RU6056U1 - NAVIGATION SYSTEM - Google Patents

Abstract

1. A navigation system for conducting marine seismic surveys, including a computer, receivers of satellite systems for determining the coordinates of an object, a log, gyrocompass, the outputs of which are connected to the input of a computer, a seismic station with pneumatic sources and a seismic spit and echo sounders, the outputs and inputs of which are connected respectively to the input and output of this computer, as well as a steering graphic display, the input of which is connected to the output of the computer, characterized in that it is equipped with a timer that records and adjusts the interval webbings between successive seismic signals fed directly during the passage of the profile of the test interval, the input of which is connected to the output of the computer, the output - to satellite receiver systems determine the coordinates of the object and the input seysmostantsii.2. The system according to claim 1, characterized in that the timer, adjusting the time interval between the supply of successive seismic signals directly during the passage of the studied section of the profile, is made up of a register, a clock and a data comparison element having inputs A and B, and is equipped with two single-vibrators, with this register input is connected to the output of the computer, the output is connected to the input A of the comparison element, the output of the clock is connected to the input B of the comparison element, one input of the clock is connected to the output of the computer, and the other to the output of the comparison element, otorrhea in turn connected to the inputs of two monostable multivibrator, one output of which is connected to the seismic recording, while the output of another - with a receiver-satellite positioning system obekta.3. The system according to p. 1, characterized in that as a computer installed personnel

Description

Navigation system.

The proposed utility model relates to automatic control systems for marine seismic surveying and is intended for navigating a vessel along a geophysical line with specified coordinates in the production of geological and geophysical surveys, mainly seismic exploration, and can also be used to ensure that the vessel is brought to a specific point during engineering work.

When conducting geological and geophysical research, the task is to ensure the most accurate passage of the given line of the geophysical profile (draft profile) by the vessel.

A well-known navigation system called SUSY 30/11 (INTEGRATED NAVIGATION SYSTEM ATLAS SUSY 30/11 AN 1057 A 005, MAITENANCE AND REPAIR INSTRUCTIONS, KRUPP ATLAS ELEKTRONIK, GEblMANY, 1987) f containing a specialized programmable computer (EPR 1100 processor with an interface) whose main function is to control geophysical surveying and navigation, connected to another specialized programmable computer (EPR 1300 processor) equipped with interface cards for connecting sensors (satellite system for determining the position of a vessel of the TRANSIT system (MAGNA VOX), echo sounders, dopp lerlag, inclinometer, gyrocompass) and actuators (autopilot, seismic station, steering monitor).

Also known is a navigation system called GIN-3 (USERS MANUAL, CGG, FRANCE), also containing a specialized programmable computer (HEWLETT PACKARD 8940 V Multiprogrammer), the main function of which is to collect inMKI: G 05 D 1/00, G 01C 23/00

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formations from appropriate sensors and the transmission of control signals of the seismic station, connected to another specialized computer (HEWLETT PACKARD A 800), whose main function is to control geophysical surveying and navigate the vessel by profiles.

As sensors, this system contains satellite receivers of the DGPS, HYPERFLIX or MULTI-REF system, induction log, gyrocompass, echo sounders. As actuators - seismic station and steering graphic display.

The navigation system drives the ship along seismic profiles with given coordinates and generates seismic station commands for the emission of elastic wave pulses (seismic signals) in time or in accordance with the distance traveled. At the same time, both well-known navigation systems set the time interval that determines the magnitude of the studied segment of the seismic profile that the vessel must pass from the moment of supplying one seismic signal to the moment of feeding the other, using a computer based on the data received by it (computer) during the passage of the previous section of the profile.

However, the actual speed of the vessel during the passage of the studied section of the profile may be different than that was established at the time of the task (calculation and recording) of the time interval for the specified section of the profile. This leads to the fact that the vessel actually passes a greater or lesser length than was necessary for a given profile project, and thereby significant errors are introduced into the implementation of this project. In addition, the freezing of the control computer or an accidental malfunction in its operation leads to the cessation of the formation of signals to launch the seismic station, which in turn leads to the cessation of seismic surveys and the descent of the vessel from the profile.

Another disadvantage of the known navigation systems is the low productivity of the computers included in their composition, which leads to uneven sending of seismic signals (delay can be up to O, 5 sec), which also introduces errors in the implementation of the profile project.

In addition, despite the presence in the known navigation systems of sensors of the satellite system for determining the position of the vessel, the interval for the supply of seismic signals using these systems is determined only on the basis of the Doppler data, which leads to an increase in discrepancies and errors in the passage of the profile associated with the error in determining the position of the vessel.

The main technical problem, which the proposed utility model is aimed at, is to provide the ability to adjust the time interval between the supply of successive seismic signals directly during the passage of the studied section of the profile, as well as to continue to work when the control computer restarts in the event of a freeze or crash.

Another task is to increase the speed of the navigation system and provide the ability to connect sensors with and without a serial interface to it.

Another objective is to increase the accuracy of determining the position of the vessel during rolling.

- 3 navigation system for conducting marine seismic surveys, including a computer, receivers of satellite systems for determining the coordinates of the object, log, gyrocompass, the outputs of which are connected to the input of the computer, a seismic station containing seismic sources and a seismic beam, and echo sounders, outputs and inputs of which are connected respectively to the input and the output of this computer, as well as a graphic steering monitor, the input of which is connected to the output of the said computer, which, according to the proposed technical solution, is equipped with a timer, egistriruyuschim and correcting the time interval between the feeding of successive seismic signals directly during the passage of the profile of the test interval, the input of which is connected to the output of the computer, the output - to a receiver of satellite positioning systems of the object and an input seismic.

Another problem is solved by the fact that a personal computer is installed as a computer, additionally equipped with at least two interface boards for connecting sensors that do not have a serial interface, a digital board, for connecting sensors having a serial interface and a control board, while the input of the steering wheel graphic monitor , the second input and two outputs of the seismic station are connected to the outputs of the digital board, the third output of the seismic station and the input of one echo sounder are connected to the output of the control board.

Another problem is solved by the fact that the navigation system is equipped with an inclinometer, the output of which is connected to the input of the computer.

computer input, which allows you to work with two types of numbering: dead reckoning along the induction lag and gyrocompass and dead reckoning along the doppler and gyrocompass.

For automatic control of the vessel on the profile, the system is additionally equipped with an autopilot, the input of which is connected to the output of the computer to collect information.

To determine the exact coordinates of the position of the pneumatic sources and the end of the seismic streamer, which are components of the seismic station, the navigation system is additionally equipped with receivers of the satellite system for determining the coordinates of the object, installed one at a time on the lines of the pneumatic sources, and the end buoy of the seismic streamer.

A timer that registers and corrects the time interval between the supply of successive seismic signals directly during the passage of the studied section of the profile is made of three elements, one of which is a register and is designed to record the time required to pass the studied section of the profile at each time point of passage of this section, the other is a clock designed to record real time from the moment the previous seismic signal was fed, the third is a data comparison element having input odes A and B, and is equipped with two single vibrators, with the input of the register connected to the computer, the output to the input A of the comparison element, the output of the clock connected to the input B of the comparison element, one input of the clock connected to the computer, and the other to the output of the comparison element, the output of which, in turn, is connected to the inputs of both single-vibrators, the output of one of which is connected to the seismic station, and the output of the other to the satellite receiver

ANYWHERE object location system.

As a digital card, a card having at least 8 communication channels can be installed.

The proposed navigation system can be equipped with an additional computer connected to the main computer, and connected to it printing devices, plotters and digital tables.

Thus, the presence of the timer described above allows, on the one hand, to provide constant adjustment of the transit time of the studied segment (linear interval) of the profile between two consecutive seismic signals, which increases the accuracy of this linear interval; on the other hand, the presence of a timer connection with the receiver of the satellite system for determining the position of the object installed on board the vessel allows you to record the start time of the seismic station for the supply of seismic signals with an accuracy of 0.000001 sec. on the world time scale, which in turn allows you to determine the exact coordinates of the pneumatic sources and the end of the seismic streamer and also increase the accuracy of the project profile. In addition, the presence of a timer, as a separate element of the system, allows you to continue working on the profile when the computer freezes up or crashes, because it allows you to save the last time correction for the studied profile interval and carry out the next seismic station starts at time intervals corresponding to this correction. If the computer stopped for no more than 1-2 minutes, then it is possible to continue working on the profile after restarting the computer.

- b Use as a computer for collecting information and controlling the geophysical survey of a personal computer equipped with at least two interface cards for connecting sensors that do not have a serial interface, a digital board having at least 8 channels for connecting sensors having a serial interface and control board, allows you to increase the reliability of the navigation system due to the fact that the functions of two computers (a computer for collecting information and a computer for control geophysical survey) is performed by one personal computer, which, in comparison with specialized computers, provides the operator with the opportunity to work not only with navigation programs, which is important both for preparing and changing the project of work, and for processing the received materials.

The presence in the computer of at least two additional interface cards for connecting sensors that do not have a serial interface and a digital board with at least 8 channels for connecting sensors having a serial interface allows you to expand the ability to connect a wide variety of sensors, including domestic production, and also allows you to transfer navigation data to several external computers to solve other navigation problems. A personal computer also allows you to install a digital board with a large number of communication channels, which provides the ability to connect an additional gyrocompass, gravimeter and other sensors.

- 7 allows you to more accurately determine the location of the vessel during rolling, relying not on the position of the antennas of satellite receivers (receivers of the satellite system for determining the position of the object), but on the position of the center of mass of the vessel, which increases the accuracy of determining the coordinates of the vessel when performing the profile. The presence of an autopilot in the proposed navigation system allows not only automatic control of the vessel on the profile, but also when entering it.

The presence in the proposed system of an additional computer with connected printing devices, plotters and digital tables allows you to control the quality of work with simultaneous output of information to print.

The essence of the proposed utility model is illustrated by graphic materials, where Fig. 1 is a block diagram of a navigation system, and Fig. 2 is a functional diagram of a timer.

The proposed navigation system contains (Fig. 1) a main computer 1, equipped with a control board 2, interface cards 3 and 4, a digital board 5, and also a seismic station b, consisting of the seismic station itself, the seismic cable, and air sources (the seismic cable and air sources are not indicated on the diagram ), the main receiver 7 of the satellite system for determining the coordinates of the object (hereinafter the satellite receiver), an auxiliary satellite receiver (or the MULTI-REF system) 8, the receiving antennas of which are installed on the antennas of the vessel, satellite receivers 9, are installed one by one on the lines of pneumatic sources (not shown on the diagram) and on the end buoy of seismic streamers (buoy and seismic streamer are not indicated on the diagram), echo sounders 10 and 11, induction log 12, gyrocompass 13, inclinometer 14, computer 15 quality control system, printer 16 , plotter 17, digital table 18, steering graphic display 19, timer 20 mounted on the control board 2, autopilot 21, doppler sensors 22 and 23.

Sesostantion 6 has two inputs, one of which is connected to a digital board 5, and the second with a timer 20 belonging (connected) to the main computer, and three outputs, two of which are connected to a digital board 5, and the third - to the control board 2. Satellite receivers 7.8 mounted on board the vessel have outputs connected to the digital board 5, and receiver 7 also has an input connected to the timer 20. Satellite receivers 9 have outputs connected to a digital board 5. The fish finder 10 has an output and an input connected to the digital board 5, the echo sounder 11 (at least one) has an output connected to the interface board 3, and an input connected to the control board 2. Induction lag 12 has an output connected to the interface board 3. Gyrocompass 13 and inclinometer 14 have outputs connected to the interface board 4. The computer 15 of the quality control system has inputs connected to the digital board 5 of the main computer 1, the output of the digital table 18, and outputs connected to the printer 16 and the plotter 17. The steering graphic display 19 has an input connected to the digital board 5. Autopilot 21 has an input connected to the control board 2. The Doppler sensor 23 has an output connected to the interface board 3, and the Doppler sensor 22 has an output connected to the digital board 5.

- 9 Pentium computers (any computers capable of additionally installing at least 4 interface cards into it) can be installed; as a computer 15 of the quality control system, a Pentium computer (or any other that can be used as the main one) is also installed; as interface cards 3.4, original boards are installed that are designed and made of well-known blocks (for example, an address decoder, bus driver, status register), taking into account the need to connect specific known sensors (doppler DOLOG 12D, echo sounders DESO 20, NEL-ZM, PEL -4, gyrocompasses SPERRY 37, ANSHUTZ Standart 4, VEGA, induction lag IEL -2M, inclinometer of any brand); as control board 2, an original board is installed, designed and made of known blocks (for example, address decoder, bus driver, status register) taking into account the connection of the autopilot 21 (for example, DECCA), timer 20, echo sounder 11, satellite receiver 7 and seismic station b . DGPS receivers (or MULTI-REF system as receiver 8) can be installed as satellite receivers 7.8, and GPS as receiver 9. As a digital board 5, a DigiBoard PC / 8e board is installed, which has V input / output RS-232 ports (a DigiBoard PC / 16e board or several DigiBoard PC / Be boards can also be installed).

The timer 20 contains (FIG. 2) a register 24, a clock 25 and a comparison element 26, and is equipped with single vibrators 27.28. The output Q of the register 24 is connected to the input A of the comparison element 26, the output Q1 of the clock 25 is connected to the input B of the comparison element 26.

- 10 The output of the comparison element 26 is connected to the input R of the clock 25, as well as to the inputs of the single vibrators 27.28. The input D of the register 24 is connected to the control board 2 (bus driver, not shown in the diagram), and the CS input of the register 24 is also connected to the control board 2 (address decoder not indicated in the diagram). The input from clock 25 is connected to the control board 2. The output of the single vibrator 28 is connected to the input of the satellite receiver 7, and the output of the single vibrator 27 is connected to the input of the seismic station 6.

The work of the proposed navigation system is controlled by original programs, for example, resident, with the help of which the so-called background navigation is carried out and which works continuously, a number of programs that enable the vessel to enter the profile and work on the profile, as well as other programs.

The described system works, for example, in the following modes:

1. Background navigation:

When the navigation system is in this mode, the main computer 1 takes information from the following sensors: satellite receivers 7 and 8, echo sounders 10 and 11, doppler sensors 22.23, induction lag 12, gyrocompass 13, inclinometer 14 and seismic station b (about the position of the seismic streamer) and provides information about the location of the vessel on the graphic monitor 19 steering.

2. The ship's approach to the profile:

When the navigation system in this mode, the main computer 1 removes information from the same sensors as when working in the background. In this case, the main computer 1, on the basis of the program laid down in it, provides information on the options for the vessel to enter the profile (in the form of graphic pictures) and position on the graphic monitor 19 of the steering operator

- 11 seismic streamers.

3. Ship operation on a geophysical profile:

When the vessel passes the geophysical profile along a predetermined route (draft profile), the navigation system drives the vessel along this profile with the given coordinates and generates seismic station 6 commands to emit pulses of elastic waves (seismic signals) at the starting point of the profile and after the vessel passes each predetermined section way (of the studied interval), while the echo sounders 10.11 and all other sensors receive from the outside and transmit information to computer 1. For this, after the vessel is brought to the starting point ofilya host computer 1 supplies a signal to the seismic station b, which performs run air gun (not indicated in the diagram) producing the first (and subsequent) seismic signal (burst). The next seismic signal is fed after the vessel passes the linear interval determined in accordance with the assignment (project) (the investigated section of the track). To do this, based on data on the speed of the vessel and the actual external environment (wind speed, currents, waves, and other noise affecting the movement of the vessel) received on computer 1 from the corresponding sensors (the same as when the system was running in the background , and satellite receivers 9) at each moment of time, computer 1 also at each moment of time generates the value of the time interval (time interval code - the length of time at the moment for which the vessel can currently pass a given linear interval), after which should be produced the next seismic signal (explosion). This code comes from control board 2

- 12 computers 1 to the input D of the register 24 of the timer 20. At the same time, the clock 25 counts the current time from the previous explosion. Information (in the form of numbers) from register 24 goes to input A, and information (also in the form of numbers) from element 25 goes to input B of comparison element 26. Comparison element 26 compares the numbers received at inputs A and B, and as soon as the number coming from element 25 becomes larger than the number coming from register 24, element 26 generates a signal that, through the single-vibrator 27, goes to seismic station 6 to start the seismic sources. At the same time, the signal from the element 26 is fed to the input R of the element 25 to zero and start a new time interval and through the one-shot 28 to the main satellite receiver 7 to request information about world time.

When the navigation system is operating in the profile mode, the input (from the control board 2) receives the frequency (quartzized) of the computer generator 1 from the control board 2, and the recording of the current linear interval code is sent to the CS input 24 of the register. Seismic station 6 sends a signal to the control board 2 of computer 1, confirming the operation of the pneumatic sources.

Thus, due to the operation of a new block, a timer 20, which is absent in the known navigation systems, a constant adjustment of the passage time of the studied segment (linear interval) of the profile and, accordingly, the time interval of the supply of the next seismic signal is ensured, which increases the accuracy of this linear interval and, accordingly, the entire profile; In addition, the registration of the moment of launch of the seismic station 6 for the supply of seismic signals with an accuracy of up to 0.000001 sec is provided. on the world time scale (accuracy is determined by the parameters of satellite receiver 7, in the specific case of DGPS), which in turn allows you to determine the exact coordinates of the air sources and the end of the seismic streamer and also increase the accuracy of the profile project. The presence of a timer 20, as a separate element of the system, allows you to continue working on the profile when the main computer 1 hangs or crashes, because it allows you to save the last time correction of the studied profile interval, tied to the world time scale, and carry out the next (after the computer freezes) seismic station launch at a time interval corresponding to this adjustment. If the stop of computer 1 lasted no more than 1-2 minutes, then it is possible to continue working on the profile after it is restarted.

The use as a computer 1 for collecting information and controlling the geophysical survey of a personal computer also allows to increase the accuracy of profile passing due to the speed of the computer, which ensures the passage of control signals with a lower delay than in known navigation systems; to increase the reliability of the navigation system due to the fact that the functions of two computers (a computer for collecting information and a computer for controlling geophysical surveys) are performed by one personal computer. Compared to specialized computers, a personal computer provides the operator with the opportunity to work not only with navigation programs, which is important both for preparing and changing the design of work, and for processing the materials received.

The presence in the computer of at least two interface cards 3.4 for connecting sensors that do not have a serial interface and a digital board 5 having at least 8 channels for connecting sensors having a serial interface allows you to expand the ability to connect a wide variety of sensors, including domestic production, and also allows you to transfer navigation data to several external computers to solve other navigation problems. Personal computer 1 also allows you to install a digital board 5 with a large number of communication channels, which provides the ability to connect an additional gyrocompass, gravimeter and other sensors.

The presence in the proposed navigation system inclinometer

14 allows you to more accurately determine the location of the vessel during rolling, relying not on the position of the antennas of satellite receivers 7.8, but on the position of the center of mass of the vessel, which increases the accuracy of determining the coordinates of the vessel when performing the profile. The presence of autopilot 21 in the proposed navigation system allows not only automatic control of the vessel on the profile, but also when entering it.

The presence in the proposed system of an additional computer

15c, connected to it by a printing device 16, a plotter 17, and a digital table 18, it is possible to control the quality of work performed while printing information.

- 15 FORMULA

Claims (5)

1. A navigation system for conducting marine seismic surveys, including a computer, receivers of satellite systems for determining the coordinates of an object, a log, gyrocompass, the outputs of which are connected to the input of a computer, a seismic station with pneumatic sources and a seismic spit and echo sounders, the outputs and inputs of which are connected respectively to the input and output of this computer, as well as a steering graphic display, the input of which is connected to the output of the computer, characterized in that it is equipped with a timer that records and adjusts the interval webbings between successive seismic signals fed directly during the passage of the profile of the test interval, the input of which is connected to the output of the computer, the output - to a receiver of satellite positioning systems of the object and an input seismic.  2. The system according to claim 1, characterized in that the timer, adjusting the time interval between the supply of successive seismic signals directly during the passage of the studied section of the profile, is made up of a register, a clock and a data comparison element having inputs A and B, and is equipped with two single-vibrators while the input of the register is connected to the output of the computer, the output is connected to the input A of the comparison element, the output of the clock is connected to the input B of the comparison element, one input of the clock is connected to the output of the computer, and the other to the output of the comparison element , which in turn is connected to the inputs of both single-vibrators, the output of one of which is connected to the seismic station, and the output of the other to the receiver of the satellite system for determining the coordinates of the object.  3. The system according to claim 1, characterized in that a personal computer is installed as a computer, additionally equipped with at least two interface boards for connecting sensors that do not have a serial interface, a digital board for connecting sensors with a serial interface, and a control board, wherein the input of the steering graphic monitor, the second input and two seismic station outputs are connected to the digital board outputs, the third seismic station output and one sounder input are connected to the control board output .  4. The system according to claim 1, characterized in that it is additionally equipped with an inclinometer, at least one doppler and one installed on the lines of air sources and the end buoy of seismic streamers by receivers of the satellite system for determining the coordinates of the object, the outputs of which are connected to the input of the computer, as well as autopilot whose input is connected to the output of the computer control board. 5. The system according to claim 1, characterized in that it is equipped with an additional computer, the input of which is connected to the output of the main computer, and connected to it printing devices, plotters and digital tables.