CN212513017U - Mapping system for realizing underground river mapping under combined navigation condition - Google Patents

Abstract

A surveying and mapping system for realizing underground river surveying and mapping under the condition of integrated navigation comprises a cableless underwater robot AUV and an unmanned aerial vehicle; the lower end of the unmanned aerial vehicle is provided with a high-precision directional sound wave detection device; the unmanned aerial vehicle is provided with a photographing system; the unmanned aerial vehicle is provided with a laser range finder; the AUV is provided with a complete Beidou positioning resolving device. The utility model discloses with the underground exploration field of satellite navigation technique popularization, play very big promotion and impetus to underground exploration, realize the survey and drawing of the underground river geographical position within the degree of depth 100m basically, accomplish the underground river position on the map, the riverbed width of each river reach, the mark of information such as degree of depth, for geographical mapping personnel, underground resource exploitation personnel provide underground river positional information, for hydrology researcher, fresh water biology researcher provide underground river video data for the progress of underground space development.

Description

Mapping system for realizing underground river mapping under combined navigation condition

Technical Field

The utility model relates to an underground river surveys technical field, specifically is a survey and drawing system who realizes underground river survey and drawing under the integrated navigation condition.

Background

The existing underground river detection technology relates to a plurality of subject fields such as physics, chemistry and the like, and has various detection ideas. However, methods such as geophysical prospecting and drilling are general in the aspect of geographic information and underground resource detection, and are not designed for underground river surveying and mapping, and these techniques belong to passive detection, that is, whether an underground river exists in a underfoot area can only be determined at a detection site, if the flow direction of the underground river is to be detected, blind search can only be performed from the detected site to the periphery, the detection cost is high, large manpower and material resources are consumed, the detection efficiency is low, and complete and systematic geographic information surveying and mapping of the underground river is difficult. The communication conditions of an underground river inlet, an underground river outlet and a skylight can be determined by methods such as isotope tracing, marker putting and the like, the water circulation process of an underground river system is macroscopically proved, but the whole appearance of an underground river section cannot be detected, the underground position is determined, the consumed material resources are large, and the surveying, mapping and obtaining results are unequal. For the method for field investigation, only one corner of the iceberg of the underground river can be detected without increasing manpower input greatly.

Disclosure of Invention

An object of the utility model is to provide a survey and drawing system of underground river survey and drawing is realized under the integrated navigation condition to propose to the method of surveying on the spot in solving above-mentioned background art, under the condition that does not increase manpower input by a large amount, also can only detect the problem of the iceberg one corner of underground river.

In order to achieve the above object, the utility model provides a following technical scheme: a surveying and mapping system for realizing underground river surveying and mapping under the condition of integrated navigation comprises a cableless underwater robot AUV and an unmanned aerial vehicle;

as an improvement, a high-precision directional sound wave detection device is arranged at the lower end of the unmanned aerial vehicle;

as an improvement, unmanned aerial vehicle is provided with the system of shooing, the system of shooing includes: matching the two-dimensional photos acquired by each surveying and mapping unmanned aerial vehicle according to the corresponding acquisition time of landmark data, marking and sequencing the two-dimensional photos according to the coordinates of the positioning mark points and the image control points in each two-dimensional photo, and synthesizing the marked two-dimensional photos into an integral three-dimensional image model according to the coordinates by adopting the Smart3D technology;

as the improvement, carry on laser range finder on the unmanned aerial vehicle, laser range finder includes: the laser is emitted to the right front of the flight, and the data of the acoustic wave detector and the data of the laser range finder are simultaneously merged into a motion control loop. When no obstacle is detected within a certain distance range right ahead, the flight height is slowly reduced while the acoustic wave signal is stably tracked. And once the obstacle is detected within the distance threshold, the flying height is gradually increased, and the flying speed in the vertical direction is proportional to the distance between the unmanned aerial vehicle and the obstacle.

As an improvement, the AUV is provided with a complete Beidou positioning resolving device, satellite signals can be received at a river outlet, a river inlet, an underground river skylight and the like, so that the longitude and latitude of a plurality of scattered points on an underground river trajectory can be measured, an inertial navigation IMU is arranged on a detector and is combined with the scattered satellite positioning points in a filtering mode, and the approximate position trend of the river can be sketched out by a combined navigation system of inertial navigation and satellite navigation carried on the AUV under the condition that the unmanned aerial vehicle loses acoustic tracking.

Further, directional sound wave detection device includes 9 sound wave detectors, and 8 of them vice detectors enclose into a circle in the unmanned aerial vehicle bottom surface is even, and 1 main detector is located circle central authorities, and 9 detectors are located same horizontal plane.

The surveying and mapping system for surveying and mapping the underground river under the combined navigation condition comprises the following steps:

s1, an alignment stage before releasing the cableless Underwater robot AUV (Autonomous Underwater vehicle). Namely, when the AUV launches, the pointing direction of the sound wave emitter is adjusted to be vertical upward (the angle is kept all the time thereafter), and the positioning unmanned aerial vehicle is accurately placed right above the AUV, so that the sound wave detector in the center right below the unmanned aerial vehicle is aligned to the center of the directional sound wave beam;

s2, autonomous mapping of AUV and drone. After alignment, the AUV is released and allowed to move with the river flow. The projection of the directional sound beam vertically penetrating to the ground on the horizontal plane can also move, the sound wave detector array at the lower end of the unmanned aerial vehicle can sense the change direction of the maximum sound wave intensity point, the detected change direction is merged into a control loop, the rotating speed and the direction of a rotor wing of the unmanned aerial vehicle are controlled, and the rotor wing of the unmanned aerial vehicle can move along with the maximum sound wave intensity point, so that the underground AUV can be tracked in real time;

s3, AUV and unmanned plane recovery. After the AUV reachs the river export promptly, surveying personnel retrieve the AUV and fix a position unmanned aerial vehicle, transfer out big dipper satellite navigation data from unmanned aerial vehicle, restore AUV movement track, accomplish underground river position survey and drawing, acquire all kinds of sensor data from the AUV simultaneously, richen and perfect underground river's mapping information.

Preferably, in step S1, the lower end of the drone needs to be equipped with a high-precision directional acoustic wave detection device. This scheme is planned to carry on 9 sound wave detectors on unmanned aerial vehicle, and 8 of them vice detectors evenly enclose into a circle in the unmanned aerial vehicle bottom surface, and 1 main detector is located circle central authorities, and 9 detectors are located same horizontal plane.

Preferably, the main detector senses the maximum intensity of the sound wave at the initial time of step S2. During the movement of the AUV to the next position, the point of maximum acoustic intensity also moves in the plane of the detector array. Since the secondary detectors enclose a circle, the point of maximum intensity is sensed by one of the secondary detectors, whichever direction it is moving. Thus, at the next instant, a maximum value will occur for one of the 8 sub-detectors.

Preferably, the unmanned aerial vehicle in step S2 is provided with a photographing system, the two-dimensional photos collected by each surveying and mapping unmanned aerial vehicle are matched according to the corresponding collection time of landmark data, the two-dimensional photos are marked and sorted according to the coordinates of the positioning mark points and the image control points in each two-dimensional photo, and the marked two-dimensional photos are combined into an integral three-dimensional image model according to the coordinates by using Smart3D technology.

Preferably, carry on laser range finder on the unmanned aerial vehicle, laser is to the dead ahead transmission of flight, fuses sound wave detector data and laser range finder data simultaneously in the motion control loop. When no obstacle is detected within a certain distance range right ahead, the flight height is slowly reduced while the acoustic wave signal is stably tracked. And once the obstacle is detected within the distance threshold, the flying height is gradually increased, and the flying speed in the vertical direction is proportional to the distance between the unmanned aerial vehicle and the obstacle.

Preferably, the AUV is also provided with a complete Beidou positioning resolving device, satellite signals can be received at a river outlet, a river inlet, an underground river skylight and the like, so that the longitude and latitude of a plurality of scattered points on an underground river trajectory can be measured, the inertial navigation IMU is arranged on the detector and is combined with the scattered satellite positioning points in a filtering manner, and the approximate position trend of the river can be drawn by the aid of the inertial navigation and satellite navigation combined system carried on the AUV under the condition that the unmanned aerial vehicle loses acoustic tracking.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses with the underground exploration field of satellite navigation technique popularization, play very big promotion and impetus to underground exploration, realize the survey and drawing of the underground river geographical position within the degree of depth 100m basically, accomplish the underground river position on the map, the riverbed width of each river reach, the mark of information such as degree of depth, for geographical mapping personnel, underground resource exploitation personnel provide underground river positional information, for hydrology researcher, fresh water biology researcher provide underground river video data for the progress of underground space development.

2. The utility model discloses show the positional information of resources such as underground river, for the development of underground river resource with utilize the fender driving and protecting navigation, promote hydrology system research, biological research under water, promote sustainable development and the implementation of western big development strategy.

3. The utility model provides technical support for underground rescue and other difficult problems.

4. The utility model discloses a regional location problem that other satellite signal can not arrive provides the solution thinking, for example the field under water promotes the popularization of satellite navigation positioning technique.

Drawings

Fig. 1 is an enlarged view of the directional sound wave detection device for positioning the bottom end of the unmanned aerial vehicle according to the present invention;

FIG. 2 is a diagram of the change process of the sound wave intensity of the present invention;

FIG. 3 is a simplified diagram of the mapping process of the present invention;

FIG. 4 is a flow chart of the mapping process of the present invention;

fig. 5 is a frame diagram of the mapping system of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, in fig. 3, 3 is the earth's surface, 4 is the stratum, 5 is the underground river, a surveying and mapping system for realizing underground river surveying and mapping under the combined navigation condition, which comprises a cableless underwater robot AUV1 and an unmanned aerial vehicle 2;

the unmanned aerial vehicle lower extreme is provided with directional sound wave detection device 21 of high accuracy, directional sound wave detection device includes 9 sound wave detector, and wherein 8 vice detectors 21a evenly enclose into a circle in the unmanned aerial vehicle bottom surface, and 1 main detector 21b is located circle central authorities, and 9 detectors are located same horizontal plane.

Unmanned aerial vehicle is provided with the system of shooing, the system of shooing includes: matching the two-dimensional photos acquired by each surveying and mapping unmanned aerial vehicle according to the corresponding acquisition time of landmark data, marking and sequencing the two-dimensional photos according to the coordinates of the positioning mark points and the image control points in each two-dimensional photo, and synthesizing the marked two-dimensional photos into an integral three-dimensional image model according to the coordinates by adopting the Smart3D technology;

carry on laser range finder on the unmanned aerial vehicle, laser is to the dead ahead transmission of flight, fuses into the motion control circuit with acoustic detector data and laser range finder data simultaneously. When no obstacle is detected within a certain distance range right ahead, the flight height is slowly reduced while the acoustic wave signal is stably tracked. And once the obstacle is detected within the distance threshold, the flying height is gradually increased, and the flying speed in the vertical direction is proportional to the distance between the unmanned aerial vehicle and the obstacle.

The AUV is provided with a complete Beidou positioning resolving device, satellite signals can be received at a river outlet, a river inlet, an underground river skylight and the like, so that the longitude and latitude of a plurality of scattered points on an underground river trajectory line can be measured, an inertial navigation IMU is arranged on a detector, and the inertial navigation IMU and the scattered satellite positioning points are subjected to filtering combination, so that the approximate position trend of the river can be sketched out by a combined navigation system of inertial navigation and satellite navigation carried on the AUV under the condition that an unmanned aerial vehicle loses acoustic tracking.

The surveying and mapping system for surveying and mapping the underground river under the integrated navigation condition can finish the concrete operation of surveying and mapping the underground river into three stages:

the first stage is alignment before the AUV is released. Because the directional sound wave needs to be strictly limited to be vertically upward, the transmitting end of the directional sound wave transmitter carried on the AUV needs to be always upward. After the AUV starts to move in water, the AUV is susceptible to water flow, and the pitch angle, the yaw angle and the course angle of the AUV can be changed all the time, so that a mechanical structure for carrying the sound wave transmitter needs to be designed into a carrying mechanism similar to an IMU (inertial measurement unit) in platform type inertial navigation, and the pointing direction of the transmitter is not changed along with the change of 3 angles of a carrier.

The ground locator is selected to be an unmanned aerial vehicle, and the lower end of the ground locator needs to be provided with a high-precision directional sound wave detection device. This scheme is planned to carry on 9 sound wave detectors on unmanned aerial vehicle, and 8 of them vice detectors evenly enclose into a circle in the unmanned aerial vehicle bottom surface, and 1 main detector is located circle central authorities, and 9 detectors are located same horizontal plane, and the arrangement is as shown in figure 1.

When the AUV launches, the pointing direction of the sound wave emitter is adjusted to be vertical upwards (the subsequent surveying and mapping process always keeps the angle), and the positioning unmanned aerial vehicle is accurately placed right above the AUV, so that the main detector is aligned to the center of the directional sound wave beam, and the maximum sound wave intensity value can be detected compared with the auxiliary detector.

The second stage is autonomous mapping of the AUV and drone. After alignment, the AUV is released and allowed to move with the river flow. The projection of the directional sound beam vertically emitted to the ground on the horizontal plane can also move, so that the sound wave detection device is required to be sensitive to the change direction of the maximum sound wave intensity point, the detected change direction is integrated into a control loop, the rotating speed and the direction of a rotor wing of the unmanned aerial vehicle are controlled, and the unmanned aerial vehicle can move along with the maximum sound wave intensity point. This scheme arranges a plurality of sound wave detectors at the unmanned aerial vehicle lower extreme into the array, is exactly the moving direction who is used for detecting the biggest point of sound wave intensity.

The main detector senses the maximum intensity of the sound wave at the initial moment. During the movement of the AUV to the next position, the point of maximum acoustic intensity also moves in the plane of the detector array. Since the secondary detectors enclose a circle, the point of maximum intensity is sensed by one of the secondary detectors, whichever direction it is moving. Thus, at the next instant, a maximum value will occur for one of the 8 sub-detectors. Assuming that the secondary detector where the maximum occurs is at the right end, the detection process is as shown in fig. 2.

In fig. 2, the detector is darkened, indicating that it is sensitive to the maximum intensity of the sound wave. The point with the maximum sound wave intensity in one detection period moves from the main detector to the right auxiliary detector, so that the connecting line direction of the main detector and the right detector is the moving direction of the sound wave intensity, namely the moving direction of the AUV. The data of the sound wave sensor are blended into the rotor wing control loop, so that the unmanned aerial vehicle can fly towards the right side, the maximum point of the sound wave intensity is made to appear on the main detector again, and then the sound wave detection of the next period is started. Therefore, the unmanned aerial vehicle can track the AUV in real time by detecting the intensity of the sound wave, and the movement track of the AUV is approximately superposed with the movement track of the unmanned aerial vehicle on the horizontal plane. It is considered that if the underwater AUV moves at a high speed, the point with the maximum sound wave intensity moves fast, which may cause the unmanned aerial vehicle to lose track of the sound wave due to insufficient motion sensitivity. Therefore, the moving speed of the underground AUV needs to be reduced, the speed information of the AUV can be accessed into a control loop of the AUV, and when the speed of the AUV exceeds a threshold value, a control signal is output to enable the propeller to rotate reversely, so that the speed is reduced. In the surveying and mapping process, a camera, a laser range finder, a barometer and the like on the AUV can work simultaneously to measure other geographic information of the underground river. The mapping process at this stage can be represented as shown in fig. 3 below.

At present, the research on satellite navigation positioning of unmanned aerial vehicles at home and abroad is very deep and is frequently repeated. After the Beidou is applied to the unmanned aerial vehicle, the positioning accuracy, the maneuvering performance and the reliability of the unmanned aerial vehicle, the mutual coordination capacity between the unmanned aerial vehicle and a command post and the like are greatly improved. Therefore, although the real-time location of underground AUV can not be realized, but after installing high accuracy big dipper satellite positioning chip on the unmanned aerial vehicle of ground end, can provide real-time accurate positional information and carry out real-time navigation for unmanned aerial vehicle, strengthen ground surveying and mapping personnel and equipment and unmanned aerial vehicle's information exchange, improve the measurement and control ability to unmanned aerial vehicle, indirectly acquire underground AUV's positional information.

The third stage is recovery of AUV and drone. Namely, when the AUV can stably receive the Beidou satellite signals, the AUV is shown to reach the open wide place. AUV stops the sound wave and sends this moment, and survey and drawing personnel retrieve AUV and fix a position unmanned aerial vehicle, transfer out big dipper satellite navigation data and underwater robot's inertial device's data from unmanned aerial vehicle, restore AUV movement track, accomplish underground river position survey and drawing, acquire all kinds of sensor data from AUV simultaneously, richen and perfect underground river's survey and drawing information. The mapping process may be represented by fig. 4.

When the utility model is used, the cableless underwater robot equipped with the directional sound wave emitter is placed at the entrance of the underground river and is aligned with the unmanned aerial vehicle with the Beidou positioning function in a precise position, so that the two robots are strictly positioned on the same vertical line; releasing the AUV to move along with the river, and moving the projection of the directional sound wave emitted by the AUV vertically and upwards on the horizontal plane, wherein the intensity of the central point of the directional sound wave is maximum; the unmanned aerial vehicle is sensitive to the moving direction of the maximum sound wave intensity point through a plurality of sound wave detectors arranged in an array at the lower end, the moving direction is not only the preplanned flying direction of the unmanned aerial vehicle, but also the advancing direction of the AUV in an underground river, so that when the unmanned aerial vehicle tracks the sound wave movement in real time, the unmanned aerial vehicle can be ensured to always fly near the AUV; the Beidou satellite signal receiver and the position resolving chip which are installed on the unmanned aerial vehicle are used for carrying out data fusion with an inertial device of the underwater robot, and the longitude and latitude information of the AUV can be indirectly obtained; and recycling the AUV and the unmanned aerial vehicle at the underground river outlet, and sorting the measurement data to obtain surveying and mapping information such as the position of the underground river, the width of a river bed and the like, so as to complete the exploration task of the underground river.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (2)

1. The utility model provides a survey and drawing system that realizes underground river survey and drawing under the integrated navigation condition which characterized in that: the unmanned underwater vehicle comprises an unmanned underwater vehicle AUV and an unmanned aerial vehicle;

the lower end of the unmanned aerial vehicle is provided with a high-precision directional sound wave detection device;

the unmanned aerial vehicle is provided with a photographing system, the photographing system comprises two-dimensional photos acquired by each surveying and mapping unmanned aerial vehicle, which are matched according to corresponding acquisition time of landmark data, the two-dimensional photos are marked and sequenced according to the coordinates of a positioning mark point and an image control point in each two-dimensional photo, and the marked two-dimensional photos are synthesized into an integral three-dimensional image model according to the coordinates by adopting the Smart3D technology;

the unmanned aerial vehicle is provided with a laser range finder, the laser range finder comprises a laser emitting device emitting laser to the right front of the flying, the data of the sound wave detector and the data of the laser range finder are simultaneously merged into a motion control loop, when no obstacle exists in a certain distance range right in front, the flying height is slowly reduced while the sound wave signal is stably tracked, once the obstacle appears in a distance threshold value, the flying height is gradually increased, and the flying speed in the vertical direction is in direct proportion to the distance between the unmanned aerial vehicle and the obstacle;

the AUV is provided with a complete Beidou positioning resolving device, satellite signals can be received at a river outlet, a river inlet, an underground river skylight and the like, so that the longitude and latitude of a plurality of scattered points on an underground river trajectory line can be measured, an inertial navigation IMU is arranged on a detector, and the inertial navigation IMU and the scattered satellite positioning points are subjected to filtering combination, so that the approximate position trend of the river can be sketched out by a combined navigation system of inertial navigation and satellite navigation carried on the AUV under the condition that an unmanned aerial vehicle loses acoustic tracking.

2. The system of claim 1, wherein the system is configured to perform underground river surveying and mapping under integrated navigation conditions, and further comprising: the directional sound wave detection device comprises 9 sound wave detectors, wherein 8 auxiliary detectors uniformly surround a circle on the bottom surface of the unmanned aerial vehicle, 1 main detector is positioned in the center of the circle, and 9 detectors are positioned in the same horizontal plane.

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