KR20200090565A - Smart underwater drone system with third party point-of-view camera - Google Patents

Abstract

Provided is a smart underwater drone system with a third-person viewpoint camera. The system comprises: an underwater drone; and one or more buoys which are tied and connected to the underwater drone and floats on the water surface. The underwater drone includes: one or more first cameras with a first-person viewpoint for photographing a front side of a main body of the underwater drone; one or more propulsion apparatuses generating a propulsion force in a certain direction to the main body of the underwater drone; and one or more second cameras with a third-person viewpoint for photographing the main body of the underwater drone by being placed on a camera supporter extended towards a rear side of the main body of the underwater drone. The buoys include: a communication relay apparatus which is wirelessly connected to a user apparatus, relays communication between the underwater drone and the user apparatus, and transmits a first image signal photographed by the first cameras of the underwater drone and a second image signal photographed by the second cameras to the user apparatus; and one or more propulsion apparatuses which generate a propulsion force in a certain direction to the main body of the buoys.

Description

SMART UNDERWATER DRONE SYSTEM WITH THIRD PARTY POINT-OF-VIEW CAMERA}

The present invention relates to a smart underwater drone system having a three-way viewpoint camera.

Recently, people exploring underwater, managing aquaculture facilities, or doing water sports such as skin scuba and sea walker are increasing.

In order to manage aquaculture facilities, it is necessary to identify aquaculture facilities and fish species targeted for aquaculture, and analyze data to take action when problems arise. Existing aquaculture facilities and aquaculture target species were carried out by installing underwater cameras to check the objects, divers entering the water directly to check the objects, or checking objects with an unmanned submersible.

However, the method of confirming the object by installing the underwater camera has limitations in close-up shooting with the object, requires a large number of underwater cameras to respond to the blind spot, and has high initial cost, and the possibility of losing the underwater camera in a disaster situation There was a problem with this high. In addition, the method of verifying the object by entering the water directly into the diver is expensive, employing specialized personnel, the working time is limited, a diver's safety problems may occur, and an immediate response is difficult in the event of a fish farm problem. However, there are problems such as a proactive management cycle. In addition, the method of confirming the object with an unmanned submersible requires expensive equipment, and the size of the equipment is large, so there is a problem in that it is difficult to enter the equipment within the cage.

In addition, water sports such as skin scuba and sea walker required expensive equipment and specialized personnel, so it was not easy to do water sports without paying a lot of money.

Therefore, there is a need for a method of minimizing costs and safely exploring underwater.

Patent Registration No. 10-1381218, 2014.03.26

The problem to be solved by the present invention is to provide a smart underwater drone system having a three-way viewpoint camera.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

A smart underwater drone system having a three-way viewpoint camera according to an aspect of the present invention for solving the above-described problem includes an underwater drone, and one or more buoys connected to the underwater drone and floating on the water surface, The underwater drone includes one or more first cameras in a first-person view of photographing the front of the body of the underwater drone, one or more propulsion devices that generate a driving force in a predetermined direction to the body of the underwater drone, and the body of the body of the underwater drone And one or more second cameras in a third person view, which are disposed on a camera support extending rearward to photograph the body of the underwater drone, wherein the buoy is wirelessly connected to a user device, the underwater drone and the user device A communication relay device that relays communication therebetween, and transmits a first video signal photographed by the first camera of the underwater drone and a second video signal photographed by the second camera to the user device, and the buoy It includes at least one propulsion device for generating a driving force in a predetermined direction on the body of the.

In some embodiments, the camera support is formed integrally with the body of the water vapor drone, or is detachably coupled to the body of the water vapor drone using a waterproof connector.

In some embodiments, the camera support, in a stationary state of the body of the underwater drone, corresponds to an angle of view of the second camera, so that the second camera on the camera support is capable of fully photographing the body of the underwater drone. It has a predetermined strength and elasticity so that the movement of the camera support is limited within a predetermined reference range in the propulsion state of the body of the underwater drone.

In some embodiments, the propulsion device of the underwater drone includes one or more propulsion devices that generate a forward, upward, or downward propulsion force to the body of the underwater drone, and the camera support is in front of the body of the underwater drone , In the maximum propulsion state upward or downward, the angle between the body of the underwater drone and the camera support on a vertical plane is a predetermined reference angle range, so that the second camera on the camera support can fully capture the body of the underwater drone It has a predetermined strength and elasticity to be within.

In some embodiments, the propulsion device of the underwater drone includes one or more propulsion devices that generate left or right propulsive force to the body of the underwater drone, and the camera support comprises: the left side of the body of the underwater drone, or In the maximum propulsion state to the right side, so that the second camera on the camera support is capable of fully photographing the body of the underwater drone, so that the angle between the body of the underwater drone and the camera support on a horizontal plane is within a predetermined reference angle range. It has a certain strength and elasticity.

In some embodiments, the camera support is formed of at least one of glass rod, carbon, boron, Kevlar, and titanium.

In some embodiments, the camera support includes at least one power line connecting the main body of the underwater drone and the second camera, and the second camera uses the one or more power lines of the camera support, Power is supplied from the body of the underwater drone, and the second video signal is transmitted to the body of the underwater drone.

In some embodiments, the buoy further includes a Global Positioning System (GPS) receiver, and the buoy's communication relay device transmits the current location information of the buoy obtained using the GPS receiver to the user device. .

In some embodiments, when the underwater drone is stationary, the second camera zooms in to shoot the underwater drone, and as the speed of the underwater drone increases, zooms out to shoot the underwater drone.

In some embodiments, the underwater drone further includes a depth sensor for measuring the depth of the body of the underwater drone from the water surface, and an ultrasonic communication device for ultrasonic communication with the buoy, wherein the buoy is a GPS receiver, and the Further comprising an ultrasonic communication device for ultrasonic communication with the underwater drone, each of the two or more buoys, the current position information of the buoy obtained using the GPS receiver is transmitted to the underwater drone using the ultrasonic communication device And, the underwater drone, the depth of the body of the underwater drone from the water surface measured using the depth sensor, the distance between each two or more of the buoy and the body of the underwater drone measured using ultrasonic communication, and each Further comprising a position calculating unit for calculating the position on the surface of the underwater drone based on the current position information of the buoy received from the two or more buoy, the communication relay device of the buoy, the position of the underwater drone on the water surface To the user device.

Other specific matters of the present invention are included in the detailed description and drawings.

According to the smart underwater drone system having a third-party viewpoint camera of the present invention, a first person view image is captured by the first camera of the underwater drone, and a third person view image is captured by the second camera on the camera support. A video signal at a viewpoint and a video signal at a third person viewpoint can be provided to the user.

In addition, by using a second camera on a camera support having a predetermined strength and elasticity, the second camera can fully capture the underwater drone even in the propulsion state at the maximum speed of the underwater drone.

In addition, the video signal of the underwater drone is transmitted to the buoy through the control tether line, the buoy is wirelessly connected to the user device, and the video signal of the underwater drone is transmitted to the user device, thereby providing the user with a real-time underwater drone video signal. Can.

In addition, the current position of the underwater drone may be calculated and provided to the user by using the depth sensor and the ultrasonic communication device of the underwater drone and the GPS receiver and the ultrasonic communication device of the buoy.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a schematic configuration diagram of a smart underwater drone system having a three-party viewpoint camera according to an embodiment of the present invention.
FIG. 2 is a schematic external view of an underwater drone including the first camera, the propulsion device, and the second camera of FIG. 1.
FIG. 3 is a schematic external view of a buoy including the communication relay device and the propulsion device of FIG. 1.
4 is an exemplary view showing the movement of the second camera of the underwater drone moving forward.
5 is an exemplary view showing the movement of the second camera of the underwater drone moving sideways.
6 is a schematic configuration diagram of a smart underwater drone system having a three-way viewpoint camera according to another embodiment of the present invention.
7 is a schematic configuration diagram of a smart underwater drone system having a three-way viewpoint camera according to another embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiments allow the disclosure of the present invention to be complete, and are common in the art. It is provided to fully inform the skilled person of the scope of the present invention, and the present invention is only defined by the scope of the claims.

The terminology used herein is for describing the embodiments and is not intended to limit the present invention. In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used herein, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other components other than the components mentioned. Throughout the specification, the same reference numerals refer to the same components, and “and/or” includes each and every combination of one or more of the components mentioned. Although "first", "second", etc. are used to describe various components, it goes without saying that these components are not limited by these terms. These terms are only used to distinguish one component from another component. Therefore, it goes without saying that the first component mentioned below may be the second component within the technical spirit of the present invention.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a sense that can be commonly understood by those skilled in the art to which the present invention pertains. In addition, terms that are defined in a commonly used dictionary are not ideally or excessively interpreted unless specifically defined.

The spatially relative terms “below”, “beneath”, “lower”, “above”, “upper”, etc., are as shown in the figure. It can be used to easily describe a correlation between a component and other components. The spatially relative terms should be understood as terms including different directions of components in use or operation in addition to the directions shown in the drawings. For example, if a component shown in the drawing is turned over, a component described as "below" or "beneath" of another component will be placed "above" of the other component. Can. Thus, the exemplary term “below” can include both the directions below and above. The component can also be oriented in other directions, so that spatially relative terms can be interpreted according to the orientation.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram of a smart underwater drone system having a three-party viewpoint camera according to an embodiment of the present invention.

Referring to FIG. 1, a smart underwater drone 100 system having a three-way viewpoint camera includes an underwater drone 100 and a buoy 200.

The underwater drone 100 is an unmanned diving device that a pilot does not board and can be controlled by radio waves. The pilot may remotely control the underwater drone 100 using a controller from the ground or underwater. The underwater drone 100 moves in the water such as a river, a lake, or the sea, and acquires image information by photographing various objects in the water. The user of the underwater drone 100 system controls the operation of the underwater drone 100 by using a terminal of a user wirelessly communicating with the underwater drone 100.

The underwater drone 100 can be used in various industries. For example, a user performing aquaculture can manage aquaculture using the underwater drone 100. In addition, the user of the tourism industry may provide a real-time underwater experience to tourists by using an underwater drone 100 and a virtual reality (VR) device wirelessly communicating with the underwater drone 100.

The buoy 200 is connected to the underwater drone 100 and the control tether line 230 to receive image information and the like from the underwater drone 100. The buoy 200 connected to the underwater drone 100 and the control tether line 230 may move the surface of the water in response to the movement of the underwater drone 100. The buoy 200 may wirelessly communicate with a user device outside the water to transmit image information of the underwater drone 100. The buoy 200 floats on the water surface not far from the water with the underwater drone 100. Therefore, the user of the underwater drone 100 system can visually check the buoy 200 on the surface to roughly grasp the position of the underwater drone 100.

FIG. 2 is a schematic external view of an underwater drone including the first camera, the propulsion device, and the second camera of FIG. 1.

Referring to Figure 2, the underwater drone 100 includes a first camera 110, a propulsion device and a second camera 130, the body of the underwater drone 100 and the second camera 130 is a camera support ( 140).

The first camera 110 is installed at a predetermined position of the main body of the underwater drone 100 to photograph the front of the main body of the underwater drone 100. For example, the first camera 110 may be located in the front center portion of the body of the underwater drone 100. The first camera 110 may be installed on the body of the underwater drone 100 according to the purpose of use of the user of the underwater drone 100 system. For example, two first cameras 110 are installed at the front of the body of the underwater drone 100, and wide-angle image information may be generated using the image information of the two cameras. In addition, two first cameras 110 are installed at the front of the body of the underwater drone 100, and 3D image information may be generated using the image information of the two cameras. In addition, the first camera 110 may be installed in the front portion of the main body of the underwater drone 100, as well as in the side portion or the upper and lower portions to generate underwater image information in various directions. The main body of the underwater drone 100 means a body part of the underwater drone 100 except for the first camera 110, the propulsion device, the second camera 130, and the camera support 140.

The first camera 110 may photograph the front of the underwater drone 100 to generate image information of the first person view point of the underwater drone 100. The image information of the first person view point is the image information of the underwater drone 100 captured by the body. The first camera 110 generates image information of a first person view that immediately reflects a change in motion of the underwater drone 100.

The underwater drone 100 includes one or more propulsion devices that generate propulsion in a predetermined direction to the body of the underwater drone 100. For example, the propulsion device may be a propeller, but is not limited thereto. The propulsion device 120 of the underwater drone not only generates a propulsion force in a predetermined direction on the main body of the underwater drone 100, but also causes the first camera 110 of the underwater drone 100 to generate an image without shaking, It is controlled to enable hovering of the underwater drone 100 while balancing the main body of the underwater drone 100.

The propulsion device 120 of one or more underwater drones generates a forward, upward or downward propulsion force to the main body of the underwater drone 100. In addition, the propulsion device 120 of one or more underwater drones generates a left or right-side thrust force on the body of the underwater drone 100. To this end, four propulsion devices of the underwater drone are installed on the upper surface of the main body of the underwater drone 100, like the propulsion device 120 of the underwater drone shown in FIG. 2, the main body of the underwater drone 100 It can be installed on the back of two, but is not limited thereto.

The propulsion device 120 of the underwater drone may be controlled according to the moving mode of the underwater drone 100. The movement mode of the underwater drone 100 may be determined by the user's selection of the underwater drone 100 system. The moving mode of the underwater drone 100 may be classified into a manual mode and an automatic mode. By the manual mode, the propulsion device 120 of the underwater drone can be controlled in real time by the user's terminal in wireless communication with the underwater drone 100. Alternatively, by the automatic mode, the propulsion device 120 of the underwater drone may be controlled to move in a predetermined direction based on a predetermined movement path.

The second camera 130 is disposed on the camera support 140 extending rearward of the body of the underwater drone 100. One end of the camera support 140 is connected to the body of the underwater drone 100, and the second camera 130 is disposed at the other end of the camera support 140. When the second camera 130 is disposed on the camera support 140, it means that the camera support 140 and the second camera 130 may be integrally formed. The camera support 140 may be formed integrally with the body of the underwater drone 100, or may be detachably coupled to the body of the underwater drone 100 using a waterproof connector.

In the stationary state of the main body of the underwater drone 100, the camera support 140 corresponds to the angle of view of the second camera 130, so that the second camera 130 on the camera support 140 is the main body of the underwater drone 100. It has a fully recordable length. Being able to shoot completely means that it is possible to shoot all areas of the body of the underwater drone 100 by the second camera 130 while the body of the underwater drone 100 is stationary.

The camera support 140 has a predetermined strength and elasticity so that the movement of the camera support 140 is limited within a predetermined reference range in the propulsion state of the body of the underwater drone 100. Therefore, the movement of the camera support 140 so that the second camera 130 can fully photograph the body of the water vapor drone while the main body of the underwater drone 100 is being pushed forward, upward, downward, left, and right. It is limited within the prescribed reference range.

The camera support 140 has a different elasticity from the control data line connecting the underwater drone 100 and the buoy 200. For example, the control tether line 230 may be formed of a rubber material, and the camera support 140 may be formed of at least one of glass rod, carbon, boron, Kevlar, and titanium. The control tether line 230 is a line that connects the underwater drone 100 and the buoy 200 while transmitting and receiving video signals, and thus may be formed of a flexible material. On the other hand, the camera support 140 should be formed of a material having a predetermined strength and elasticity, since the second camera 130 must completely photograph the underwater drone 100 in motion.

The camera support 140 includes at least one power line connecting the main body of the underwater drone 100 and the second camera 130 therein. The second camera 130 receives power from the main body of the underwater drone 100 using one or more power lines of the camera support 140 and transmits a second image signal to the main body of the underwater drone 100.

The second camera 130 generates image information of a third person view point of the body of the water vapor drone. The image information of the third person view point is a view point of the body of the underwater drone 100 and is the image information of the underwater image. The second camera 130 generates image information of a third person view that captures a change in motion of the underwater drone 100 from a third party's point of view.

The image of the underwater drone 100 system may be provided to a user of the underwater drone 100 system according to the view mode of the underwater drone 100. The view mode of the underwater drone 100 may be determined by the user's selection of the underwater drone 100 system. The view mode of the underwater drone 100 may be classified into a first person mode, a third person mode, and a 1&3 person mode. By the first person mode, the user of the underwater drone 100 system may be provided with the image information of the first person view point generated by the first camera 110. Alternatively, by the third person mode, the user of the underwater drone 100 system may be provided with image information of the third person view point generated by the second camera 130. Alternatively, by the 1&3 first person mode, the user of the underwater drone 100 system can view both the first person view image information generated from the first camera 110 and the third person view image information generated from the second camera 130. Can be provided.

The body of the underwater drone 100 receives the second video signal from the second camera 130 using PLC (Power-Line Communications) communication, and transmits the first video signal and the second video signal to the buoy 200 do. The main body of the underwater drone 100 performs PLC communication with the second camera 130 and the buoy 200 by using the power line inside the camera support 140 and the power line inside the control tether line 230. PLC communication is a communication method using a power line as a communication medium, and is a communication method well known in the art to which the present invention pertains, and thus a detailed description thereof will be omitted because it may damage the subject matter of the present invention. The communication method between the main body of the underwater drone 100 and the second camera 130 and the buoy 200 may be based on a communication method other than PLC communication. For example, the body of the underwater drone 100 may communicate with the second camera 130 and the buoy 200 using at least one of a power line and a data line.

FIG. 3 is a schematic external view of a buoy including the communication relay device and the propulsion device of FIG. 1.

Referring to FIG. 3, the buoy 200 includes a communication relay device 210 and one or more propulsion devices, and is connected to a control tether line 230 connected to the underwater drone 100.

The communication relay device 210 is wirelessly connected to the user's device, relays communication between the underwater drone 100 and the user device, and the first image captured by the first camera 110 of the underwater drone 100 The signal and the second image signal captured by the second camera 130 are transmitted to the user device.

In addition, the communication relay device 210 transmits the position information of the underwater drone 100 and the position information of the buoy 200 to the user's device. The method of acquiring the position information of the underwater drone 100 and the method of acquiring the position information of the buoy 200 will be described in detail with reference to FIGS. 6 to 7.

The user's device may be a central management device that stores and manages at least one of a first video signal, a second video signal, location information of the underwater drone 100 and location information of the buoy 200. Alternatively, the user device may be a terminal such as a VR device in wireless communication with the underwater drone 100 system, but is not limited thereto.

The buoy propulsion device 220 generates a propulsion force in a predetermined direction on the body of the buoy 200. For example, the buoy propulsion device 220 may be a propeller, but is not limited thereto. The buoy propulsion device 220 may be operated in correspondence with the moving speed and the moving direction of the underwater drone 100. The propulsion device 220 of the buoy is combined with a structure that can be rotated 360 degrees to generate a propulsion force in a predetermined direction on the body of the buoy 200.

4 is an exemplary view showing the movement of the second camera of the underwater drone moving forward.

Referring to FIG. 4, when the underwater drone 100 moves forward, the angle between the main body of the underwater drone 100 and the camera support 140 is reduced on a vertical plane.

The propulsion device 120 of the underwater drone generates a propulsive force forward, upward, or downward to the body of the underwater drone 100. In the camera support 140, the second camera 130 on the camera support 140 can fully photograph the body of the underwater drone 100 in the maximum propulsion state of the main body of the underwater drone 100 forward, upward, or downward. Thus, on the vertical surface, the angle between the body of the underwater drone 100 and the camera support 140 has a predetermined strength and elasticity within a predetermined reference angle range.

Referring to Figure 4 (a), when the underwater drone 100 is stationary, the main angle of the underwater drone 100 and the camera support 140 on the vertical plane 10 is maintained within a predetermined reference angle range while the underwater drone 100 is stationary. 2 The camera 130 completely captures the body of the underwater drone 100 to generate a second image signal.

Referring to FIG. 4 (b), when the underwater drone 100 is advanced at the maximum speed, the body 20 of the underwater drone 100 and the vertical angle 20 of the camera support 140 become smaller on the vertical plane, and the second The camera 130 completely photographs the body of the underwater drone 100 to generate a second image signal.

When the underwater drone is stationary, the second camera zooms in to shoot the underwater drone, and as the speed of the underwater drone advances, the second camera zooms out to shoot the underwater drone. Can. Thus, when the underwater drone is stationary, the second camera may shoot as if approaching the underwater drone, and as the forward speed of the underwater drone increases, the second camera may shoot as if moving away from the underwater drone.

5 is an exemplary view showing the movement of the second camera of the underwater drone moving sideways.

Referring to FIG. 5, when the underwater drone 100 moves to the side, the angle between the main body of the underwater drone 100 and the camera support 140 increases on a horizontal plane.

The propulsion device 120 of the underwater drone generates a leftward or rightward propulsion force to the main body of the underwater drone 100. In the camera support 140, the second camera 130 on the camera support 140 can fully capture the body of the underwater drone 100 in the maximum propulsion state to the left or right side of the body of the underwater drone 100. In order to do so, on the horizontal plane, the angle between the body of the underwater drone 100 and the camera support 140 has a predetermined strength and elasticity within a predetermined reference angle range.

Referring to FIG. 5 (a), when the underwater drone 100 is in a stationary state, the second camera (while the angle between the main body of the underwater drone 100 and the camera support 140 is maintained within a predetermined reference angle range on a horizontal plane ( 130) completely captures the body of the underwater drone 100 to generate a second image signal. For example, when the underwater drone is stationary, the angle between the main body of the underwater drone 100 and the camera support on the horizontal plane may be 0 degrees.

5(b) and 5(c), when the underwater drone 100 rotates left or right at the maximum speed, the angle 30 between the main body of the underwater drone 100 and the camera support 140 on a horizontal plane, 40) is increased, but while maintaining within a predetermined reference angle range, the second camera 130 completely captures the body of the underwater drone 100 to generate a second image signal.

When the underwater drone is stationary, the second camera zooms in and shoots the underwater drone, and as the speed of the underwater drone's left or right turns increases, the second camera zooms out and the underwater drone Can shoot. Therefore, when the underwater drone is stationary, the second camera may shoot as if approaching the underwater drone, and as the left or right turn speed of the underwater drone increases, the second camera may shoot as if moving away from the underwater drone.

6 is a schematic configuration diagram of a smart underwater drone system having a three-way viewpoint camera according to another embodiment of the present invention.

Referring to FIG. 6, V's GPS receiver receives a location signal from a satellite to calculate the current location.

The buoy 200 may include a Global Positioning System (GPS) receiver. The GPS receiver calculates the current position of the buoy 200 by receiving a signal transmitted by the GPS satellite 300.

The communication relay device 210 of the buoy 200 transmits the current location information of the buoy 200 obtained using the GPS receiver to the user device. The user device may track the location of the buoy 200 using the current location information of the buoy 200. In addition, the user device may estimate and track the position of the underwater drone 100 based on the position of the buoy 200.

The user device may receive the first image signal, the second image signal, and the current location information of the buoy 200 and configure a split screen on the display terminal to be displayed for each. The user of the underwater drone 100 system can perform underwater exploration, water sports, etc. according to the user's purpose of use while viewing the split screen of the first video signal, the second video signal, and the current location information of the buoy 200.

7 is a schematic configuration diagram of a smart underwater drone system having a three-way viewpoint camera according to another embodiment of the present invention.

Referring to FIG. 7, the position of the underwater drone 100 C is measured using the distance to each of the buoy 200 A, the buoy 200 B, and the underwater drone 100 C and the depth of the underwater drone 100 C. do.

The underwater drone 100 includes an ultrasonic communication device for ultrasonic communication with the buoy 200 and a depth sensor that measures the depth of the body of the underwater drone 100 from the water surface. Using the depth sensor of the underwater drone 100, the depth of the body of the underwater drone 100 is measured from the water surface, and the measurement result is transmitted to the buoy 200. In addition, the distance between the main body of the underwater drone 100 and the buoy 200 is measured using the ultrasonic communication device of the underwater drone 100. Distance measurement using an ultrasonic signal is a well-known method in the technical field to which the present invention pertains, and a detailed description thereof will be omitted because it may damage the subject matter of the present invention.

The buoy 200 may include a GPS receiver and an ultrasonic communication device for ultrasonic communication with the underwater drone 100. The GPS receiver of the buoy 200 receives the signal transmitted by the GPS satellite 300 and calculates the current location of the buoy 200. The buoy 200's ultrasonic communication device is used to measure the distance between the buoy 200 and the underwater drone 100.

Two or more buoys 200 are required to calculate the current position of the underwater drone 100. Each of the two or more buoys 200 transmits the current location information of the buoys 200 acquired using a GPS receiver to the underwater drone 100 using an ultrasonic communication device.

Position calculation unit (not shown) of the underwater drone 100, the depth of the body of the underwater drone 100 from the water surface measured using a depth sensor, each of two or more buoys 200 and underwater measured using ultrasonic communication The position on the water surface of the underwater drone 100 is calculated based on the distance between the main bodies of the drone 100 and the current position information of the buoy 200 received from each of two or more buoys 200.

The buoy 200 receives the position on the surface of the underwater drone 100 from the position calculating unit (not shown) of the underwater drone 100 using the control tether line 230, and the communication relay device of the buoy 200 ( 210 transmits the location of the underwater drone 100 on the water surface to the user device. When the communication relay device 210 of the buoy 200 transmits the position on the surface of the underwater drone to the user device, the communication relay device 210 of only one buoy 200 among the two or more buoys 200 is underwater The drone's sleeping position may be transmitted to the user device.

Hereinafter, a method of calculating the current position of the underwater drone will be described.

The position of buoy A is A(x0, y0), the distance of buoy A and buoy B is c, the position of the water surface on the vertical line from underwater drone D is C(x1, y1), C(x1, y1) and buoy A is It is assumed that the distance between b, C(x1, y1) and buoy B is a, the distance between buoy A and underwater drone D is l, the distance between buoy B and underwater drone D is m, and the depth of underwater drone D from the water surface is h.

The distance l between the buoy A and the underwater drone D is measured using the buoy A ultrasonic communication device. In addition, the distance m between the buoy B and the underwater drone D is measured using the buoy B ultrasonic communication device. In addition, the depth h of the underwater drone D from the water surface is measured using the depth sensor of the underwater drone. Using the measured information, the distances of C(x1, y1) and buoy A, and the distances of C(x1, y1) and buoy B, a can be calculated as follows.

The distance c between the buoy A and the buoy B can be calculated using location coordinates based on the GPS signals received by buoy A and buoy B. Using the calculated information, the angle Θ(50) formed by the straight line between the buoy A and the buoy B and the straight line between the water surface position C and the buoy A of the underwater drone can be calculated as follows.

Using the angle θ(50) obtained as described above, it is assumed that the vertical point from the position C of the surface of the underwater drone to the straight line between buoy A and buoy B is F, and xd, the distance between the vertical point F and buoy A, The distance yd between the vertical point F and the position C of the water surface of the underwater drone can be calculated as follows.

Using the obtained xd and yd as described above, the position C of the water surface of the underwater drone can be calculated as (x1, y1)=(x0+xd, y0+yd). In the three-dimensional space, the position of the underwater drone is calculated by using the coordinates of the position C(x1, y1) of the surface of the underwater drone as the x and y coordinates, and the depth h of the underwater drone D from the surface as the z coordinate. Can.

The steps of a method or algorithm described in connection with an embodiment of the present invention may be implemented directly in hardware, a software module executed by hardware, or a combination thereof. The software modules may include random access memory (RAM), read only memory (ROM), erasable programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), flash memory, hard disk, removable disk, CD-ROM, or It may reside on any type of computer readable recording medium well known in the art.

The embodiments of the present invention have been described above with reference to the accompanying drawings, but those skilled in the art to which the present invention pertains may be implemented in other specific forms without changing the technical spirit or essential features of the present invention. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive.

100: underwater drone
200: buoy
300: GPS satellite

Claims (10)

Underwater drones; And
Wired connection with the underwater drone, and includes one or more buoys floating on the water surface,
The underwater drone,
One or more first cameras in a first person view of the front of the body of the underwater drone;
At least one propulsion device for generating propulsion in a predetermined direction to the body of the underwater drone; And
It is disposed on a camera support extending to the rear of the body of the underwater drone, and includes at least one second camera at a third person perspective to photograph the body of the underwater drone,
The buoy,
It is wirelessly connected to a user device, relays communication between the underwater drone and the user device, and a first video signal captured by the first camera of the underwater drone and a second video captured by the second camera A communication relay device transmitting a signal to the user device; And
It includes at least one propulsion device for generating a driving force in a predetermined direction on the body of the buoy,
Smart underwater drone system with a three-way camera. According to claim 1,
The camera support,
It is formed integrally with the body of the steam drone, or is detachably coupled to the body of the steam drone using a waterproof connector,
Smart underwater drone system with a three-way camera. According to claim 1,
The camera support,
In the stationary state of the body of the underwater drone, corresponding to the angle of view of the second camera, the second camera on the camera support has a length capable of fully photographing the body of the underwater drone,
In the propulsion state of the body of the underwater drone, has a predetermined strength and elasticity so that the movement of the camera support is limited within a predetermined reference range,
Smart underwater drone system with a three-way camera. According to claim 3,
The propulsion device of the underwater drone,
It includes at least one propulsion device for generating a forward, upward or downward propulsion force to the body of the underwater drone,
The camera support,
In the maximum propulsion state of the body of the underwater drone forward, upward, or downward, the second camera on the camera support enables the second camera to fully capture the body of the underwater drone, and the body of the underwater drone and the camera support on a vertical plane. Having a predetermined strength and elasticity so that the angle of incidence is within a predetermined reference angle range,
Smart underwater drone system with a three-way camera. According to claim 3,
The propulsion device of the underwater drone,
It includes at least one propulsion device for generating a left or right-side propulsion force to the body of the underwater drone,
The camera support,
In the state of maximum propulsion to the left or right side of the body of the underwater drone, the second camera on the camera support enables the second drone to fully capture the body of the underwater drone, and the body of the underwater drone and the camera support on a horizontal plane. Having a predetermined strength and elasticity so that the angle of incidence is within a predetermined reference angle range,
Smart underwater drone system with a three-way camera. According to claim 3,
The camera support,
Formed comprising at least one of glass rod, carbon, boron, Kevlar and titanium,
Smart underwater drone system with a three-way camera. According to claim 1,
The camera support,
It includes at least one power line connecting the body of the underwater drone and the second camera therein,
The second camera,
Using the one or more power lines of the camera support, receiving power from the body of the underwater drone, and transmitting the second video signal to the body of the underwater drone,
Smart underwater drone system with a three-way camera. According to claim 1,
The buoy,
Further comprising a GPS (Global Positioning System) receiver,
The communication relay device of the buoy,
Transmitting the current location information of the buoy obtained using the GPS receiver to the user device,
Smart underwater drone system with a three-way camera. According to claim 1,
The second camera,
When the underwater drone is stationary, zoom in to photograph the underwater drone, and as the speed of the underwater drone increases, zoom out to photograph the underwater drone,
Smart underwater drone system with a three-way camera. According to claim 1,
The underwater drone,
A depth sensor that measures the depth of the body of the underwater drone from the water surface; And
Further comprising an ultrasonic communication device for ultrasonic communication with the buoy,
The buoy,
GPS receiver; And
Further comprising an ultrasonic communication device for ultrasonic communication with the underwater drone,
Each two or more of the buoys,
The current position information of the buoy obtained using the GPS receiver is transmitted to the underwater drone using the ultrasonic communication device,
The underwater drone,
The depth of the body of the underwater drone from the water surface measured using the depth sensor, the distance between each of the two or more buoys measured using ultrasonic communication and the body of the underwater drone, and received from each of the two or more buoys Further comprising a position calculating unit for calculating the position on the surface of the underwater drone based on the current position information of the buoy,
The communication relay device of the buoy,
Transmitting a location on the surface of the underwater drone to the user device,
Smart underwater drone system with a three-way camera.

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