SU1037195A1 - Equipment for temporary synchronization of seismic prospecting - Google Patents

Abstract

EQUIPMENT FOR TEMPORAL SYNCHRONIZATION OF SEISMO-SURVEY WORKS, consisting of half sets for master and slave seismic stations and including a radio transmitter and a radio receiver and on each half set, a time mark storage unit containing oscillator / reference oscillations, a frequency divider, a time generator, and a time diagram and a timeline diagram, and a time diagram and a time diagram and a diagram of a time diagram and a diagram of a diagram of the storage of time stamps; By the fact that, in order to reduce the cost of seismic prospecting and ampli fi cation, in the storage unit of time stamps of a half-set of a slave seismic station and an additional element And serially connected comparison circuit, a switching element, a memory unit, a second switching element, a shaper of control signals and an inverter 5 are added. In addition, the output of the synchronization circuit is connected to both switching elements, the onop oscillations and the frequency divider are connected to the comparison circuit and the control signal driver, and the output of the inverter through the AND element is connected to the frequency divider.

Description

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The invention relates to seismic exploration, in particular, devices for time synchronization of seismic exploration, and is intended for use by seismic stations located at large distances from each other as well as during underground seismic exploration.

The known apparatus for the time synchronization of seismic works carried out at points distant from each other without a direct connection between them, containing blocks for storing time stamps including stable frequency generators, blocks for forming time marks, sensors for visible signals

The disadvantage of this equipment is that in the event of a technical failure of one seismic station, a friend will execute the entire pre-agreed program, since the connection between them is not provided. Thus, there are unproductive costs of working time and money.

Also known equipment for time synchronization, containing a storage unit of time stamps in the semi-sets t of the master and slave seismic stations and standard radio equipment for transmitting voice or code signals, allowing the launch of seismic stations by successive time stamps 2).

However, such equipment for time synchronization of seismic exploration does not have the required noise immunity, which practically excludes its use for seismic exploration in underground conditions. Improving the noise immunity of equipment for temporal synchronization of seismic exploration requires an increase in the capital cost of these operations.

The closest in technical essence to the invention is an apparatus for synchronizing seismic surveys, which consists of semi-sets for the master and the driven seismic stations. The half-set of the master seismic station contains a radio transmitting device and a time stamp storage unit, which is composed of a reference oscillator, connected by its output to a frequency divider, the output of which is connected to a time stamp former, and a synchronization circuit. The radio transmitting device contains a resolution code signal generator. To use the next time stamp by coding signals from the intermediate stages of dividing the reference oscillations by frequency and the transmitting antenna. The half set of the slave seismic station contains a radio receiver and a timestamp storage unit, similar to the timestamp storage unit of the half set of the leading seismic station. The radio receiver contains a receiving antenna, synchronous filters, a detector, a switch, with which the incoming signals are selected by duration and location in time t31.

When using the known equipment, the error in synchronization of the interacting stations is determined mainly by the error of storage of time marks and does not depend on the parameters of the communication channel between the master and the slave stations. The main factor determining the accuracy of storing synchronized time stamp sequences in time stamp storage blocks is the accuracy of tuning the reference oscillators at a given operating frequency. Under field conditions of operation of seismic prospecting stations, the most acceptable type of reference oscillator are oscillators with quartz frequency stabilization. The error of tuning such generators for a given operating frequency is defined as the sum of the three components: the installation error associated with the inaccuracy of their adjustment during production, and errors caused by temperature and time drift of the frequency of the reference oscillators. At the same time, to ensure the required synchronization accuracy of seismic survey operations, determined by the amount of permissible non-synchronization of the launch points of seismic stations no more than 1 ms in 8 hours of continuous operation, the total relative detuning of the reference oscillators should not exceed 3-10.

Since the adjustment error and temperature drift are brought to a predetermined value when adjusting the equipment, the main source of inaccuracy in the operation of known devices is the time drift of the frequencies of the reference oscillators caused by oscillator elements, mechanical overloads and other factors that are not directly controllable. . Since the time drift of the frequency of thermostatically controlled quartz oscillators during their lifetime is of the order of 10, it cyiijecTBeHHo exceeds the permissible value relative to the detuning of the reference oscillations in frequency equal to S. Therefore, to ensure the required accuracy of the equipment for time synchronization of seismic exploration, periodic adjustment work (adjustment) of the reference frequency oscillations, which require expensive measuring equipment and highly qualified personnel, is included in the staffing schedule for their maintenance. All this, as well as the inevitable loss of working time associated with carrying out periodic adjustments, lead to an increase in operational and capital expenditures for seismic exploration.

The purpose of the invention is to reduce the capital costs of seismic prospecting.

This goal is achieved by the fact that S equipment for time synchronization of seismic exploration, consisting of semi-sets for master and slave seismic stations and including a radio transmitter jH radio receiving device and in each semi-complement a time stamp storage unit containing a generator of reference oscillations, a frequency divider marker generator time, the synchronization circuit, the storage unit. the time of the half-set of the slave seismic station is additionally introduced the AND element and the serially connected circuit are compared , a switching element, a memory unit, a second switching element, a Formation of control signals and an inverter, the synchronization output cxeNbi is connected to both switching elements, a reference oscillator and a frequency divider are connected to a comparison circuit and a driver of control signals, and the output the inverter through the element AND is connected to the divider h atoty.

Due to this, the specified synchronization of time stamp sequences generated at different seismic stations is ensured, since during the operation of the equipment, regular rather than periodic adjustment of the time stamp storage units is carried out. In this case, the adjustment is performed without the aid of external measuring and calibration devices. As a result, the operational and capital costs of seismic exploration are reduced.

The drawing shows the functional diagram of the device.

Equipment. The time synchronization of seismic surveys contains semi-sets 1 and 2 for Veduice and slave seismic stations, respectively. The leading seismic station half-package 1 includes a time tag storage unit 3 containing a generator of 4 reference oscillations, a frequency divider 5, a time stamp generator 6 and a synchronization circuit 7, and a radio transmitter device 8 containing a signal generator 9, code signals, modulator 10, amplifier 11 power and transmitting antenna 12. The generator 4 reference oscillations connected to the input of the divider frequency 5, the output of which is connected to the driver 6 timestamps. The output of the synchronization circuit 7 is connected to the control input of the divider

5 frequencies. The intermediate output 13 of the divider frequency 5 is connected to the input of the circuit 7 synchronization. Intermediate output 13, 14, 15, 16, 17 are connected to the driver 9 code

signals, and output 18 to the modulator. The half-set 2 of the slave seismic station includes a time tag storage unit 19 comprising a reference oscillator 20, element 21,

a frequency divider 22, a time stamp driver 23, a synchronization circuit 24, a comparison circuit 25, a switching element 26, a memory block 27, a second commutation element 28,

a driver 29 of control signals and an inverter 30, a radio receiver 31 comprising a receiving antenna 32, a synchronous filter 33, a detector 34 and a switch 35. In block 19 of the storage of time stamps, the comparison circuit 25 is sequentially compared to the cell 26 , the switching element 28, the driving signal driver 29. and the inverter 30. The output

synchronization circuits 24 are connected to switching elements 26 and 28 and to the control input of frequency divider 22. The generator 20 reference oscillations is connected through the element And 21

to the input of the divider frequency 22; the input of the comparison circuit 25 and the input of the control pulse former 29.

Output 36 of the divider 22 frequencies under the keys to the input of the 25 s comparison:

The output 13 of the divider 5 and the output 36 of the divider 22 are taken from identical steps of dividing the reference oscillations by frequency. Taken from the division of divider 22, which precedes the output 36 of the division stage 22, is connected to the input of the control signal generator 29. . The output of the i-inverter 30 is connected to the input of the divider 22 through I 21. Exit 36, 37, 38, 39 the divider 22 are connected to the switch 35, and you -

stroke 40 of divider 22 - to synchronous filter 33. The generator 20 of the reference oscillations of the block 19 of the semi-complement 2 of the slave seismic station is disturbed by the frequency relative to the generator 4 of the block 3 of the storage of time stamps of the semi-complement I of the leading seismic station by an amount greater than the time drift of the oscillators of the reference oscillations and less relative hyiirins of the energy spectrum of the code signal allowing the use of the next time stamp. Before starting work, blocks 3 and 19 of storing time stamps of half sets 1 and 2 of the master and slave seismic stations are transported to one place. A signal from the intermediate output 13 of the divider 5 of the frequency of the half-set 1 is supplied to the input of CHART 25 of the half-unit 2 and the timing of the half-set 1 of the leading seismic station is started. The synchronization pulse generated by the circuit 7. All divider stages 5 and 22 are set to the initial zero state and after the synchronization pulse of divider 5 and 22 ends, they are switched to the synchronous frequency division mode of the reference oscillations with equal division factors, since the control signals are at the output of the invertor 30 are missing. Simultaneously, the synchronization pulse from the exit of the synchronization circuit 24 opens the switching element 26 and closes the switching element 28. Since the frequency of the reference oscillations of the time stamp storage unit 19 is higher than the frequency of the reference oscillations generated in the time stamp storage unit 3, the signal An intermediate output 36 of divider i22, which is fed to the first input of the comparison circuit 25 and opens it. The moment of occurrence of the signal at the input of the switch 25 is the moment of the start of the counting of the pulses coming from the generator 20 through the comparison circuit 25 and the switching element 26 into the memory block 27, which is defined as tg t 6 split frequency factor 1 l 22; T is the repetition period of the reference oscillations; fg is the frequency of the reference oscillations at the vedkey seismic station. At time tp, a signal appears at the intermediate output 13 of divider 5 on the floor of set 1, which is fed to the second input of the comparison circuit 25, behind it. The time instant t, is defined as t crrrrrrrr-, where o / o (n is the divisor ratio of the divider 5 T {, is the repetition period of the reference oscillations generated by the generator 4. Thus, the difference in the half-period duration is measured repetition of oscillations at outputs 13 and 36 of dividers 5 and 22, respectively, G ft 2 o -fg b which is proportional to the difference between the true frequencies of the reference oscillations at the master and slave seismic stations at the time of comparison. In block 27, the binary number N was fixed. the whole part of the result of the true duration romezhutka D1 the duration of the period of reference pulse povtoeni oscillations). At the time point C, the output from 13 of the splitter 5 polats is also input to the schema 7 of the synchronization of the half-set 1. The synchronization pulse from the hook 7 is sent to the input of the synchronization circuit 24 of the half-set 2 and the secondary synchronization of the blocks 3 and 19 is carried out. Simultaneously, the signal from the circuit 24 is fed to the co-switching element 26 for its closure and for the switching of the element 28, in order to open it above this, the blocks 3 and 19 are displaced in the workplace. Further work is carried out in a known manner. At the master station, a permission code signal is generated to use the next time stamp with the aid of a radio transmitter 8. At the slave seismic station, the resolution code signal is received and selected. The formation of a sequence of time stamps at the slave seismic station is carried out as follows. The reference oscillations generated by the generator 20 are supplied to the first input of the element I and through the switching element 28 to the driver 29 of the control signals to the controller. The input input of which is also supplied from the intermediate output 37 of the divider 22. The control signal from the driver 29 through the inverter is fed to. element AND 21. As a result, the supply of reference oscillations from generator 20 to the input of divider 22 is delayed. Thus, the division factor of divider 25 is corrected in accordance with the actual detuning of the frequencies of oscillators 4 and 20. In this case, periodic sequences of time stamps with a given synchronism are formed. the use of the invention ensures the mutual synchronization of the seismic oscillator and the seismic receiver without using

71037195 °

{and non-underground in: with the known is provided conditions of wired communication channels of a given synchronization accuracy

with a high degree of accuracy. seismic exploration provided

An axial technical advantage is the comparative use of the proposed equipment for high-quality equipment.

Claims (1)

EQUIPMENT FOR TEMPORARY SYNCHRONIZATION OF SEISMIC EXPLORATION WORKS, consisting of half-kits for master and slave seismic stations and including a radio transmitting and receiving device and in each half-set a time-stamp storage unit containing a reference oscillation generator, a frequency divider, ¹ time-stamp synchronizer and ¹ time-stamp generator that, in order to reduce capital costs for seismic exploration, will complement The AND element and series-connected comparison circuit, switching element, memory unit, second switching element, control signal generator and inverter are introduced in parallel, while the output of the synchronization circuit is connected to both switching elements, the on-oscillator and frequency divider are connected to the comparison circuit and to the shaper of control signals, and the inverter output through the And element is connected to a frequency divider. SU. „, 1037195