JP2018084445A - Underwater acoustic positioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an underwater acoustic positioning system which can accurately correct the position of an autonomous underwater robot moving in the water, without requiring any operations to be done.SOLUTION: The underwater acoustic positioning system according to the present invention can stably increase the density and the accuracy of acquiring positional data for an underwater part only by using an acoustic response signal based on a question signal from the underwater part, without requiring an operator to conduct a sending work or operational processing in an on-water part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an underwater acoustic positioning system that can move underwater, for example, an operation-free and highly accurate correction of the position of an autonomous underwater robot.

  For example, an autonomous underwater robot that can move on the water can acquire its position from a signal from GPS. However, autonomous underwater robots that move underwater may not receive signals from GPS, so inertial navigation is often used to calculate position by estimation by combining your own speed and heading data. ing. In many cases, the speed of the autonomous underwater robot is calculated from a ground speedometer, and the direction is calculated from a magnetic compass or a gyro sensor. However, there were the following problems.

  The ground speedometer emits sound waves from the autonomous underwater robot itself toward the seabed, receives the reflected waves, and calculates the speed based on the principle of the Doppler effect. However, there is a limit to the distance to the seabed where the reflected wave can be received depending on the model of the autonomous underwater robot and the frequency of sound waves transmitted. Therefore, the calculation method cannot calculate the speed in the sea area exceeding the limit distance, and as a result, cannot calculate an accurate position.

  Regarding the orientation, the method using a magnetic compass has a disadvantage that the orientation accuracy is not so good, although the cost of the product itself can be kept low because the product itself is inexpensive. The method using the gyro sensor can obtain a highly accurate bearing, but the purchase price is very expensive. Also, even if the physical attachment error of the gyro sensor can be made minute, it is difficult to make it completely zero. For this reason, during long-distance navigation, fine errors are accumulated, resulting in a large navigation error. In order to reset this accumulated error, the autonomous underwater robot had to rise and received position data from GPS again.

  FIG. 3 is a diagram for explaining an example of determining the position of a conventional autonomous underwater robot. In FIG. 3, for example, the autonomous underwater robot 31 can navigate the underwater 30 freely. The underwater 30 is provided with, for example, two underwater transboners 32 and 33 at a predetermined interval. For example, the two underwater transponders 32 and 33 installed on the seabed serve as reference stations and return acoustic response signals 321 and 331 to the acoustic interrogation signals 311 and 312 to the autonomous underwater robot 31. The autonomous underwater robot 31 can calculate its own position based on the acoustic interrogation signals 311 and 312. Other acoustic positioning systems include the baseline acoustic positioning system (LBL navigation) or the GPS position of a support vessel on the water and the relative position of the autonomous underwater robot equipped with a transponder in terms of arrival time and direction of sound waves. There is a short baseline acoustic positioning system (SSBL navigation) to calculate, or an ultrashort baseline acoustic positioning system (USBL navigation). However, these also have the following problems.

  The long baseline acoustic positioning system has the disadvantage that it requires two transponders to be installed, which requires a lot of preparation and cost before operation. In addition, the location of the installation uses the position information of the GPS at the time of input, but there is a disadvantage that the position is shifted by the ocean current or the like from the time of input to the time of landing. In this method, it is difficult to determine the exact position of the transmitter that has landed. In addition, the transponder has a drawback that the error becomes more prominent as the water depth of the sea area is larger.

  FIG. 4 is a diagram for explaining an example of using a support ship when determining the position of a conventional autonomous underwater robot. In FIG. 4, the autonomous underwater robot 41 sends back an acoustic response signal 411 based on the acoustic interrogation signal 421 from the support ship 42, and is received by the upper ship acoustic receiver 422. The ship upper acoustic transducer 422 is arranged as shown in the figure. In the case of the short baseline acoustic positioning system or the ultra-short baseline acoustic positioning system, only the upper part for wave transmission / reception is installed on the support ship 42, so it takes less time for preparation before operation than the long baseline acoustic positioning system. . However, in the system shown in FIG. 4, the acoustic interrogation signal 421 transmitted from the support vessel 42 responds to the transponder mounted on the autonomous underwater robot 41, and the response signal is received as an acoustic response signal by the support vessel 42. ing. Since the system calculates the position from the propagation time and the phase difference between the receiving arrays, the transponder equipped with the autonomous underwater robot 41 receives the acoustic interrogation signal from the support ship 42 depending on the thruster rotation of the autonomous underwater robot 41 and the external noise environment. 421 cannot be received correctly. As a result, the system cannot obtain an accurate position.

  Also, if positioning is impossible, or if positioning becomes impossible, the autonomous underwater robot's own inertial navigation will be used.However, if the time interval between positioning or the positioning impossible time increases, the position error of the autonomous underwater robot will increase. Is equivalent to inertial navigation error. In particular, for autonomous underwater robots that use a magnetic compass that does not use a gyro sensor, inertia errors are inherently large, so the time interval between these external position corrections is shorter in order to navigate accurately. desirable. Further, when performing position correction, the system needs to perform transmission work with each operator intervening.

  In addition, since GPS radio waves or light do not reach the seabed accurately, it is difficult to observe the degree of variation or crustal deformation even in shallow seabeds. The structure change or crustal movement on the sea floor is obtained by determining the position of the support ship 42 by GPS or the like, and obtaining information by the acoustic response signal 411 to the acoustic question signal 421 from the support ship 42 to the autonomous underwater robot 41. Is possible. However, since the speed of sound of the acoustic signal in the sea changes from time to time depending on seawater temperature, salinity concentration, etc., it has been difficult to accurately grasp in time and space. On the other hand, the observation device installed on the support ship 42 moves in at least three directions of rolling, pitching, and yawing, and the position of the acoustic transducer 422 of the support ship 42 that emits an acoustic signal is accurately determined. It was difficult to decide.

  In the above example, an ID code and a ranging signal are transmitted from the support vessel 42, and then received by the autonomous underwater robot 41, and all the ranging signals are returned with the same ID code. Since the transmission / reception time for the exchange of data takes a long time, accurate data could not be obtained when changes in seawater temperature and salinity concentration are not constant.

  Therefore, in the invention according to Japanese Patent Application No. 2013-102097 (filed on May 14, 2013) proposed by the present applicant, the support ship sends the same ranging signal to the autonomous underwater robot with the same ID code. The autonomous underwater robot sent the ID code and the same distance measurement signal to the support ship.

JP 2014-222200 A

  In the invention described in the application, the support ship transmits the ID code S1 and the ranging signal M toward one of the autonomous underwater robots. The autonomous underwater robot transmits an ID code S6 (predetermined by the Japan Coast Guard) and a ranging signal M as response signals to the support ship. Similarly, the support ship sequentially transmits and receives to other autonomous underwater robots. The ID code S6 and the ranging signal M are transmitted from each underwater part to the upper part of the ship with a time difference of 10 seconds, for example. Sending and receiving data between such support vessels and autonomous underwater robots is not only time consuming, but the data obtained with the first autonomous underwater robot and the data obtained with the last autonomous underwater robot are the seawater temperatures. In addition, since it is in a different state depending on the salinity concentration, the position and inclination of the ship (pitching, etc.), there is a drawback that accuracy is lacking.

  The acoustic signal returned from the autonomous underwater robot is received by the acoustic transducer, and then the position of the autonomous underwater robot is calculated by GPS or the like provided in the support ship. The GPS and the like are based on GPS observation data on land. The observation can be performed every few months, for example, to determine how the position of the autonomous underwater robot has changed.

  The underwater acoustic positioning system transmits acoustic signals all at once from the acoustic transducer toward a plurality of autonomous underwater robots installed on the sea floor from the support vessel. Thereafter, the autonomous underwater robot that has received the acoustic signal from the transducer sends response data almost simultaneously toward the support ship. The acoustic signals of each autonomous underwater robot received by the support ship are collected with a slightly different time difference depending on the position (distance). The data can be processed by a data processor (not shown) to obtain position information of the autonomous underwater robot. In the conventional underwater acoustic positioning system, the measurement results return almost simultaneously from each autonomous underwater robot with a single call from the support vessel, so conditions such as seawater temperature and salinity change from moment to moment. Previous data can be obtained efficiently.

  In recent years (after the Great Tohoku Earthquake), the probability of a large earthquake occurring has increased. It is possible to predict the earthquake in the near future by accurately observing the crustal deformation of the seabed. The crustal movement of the sea floor in the shallow water cannot be observed by radio waves or light, and therefore there is no means other than using an acoustic signal. However, as described above, the speed of the acoustic signal not only changes depending on the seawater temperature, the salinity concentration, the state of the shipboard station, etc., but it is easy to pick up various noises that are derived temporally and spatially.

  In order to solve the problems as described above, the present invention provides a stable positioning resistant to a noise environment by, for example, a system that can transmit a question signal from an autonomous underwater robot to a support ship in an underwater part. It is possible to construct a completely self-supporting drone system that does not involve an operator during exploration.

(First invention)
The underwater acoustic positioning system according to the first aspect of the present invention can accurately obtain position information of the underwater part based on GPS by transmitting an acoustic interrogation signal from the underwater part to the upper part of the water. An underwater portion that transmits a question signal and receives position information based on the acoustic question signal as an acoustic response signal; an acoustic response signal from the underwater portion that receives an acoustic question signal from the underwater portion; Based on the transmitted water upper part and the acoustic interrogation signal from the underwater part, for calculating the exact position of the underwater part based on the position signal transmitted from the GPS toward the underwater part It comprises at least a data processing device provided in the underwater part that performs processing.

(Second invention)
The underwater acoustic positioning system of the second invention is characterized in that the underwater part is an autonomous underwater robot.

(Third invention)
The underwater acoustic positioning system of the third invention is characterized in that the upper part of the water is composed of an unmanned surface station having at least an iridium antenna and / or a GPS antenna.

(Fourth invention)
The underwater acoustic positioning system of the fourth invention is characterized in that the data processing device includes a Kalman filter.

  According to the present invention, the autonomous underwater robot itself corrects based on the acoustic response signal returned from the support ship by providing the acoustic receiving array and the signal processing function on the underwater part, for example, the autonomous underwater robot side. Since position data can be generated, it is not necessary for the operator to perform transmission work, and the degree of freedom of work on the support ship can be increased.

  According to the present invention, for example, a method of sending a question signal from the autonomous underwater robot side and calculating its own position from the response signal is the same as the baseline acoustic positioning (LBL navigation). By passing the result through a Kalman filter, it is possible to remove erroneous positioning information due to multipath or the like, and it is possible to calculate correction position data with higher accuracy.

FIG. 1 is a schematic diagram for explaining an example in which an acoustic response signal composed of a position signal is returned in response to an acoustic interrogation signal from an autonomous underwater robot according to an embodiment of the present invention. FIG. 2 is a schematic block diagram for explaining an example of an autonomous underwater robot and a surface station in the embodiment of the present invention. FIG. 3 is a diagram for explaining an example of determining the position of a conventional autonomous underwater robot. FIG. 4 is a diagram for explaining an example of using a support ship when determining the position of a conventional autonomous underwater robot.

(First invention)
In the underwater acoustic positioning system of the present invention, a process for accurately obtaining the position information of the underwater part is performed for the first time by transmitting an acoustic interrogation signal from the underwater part to the upper part of the water. The underwater part transmits an acoustic interrogation signal toward the upper part of the water. The upper part of the water returns position information as an acoustic response signal to the underwater part based on the acoustic interrogation signal. The upper part performs processing for transmitting position information based on GPS toward the underwater part based on the acoustic interrogation signal. The underwater portion can know its position accurately by autonomously performing a calculation process based on the position information. That is, the underwater part transmits an acoustic interrogation signal to the upper part of the water, and receives a modem message including position information responded from the upper part of the water, without human or mechanical assistance of the upper part, Position correction can be performed by own calculation processing. In this specification, autonomous means that it is controlled by a program set up by itself without being controlled from the outside.

(Second invention)
In the underwater acoustic positioning system of the second invention, the underwater part is composed of an autonomous underwater robot, and it is possible to accurately calculate the position of itself according to the position request from the autonomous underwater robot side. .

(Third invention)
The underwater acoustic positioning system according to a third aspect of the present invention includes an unmanned surface station having at least an iridium antenna and / or a GPS antenna on the water. The unmanned surface station can be an inexpensive station because it requires only a simple operation of sending back position information based on GPS or the like by an acoustic interrogation signal from the underwater part. The surface station can receive satellite signals of Iridium / GPS without interruption, and can supply power to the antenna.

(Fourth invention)
The underwater acoustic positioning system of the fourth invention includes a Kalman filter in the underwater part. Autonomous underwater robots are used when estimating the amount of change from moment to moment based on observations with discrete errors, such as position information. The information with discrete errors exhibits an effect in the water that changes every moment by using a Kalman filter provided in the autonomous underwater robot. That is, the Kalman filter can calculate the estimated state of the current time from the estimated state of the previous time in the autonomous underwater robot.

  FIG. 1 is a schematic diagram for explaining an example in which an acoustic response signal composed of a position signal is returned in response to an acoustic interrogation signal from an autonomous underwater robot according to an embodiment of the present invention. In FIG. 1, the surface station 11 is an unmanned station having a water surface 111 on the water surface and at least an iridium / GPS antenna 112 provided thereon. The Iridium / GPS antenna 112 referred to in this specification refers to satellite communication using an Iridium satellite. The surface station 11 is equipped with the iridium / GPS antenna 112, and can transfer data via satellite communication when the autonomous underwater robot 12 floats on the water surface. GPS, on the other hand, provides a position in earth coordinates to a device equipped with a receiving antenna using a satellite. Since the surface station 11 has a positive buoyancy, the surface station 11 always floats on the surface of the water. Therefore, it is possible to receive GPS and Iridium satellite signals without interruption. In addition, power can be supplied to the antenna.

  For example, the autonomous underwater robot 12 travels or floats underwater or on water. The autonomous underwater robot 12 includes a transducer 125 that transmits an acoustic interrogation signal 122 to the surface station 11 and receives an acoustic response signal 123 transmitted from the surface station 11. The transducer 125 is provided with at least three acoustic receiving arrays. In other words, in this embodiment, the autonomous underwater robot 12 in the underwater has the transducer 125 for acoustic communication, and the iridium / GPS antenna 112 is installed in the unmanned surface station 11 that is above the water.

  The autonomous underwater robot 12 sends an acoustic interrogation signal 122 to the unmanned surface station 11 and receives a modem message including position information responded from the surface station 11, whereby the autonomous underwater robot 12 autonomously Position correction can be performed.

FIG. 2 is a schematic block diagram for explaining an example of an autonomous underwater robot and a surface station in the embodiment of the present invention.
2, the surface station 11 includes at least an acoustic communication transducer 113, an acoustic signal receiving circuit 114, an acoustic response signal generating circuit 115, a GPS position / time signal generating circuit 116, and an acoustic signal transmitting circuit 117. The acoustic interrogation signal 122 from the autonomous underwater robot 12 is received by the acoustic communication transducer 113. The acoustic interrogation signal 122 received by the acoustic communication transducer 113 passes through the acoustic signal reception circuit 114 and is combined with the signal of the GPS position / time signal generation circuit 116, and the acoustic response signal generation circuit 115 A response signal is generated. The acoustic response signal is transmitted to the autonomous underwater robot 12 as the acoustic response signal 123 from the acoustic communication transducer 113 via the acoustic signal transmission circuit 117.

  The autonomous underwater robot 12 includes an acoustic receiving array 125, an acoustic signal receiving circuit 126, an acoustic signal processing circuit (distance / arrival angle calculation) 127, a position / azimuth arithmetic processing circuit (latitude / longitude, processing) 128, and a Kalman. It comprises at least a filter 129, correction position data 130, a timing control circuit 131, an acoustic signal transmission circuit 132, and an acoustic communication transducer 133. The acoustic response signal 123 from the surface station 11 is received by the acoustic receiving array 125. The acoustic receiving array 125 is composed of, for example, four pieces as shown in the figure, and a magnetically shielded azimuth magnet (not shown) is placed at the center point of the coordinates, and they are connected so as to be perpendicular to each other. Moreover, the said magnetic-shielding direction magnet is connected to the autonomous underwater robot by the waterproof cable etc. which are not shown in figure.

  Since the acoustic receiving array 125 is connected so as to be perpendicular to the center of the magnetic-proof azimuth magnet, it is possible to know an accurate azimuth and direction in water. In this specification, an azimuth is defined as an angle on a horizontal plane, and a direction is defined as an angle in the depth direction of the water surface.

In FIG. 2, the acoustic receiving array 125 is assumed to have a distance L. Sound waves from the sound source are respectively received by the acoustic receiving array 125 with an arrival angle θ. The distance of the autonomous underwater robot 12 is calculated based on the arrival angle θ and the arrival time difference δT.
δT × sonic velocity (C) = distance (L) × cos θ
θ = arccos (δT × C / L)
Can be calculated as
For the sake of easy explanation, the calculation is only the orientation of the horizontal plane, but the direction in the depth direction can be calculated by a similar calculation process.

  In FIG. 2, the acoustic response signal received by the acoustic receiving array 125 is received by the acoustic signal receiving circuit 126. The acoustic signal received by the acoustic signal receiving circuit 126 is processed by an acoustic signal processing circuit (distance / arrival angle calculation) 127. The calculated distance and arrival angle are processed by a position / orientation calculation processing circuit (latitude / longitude, azimuth) 128.

  Data processed by the position / orientation calculation processing circuit (latitude / longitude, azimuth) 128 is corrected by the Kalman filter 129 and then output as correction position data. On the other hand, the timing control circuit 131 sends a timing signal to the acoustic signal processing circuit (distance / arrival angle calculation) 127 and the acoustic signal transmission circuit 132. The acoustic communication transducer 133 transmits the acoustic interrogation signal 122 based on the timing.

  The Kalman filter referred to in the present invention has been proposed by Rudolf Kalman, and is used to estimate an amount that changes with time from observations having discrete errors. In the present invention, the Kalman filter used, for example, integrates erroneous information from a gyro sensor or a ground speed meter built in an autonomous underwater robot, and changes autonomously in water. It has been found that it has a great effect when used to estimate the position of the underwater robot.

  As mentioned above, although the Example of this invention was explained in full detail, this invention is not limited to the said Example. The present invention can be modified in various ways without departing from the scope of the claims. The ship upper part, surface station or underwater part, autonomous underwater robot, transmission / reception device, data processing device, etc. of the present invention are composed of known mechanical engineering, communication engineering, and acoustic engineering technology. Modifications can be made without departing from the above range.

11 ··· Surface Station 111 ··· Upper part 112 · · Iridium · GPS antenna 12 · · · Autonomous underwater robot 122 · · Acoustic interrogation signal 123 · · Acoustic response signal 125 · · Transceiver

Claims (4)

In the underwater acoustic positioning system that can accurately obtain the position information of the underwater part based on GPS by transmitting an acoustic interrogation signal from the underwater part to the upper part of the water,
An underwater portion for transmitting an acoustic interrogation signal to the upper part of the water, and receiving position information based on the acoustic interrogation signal as an acoustic response signal;
The water upper part that receives the acoustic interrogation signal from the underwater part and transmits an acoustic response signal composed of position information toward the underwater part,
Based on the acoustic interrogation signal from the underwater part, the underwater part performs processing for calculating an accurate position of the underwater part based on the position signal transmitted from the GPS toward the underwater part. A data processing device provided in
An underwater acoustic positioning system characterized by comprising at least.   The underwater acoustic positioning system according to claim 1, wherein the underwater portion is an autonomous underwater robot.   The underwater acoustic positioning system according to claim 1 or 2, wherein the upper part of the water includes an unmanned surface station having at least an iridium antenna and / or a GPS antenna.   The underwater acoustic positioning system according to any one of claims 1 to 3, wherein the data processing device includes a Kalman filter.