected to the second input of the AND element and the output of the element NOT. Output-5 on the bus is connected to the output of the OR element. A pulse leading edge driver is used as a driver.

In the device for synchronizing seismic signal sources (Fig. 1), the start block 1 includes a start circuit of the seismic station and a Start button, the outputs of which are connected to the inputs of the OR element, the output of which is the output of the start block.

5 Modulator 3 contains a sinusoidal signal generator, an inverter amplifier and two keys, while the output of the sinusoidal signal generator is connected to the inputs of the inverter and the second switch, the output of the inverter amplifier is connected to the input of the first

the key, the outputs of the first and second keys are connected to the output bus of the modulator, and the control inputs of the first and second keys are connected respectively to the first and second input buses of the modulator, to which signals corresponding to the elements of the sequence + 1 and - 1 are supplied. it is implemented in digital form on the basis of a reference pulse generator, a binary pulse counter, read-only memory (ROM) and an analog-to-digital converter with a filter.

As the radio transmitter 4 and the radio 5, standard Len-B radio stations are used.

The pseudo-random sequence of numbers generator 8 is made according to the ternary sequence generator circuit (Fig. 2), which includes a register presetter (single vibrator 23) and a sequence length generator 18, and the generator feedback circuits are open (i.e., the outputs of the elements EXCLUSIVE OR 33 , 34 are not connected to the DR inputs of the shift registers 19, 20).

The selector 9 of the clock pulse is made according to the coincidence circuit, the inputs of which are fed from the first shift register 19 of the pseudo-random sequence generator, and the inverse bit outputs are fed from the second shift register 20 of the pseudo-random sequence generator and the second output of block 14 is connected to one of the inputs checking that the input and generated sequences match.

The clock generator 11 is made according to a standard scheme containing a highly stable quartz reference frequency generator and a frequency divider made on binary counters. The inputs of the installation in About the pulse counters are connected to the input bus of the generator, which receives the clock signal of the phase of the clock pulses. At the second output of the generator, clock pulses are generated for the ternary sequence generator (pseudo-random sequence generator), and at the first output of the generator, pulses with a higher frequency, a multiple of the clock frequency at the first output of the generator, are used in the clock phase synchronizer 10.

As a switch 30, a switch is used, which allows connecting the necessary outputs from the shift registers 19 and 20 to the inputs of the adder 31.

A device for synchronizing sources of seismic signals works as follows.

In the initial state, the check unit 12

occurrence of synchronism is set to the initial state by a signal from the generator 13 of the general reset, which provides a signal for its installation when a pause occurs for more than a specified duration. Moreover, with

0, the second output of the synchronization check unit 12 receives a signal at the control input of the multiplexer 7 to turn it on in such a state that the signals from the first and second outputs of the regulator 6 of the sequence element 6 pass through the multiplexer 7 to the second and third inputs of the pseudo-random generator 8 sequences of numbers

In the generator 2 of the ternary sequence and the generator 8 of the pseudo-random sequence of numbers using the switch 30 in the adder 24 modulo three connect the necessary outputs of the first and second shift registers 19 and 20 to

5-bit inputs of the adder 31. For example, when using a pulse sequence consisting of 13 elements as a synchronization code, the first three triggers are used in the shift registers 19 and 20, while the switch 30 connects the second and third outputs of the shift registers 19 and 20 to the digital inputs of the adder 31. When used as a clock

5 of the pulse sequence code, consisting of 121 elements, the first five triggers are activated in the shift registers 19 and 20, while the switch 30 connects the fourth and fifth outputs of the shift

0 registers 19 and 20 to the bit inputs of the adder 31. If you use a pulse sequence consisting of 1093 elements as a synchronization code in the shift registers 19 and 20

5, the first seven triggers are involved, and the switch 30 connects the second and seventh outputs of the shift registers 19 and 20 to the bit inputs of the adder 31.

From the start block 1, a launcher is supplied

0. pulse to the generator 2 of the ternary sequence. When this pulse arrives, the trigger 27 of the driver 18 of the sequence length is set to a single state, ensuring receipt. clock pulses from the generator-17 through the element And 21 and the element OR 22 to the clock inputs of the shift registers 19 and 20. Previously, before the start of the work of the shift registers 19 and 20, they record in parallel the following information: in the first shift register 19 in all bits entered code D, and in the second shift register 20, code 0y is entered into all bits. This is accomplished by supplying a short start-up clock pulse from the input bus 16 through the OR element 22 to the clock inputs of the shift registers 19 and 20. At the same time, the start-up pulse expanded by a single-shot 23 is applied to the recording enable input for parallel information, which makes it possible to produce a start-up pulse parallel recording of information in the shift registers 19 and 20.

. The ternary sequence generator 2, using the pulse counter 28 and the And 29 element, which acts as a decoder, generates a pulse sequence consisting of a given number of elements. At the moment of the formation of the last element of the sequence, the signal from the output of the element And 29 resets the trigger 27 to the zero state, which prohibits the passage of clock pulses through the element And 21. As a result, the ternary sequence generator 2 stops working. The law of the generated ternary sequence is determined by the feedbacks in the shift registers 19 and 20 and the operations performed by the adder 24 modulo three. The operation of the adder 24 modulo three is presented in the table.

In the table, the notation is accepted: Ai, A2 are the bit outputs of the shift register 19; Bi, 62 - bit outputs of the shift register 20; P0 is the transfer input of the adder 31; PRi, DRa - information inputs of the shift registers 19 and 20, respectively.

Therefore, in the process of generating a pulse sequence by the generator 2, the following code signals appear on its output buses 25 and 26: O O corresponding to the ternary sequence element O; 10 corresponding to element +1 of the ternary sequence; 01 corresponding to element -1 of the ternary sequence.

The ternary sequence generated by the generator 2, for example, consisting of 13 elements: -1 -1 0 +1 -1 + 1 00 + 10 +1 +1 +1, is supplied to the modulator 3, in which the sinusoidal signal of the subcarrier of the radio transmitter 4 is modulated by phase as follows. Each element of the sequence corresponds to one period of the sinusoidal oscillation, while the element of the ternary sequence + G corresponds to the period of the sinusoidal oscillation of the subcarrier with the initial phase

Oh, the element of the ternary sequence -1 corresponds to the period of the sinusoidal oscillation of the subcarrier with the initial phase, and the element of the ternary sequence

0 corresponds to the omission of sinusoidal oscillations of the subcarrier over a time interval of a length during the period of the sinusoidal oscillation. The signal from the modulator 3 is fed to the radio transmitter 4 for modulating the carrier frequency and transmitting it via the communication channel to the radio receiver 5, which extracts the subcarrier signals and feeds them to the input of the regenerator 6 of the sequence elements, where they are amplified and converted

5 into unipolar rectangular pulses. At the same time, at the first output of the regenerator 6, rectangular pulses of a length during the period of sinusoidal oscillation of the subcarrier are received when receiving the +1 symbol, at the second output of the regenerator 6, rectangular pulses of a length during the period of sinusoidal oscillation of the subcarrier are received at the reception of the symbol -1, and at the third output regenerator 6 produces pulses corresponding to elements +1 or -1. The absence of pulses at the first and second output of the regenerator 6 elements of the sequence, indicates the reception of the element of the 0th sequence.

0 Since the control signal from the synchronization checking unit 12, the multiplexer 7 is turned on to transmit the signals of the sequence element regenerator 6 to the information inputs

5 of the pseudo-random sequence of numbers generator 8, the numbers allocated by the sequence element regenerator 6 are input into the shift registers 19 and 20 of the pseudo-0 random sequence of numbers generator 8 to ensure that it is in synchronism with the ternary sequence generator 2. 6 elements selected by the regenerator.

In sequence 5, the signals corresponding to elements +1 also arrive at the synchronizer 10 of the phase of clock pulses, where they form their leading edges and check their compliance with the signals, rather than the noise, based on measuring the interval of their repetition with a given tolerance. The signals of the leading edges of the pulses extracted from the regenerator 6 of sequence elements 5 extracted by this selector are transmitted to the input of the clock pulse generator 11 for its synchronization. If the synchronizer 10 phase of the clock pulses does not highlight the phase of the received signals pulsed. sequences due to interference in

radio channel, the clock generator 11 operates without phase locking of the clock phase. This is possible because with high stability of the reference oscillators, the phase drift between the clock pulses in the ternary sequence generator 2 and the generator 11. will be insignificant due to the short time interval during which the pulsed interference is effected:

If the elements of the sequence, highlighted by the regenerator 6 of the elements of the sequence, are not distorted by noise, then at the first and second output of the generator 8 of the pseudorandom sequence of numbers, a code of numbers is issued that matches the code of the numbers generated by the ternary sequence generator 2 after receiving the number of elements of the sequence through the communication channel equal to the number of bits involved in the shift registers 19 and 20. Block 12 check input. neither in synchronism compares 2–5 codes of numbers received at the inputs generated by the generator 8 of the pseudo-random sequence of numbers and the regenerator of b sequence elements. If these codes coincide, the set number of times is different. The signal From the second output of the synchronization check unit 12 is sent to the control unit. the input of the multiplexer 7 and to the third input of the block 14 for checking the coincidence of the input and generated sequences for its inclusion in operation. In this case, the multiplexer 7 connects the outputs of the generator 8 to its inputs and it begins to form an internal sequence in stand-alone mode. power with phase connected via the communication channel,; ; /:; G ;. : ... -. : ...; - ..

At the same time, the entry into the synchronization checker 12 starts issuing to the first output the clock pulses arriving at its sixth input from the oscillator 11 for each mismatch of the elements in the received via the communication channel and autonomously generated sequence. The indicated mm pulses are fed to the second input of the block 14 for checking the coincidence of the input and generated sequences for counting them in the generated time window based on the signals arriving at its third and second inputs, respectively, the resolution signal from block 12 and the clock pulses of generator 11. In case the number of detected mismatches in the installed window will not exceed the specified threshold; then the signal at the first output of block 14 does not appear and the common reset driver 13 will not give out a single reset signal in time

validation of input and self-generated sequences. In this case, the clock selector 9 determines the end of the pulse sequence of the sync code for a given code at the output of the shift registers of the generator 8, namely, code 1 at all the bit outputs of the shift register 19 and the code O at all bit outputs of the shift register 20. Selector 9

the sync pulse will give a start signal for the source of seismic oscillations upon receipt from block 14 of the verification of the coincidence of the input and generated sequences of the enable signal at its input

enable and isolate the end signal of the sync code pulse sequence.

If the generators 2 and 8 are out of phase, the match check unit 14

: the input and generated sequences through the first output will give a signal to the first input of the generator 13 of the general reset. As a result, the driver 13 of the General reset will give a signal to install in

the initial state of the synchronization check unit 12. In this case, a new attempt is made to introduce oscillators 2 and 8 into synchronism. The number of repeated attempts to introduce oscillators 2 and 8 into synchronism is determined by the length of the sequence used as a sync code, as well as the size of the time

a window used to verify that the input and generated sequences match. An increase in the length of the sequence used as a sync code increases the reliability of triggering sources of seismic oscillations, but it is advisable to choose the length

the sequences should be carried out in optimal limits so that this does not lead to a loss in the productivity of seismic surveys.

If there is more than the permissible number of gaps in the sync code sequence transmitted over the air, the common reset driver 1.3 based on the signals coming from the third output of the regenerator 6 of the sequence elements arriving at the second input and generates a reset signal to the input check unit 12 to the third output of the clock pulses from the generator 11 synchronism for resetting it. The same situation occurs when the transmission of the sync code over the air is not performed for more than a specified time.

Thus, the start signal of the source of seismic oscillations provided by the clock selector 9 coincides in time with an accuracy of phase incursion in the radio channel with the signal of the end mark of the sequence provided by the synchronization generator 2; . the sequence at the seismic station for registration.

Claims (3)

1. A device for synchronizing sources of seismic signals, containing a series-connected trigger unit, a synchronizing sequential generator. sequence, a modulator, a radio transmitter, as well as a radio receiver, a sequence element regenerator, a clock selector, a clock pulse generator, a general reset generator, a synchronization check unit, an input and generated sequence matching unit and an output bus, while the output of the radio receiver is connected to the input regenerator of the sequence elements, the first output of the synchronization checker is connected to the first input of the matching checker of the input and generated signals , the first input of the synchronization checking unit is connected to the output of the common reset driver, the first and second outputs of the matching unit of the input and generated sequences are connected respectively to the first input of the general reset driver and the enable input of the clock selector, and the output of the clock selector is connected to the output bus, It is important that, in order to increase the noise immunity, the synchronization sequence generator is made in the form of a triple generator of the first sequence and a multiplexer, a pseudo-random number sequence generator and a clock phase synchronizer are introduced into the device, while the first output of the sequence element regenerator is connected to the first input of the multiplexer, the second input of the synchronization check unit and the first input of the clock phase synchronizer, the second output of the element regenerator the sequence is connected to the second input of the multiplexer and the third input of the synchronization check unit, the third output is re the sequence element generator is connected to the second input of the common reset driver, the first output of the clock generator is connected to the second input of the phase synchronizer, the first and second the output of the pseudo-random sequence of numbers is connected respectively to the third and fourth inputs of the multiplexer and the fourth and fifth inputs of the synchronization checking unit, the second output of the clock is connected to the first input of the pseudo-random sequence of numbers, the third in the run of the driver 0 total reset, the sixth input of the synchronization checking unit and the second input of the input and generated sequence matching unit, the first and second outputs of the multiplexbrags 5 are connected respectively to the second and third inputs of the pseudo-random sequence of numbers, the bit outputs of the pseudo-random sequence of numbers are connected to the entrances to. 0 of the clock pulse generator, the output of the clock phase synchronizer is connected to the input of the clock generator, and the second output of the synchronization check unit is connected to the control input of the multiplexer and the third, input of the matching unit of the input and generated sequences. 2. The device pop, 1, characterized in that the ternary sequence generator contains a clock pulse generator, a sequence length generator, two shift registers, an adder modulo three, an AND element, an OR element, and a single-shot, the output of which is connected to the resolution inputs parallel recording information of the first and second shift registers, the output of the clock generator is connected to the first input of the element And, the second input 0 which is connected to the output of the sequence length former, the input bus of the ternary sequence generator is connected to the input of the single-vibrator, with the first input of the element 5 OR, with the input of the clock generator and with the first input of the sequence length generator, the second input of which is connected to the output of the AND element and the second input of the OR element, clock 0 inputs of the first and second shift registers are connected to the output of the OR element, the bit outputs of the shift registers are connected to the input of the adder modulo three, the first output of which is connected to the information input of the first shift register and the first output bus of the ternary sequence generator, and the information input of the second shift register register connected to the second output of the adder modulo three and the second output ternary sequence generator bus .. 3. The device according to paragraphs. 1 and 2, with the proviso that the modulo three adder contains a switch, a two-bit adder, an AND element, and two EXCLUSIVE OR elements. in this case, the adder input busbars are modulo three connected to the inputs of the switch, the outputs of which are connected to the adder inputs, the first adder output is connected to the first input of the first EXCLUSIVE OR element and the first 0 by the input of the AND element, the second bit output of the adder is connected to the first input of the second EXCLUSIVE OR element and the second input of the AND element, the output of which is connected to the second inputs of the first and second EXCLUSIVE OR elements. the adder’s output is connected to its transfer input, the output of the first EXCLUSIVE OR element is connected to the first output bus of the adder modulo three, and the output of the second element of the EXCLUSIVE OR is connected to the second output bus of the adder modulo three. FIG. 4. input S3 about 55 56 57 FIG. .