A water sports device is provided in which a propulsion device has at least one sensor arrangement which is usable for position determination. A control unit of the water sports device is designed for generating control signals on the basis of signals from the sensor arrangement for the purpose of geofencing and/or homing. One or more controllable elements of the water sports device are activated by means of the control signals. Such elements may include a motor of the propulsion device, movable means for generating an alignment of a water jet (e.g. a wing, motor, rudder blade, a fin and/or nozzle), and/or retractable and extendable elements (a centerboard, a holding and/or hydrofoil device) which influence the floating properties of the water sports device.

Disclosed is an unmanned robot for water quality management. An unmanned robot for water quality management according to the present disclosure includes a traveling unit provided with a pair of caterpillar treads mounted on both side surfaces of a body and including floating bodies having their own buoyancy, a drive motor that drives the traveling unit, a water quality measurement sensor that measures water quality of a water surface on which the unmanned robot for water quality management is operated, and a processor that controls the traveling unit so that the unmanned robot travels on the water surface to collect water quality data measured by the water quality measurement sensor.

A marine vessel propulsion control system that improves the operability of a marine vessel includes a controller configured or programmed to execute a dynamic positioning control to restrict movement of the marine vessel to make the marine vessel stay at a predetermined position. When the controller accepts an instruction to move the marine vessel during execution of the dynamic positioning control when a flow acting on a hull of the marine vessel exists, the controller is configured or programmed to move the marine vessel according to the instruction and then execute the dynamic positioning control again after moving the marine vessel.

The present invention provides an operating method and an operating system of a multiple underwater vehicles 30, wherein exploration missions and exploration depths of the multiple underwater vehicles 30 are differently set in the underwater vehicles 30 for exploring a water bottom, the multiple underwater vehicles 30 are submerged to the respective set exploration depths, the multiple underwater vehicles 30 are made to cruise at the respective set exploration depths to execute the exploration missions, and execution results of the exploration missions are recorded and/or transmitted. According to this, it is possible to deploy and operate the multiple underwater vehicles and safely and efficiently explore the water bottom.

A system and method of navigating a vehicle, the vehicle comprising a scanning device and a self-contained navigation system (SCNS) operatively connected to a computer, the method comprising: operating the scanning device for repeatedly executing a scanning operation, each operation includes scanning an area surrounding the vehicle, thereby generating respective scanning output data; operating the computer for generating, based on the scanning output data, a relative map representing at least a part of the area, the map having known dimensions and being relative to a position of the vehicle, wherein the map comprises cells, each cell classified to a class from at least two classes, comprising traversable and non-traversable, and characterized by dimensions equal or larger than an accumulated drift value of the SCNS; wherein non-traversable cells correspond to identified obstacles; receiving SCNS data and updating a position of the vehicle relative to the cells based on the SCNS data.

A sonar system is provided including a sonar assembly configured to attach to a motor assembly of a watercraft or a watercraft. The sonar assembly includes sonar transducer element(s) that transmit sonar beam(s). The sonar system includes a display, processor(s), and a steering assembly configured to cause rotation of the sonar assembly or the motor assembly. The sonar system includes a memory including computer program code that causes the processor(s) to cause the sonar transducer element(s) to emit sonar beam(s), receive sonar return data from a coverage volume of the sonar transducer element(s), generate a sonar image of the coverage volume based on the sonar return data, receive an input from a user, determine a target in the underwater environment based on the input, and cause the steering assembly to adjust the coverage volume to maintain the target within the coverage volume as the watercraft moves relative to the target.

A marine vessel propulsion control system that smoothly performs propulsion control of a marine vessel includes a controller configured or programmed to control a propulsion device that applies a thrust to a marine vessel. The controller is configured or programmed to adjust the thrust based on position information of the marine vessel and map information that includes an avoidance target.

Disclosed is path planning system and method for sea-aerial cooperative underwater target tracking, the method comprises: obtaining the position information of a detection target, carrying out a first path planning along a channel of sea surface monitoring device according to the position information of the detection target; carrying out a second path planning along the channel of sea surface monitoring device according to the water surface navigation map and its own position information, constructing an underwater obstacle map; performing a third path planning according to the underwater obstacle map, and tracking to the position of the detection target to complete the tracking task. This disclosure adopts the collaborative optimization of several clusters to reduce the number of iterations and improve the optimization efficiency, making the path planning reasonable, as a result, the target position can be quickly tracked, and the autonomous collaborative tracking capability is improved.

A navigational system for guiding a boat onto a trailer comprising at least a portion of a tow vehicle which forms a natural marker for the navigation system. A camera is located on the boat to assist the navigational system with aligning a longitudinal axis of the boat with a longitudinal axis of the trailer. A central vertical (mid) axis of the camera is aligned with the longitudinal axis of the boat. An image processing unit receives and processes images from the camera. The image processing unit, based upon a determination of a position of the central vertical (mid) axis of the camera relative to a target area of the detected natural marker, generating guidance commands to assist a user with alignment of the longitudinal axis of the boat with the longitudinal axis of the trailer and thereby facilitate proper loading of the boat onto the trailer.

A marine vessel propulsion control system includes a controller to control a movement of a marine vessel and propulsion devices each including a power source and a thrust generator to generate a thrust based on a drive force of the power source. The controller controls the movement of the marine vessel to navigate according to a preset sea route including a target position. The controller reduces the drive force of the power source of each of the propulsion devices when the marine vessel reaches a deceleration start position that is spaced apart from the target position by a required deceleration distance, and, after reducing the drive force of the power source of each of the propulsion devices, cuts off transmission of the drive force from the power source to the thrust generator in at least one of the propulsion devices depending on a predetermined condition.