A system and a method are disclosed for enabling seamlessly tracking a location of a water vessel by supplementing satellite data with mobile data location based on proximity of a water vessel to shore. The system receives a Global Positioning System (GPS) location of the water vessel, the GPS location of the water vessel based on using the satellite data of the water vessel. The system determines that the GPS location is within a threshold distance of a boundary. Responsive to determining that the GPS location is within the threshold distance of the boundary, the system initiates monitoring for a mobile signal emanating from a trajectory path of the water vessel. The system detects, during the monitoring, the mobile signal, the tracking the location of the water vessel based on mobile data of the mobile signal. The system provides the tracked location to a monitoring device.

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.

A ferry controlling system for controlling a ferry in a marina where a watercraft of a user is moored and stored includes a controller and a storage. The storage stores identification information identifying the user, first location information regarding a first location where a ferry is docked/undocked, and second location information regarding a second location on the water where the watercraft of the user is moored and stored. Upon receiving the identification information, the controller is configured or programmed to allow driving of the ferry and set the second location as a destination of the ferry based on the second location information.

A watercraft control system includes a watercraft and a communication device. The communication device includes a communication unit configured to transmit information indicating a location of the communication device to the watercraft. The watercraft includes a communication unit configured to receive the information indicating the location of the communication device and a difference calculation unit configured to calculate a difference between the location of the communication device and a location of the watercraft.

Methods and systems described herein can assist a user when loading a watercraft onto a trailer (e.g., at a boat ramp). For example, position data generated by sensor(s) coupled to the watercraft and/or trailer can cause one or more propulsion devices associated with the watercraft to automatically (e.g., without user intervention) position the watercraft onto the trailer, for example, by controlling the power and/or thrust direction of the propulsion device(s).

A method for shoreline segmentation in complex environments based on the perspective of an unmanned surface vessel is provided. A visible light image, a thermal infrared image and a raw radar echo image of a shoreline are obtained. The visible light image and the thermal infrared image are subjected to fusion and feasible region segmentation to obtain an all-weather two-dimensional image information of the shoreline, and an echo image including tiny features is obtained based on the raw radar echo image. An extraction region is constrained and shoreline features are enhanced based on the all-weather two-dimensional image information and the echo image to obtain a multi-feature point cloud dataset for shoreline segmentation.

A control system for controlling movement, position, or force for a mechanically connected object comprising a plurality of marine vessels. The control system includes at least one processor configured to: receive a movement, position or force command for the mechanically connected object; and generate at least one first command for a first marine vessel of the plurality of marine vessels and at least one second command for a second marine vessel of the plurality of marine vessels, to control movement, position, or force of the mechanically connected object in response to the movement, position or force command for the mechanically connected object.

A berthing assistance device for assisting berthing of a ship to which a propulsion unit is attached. The berthing assistance device includes a controller configured to control the propulsion unit, based on an operation amount from an operation device, an acquisition unit configured to acquire a ship condition, the ship condition including a current ship position and a current bow direction, a calculation unit configured to calculate a berthing route from the current ship position to a berthing position, and a correction unit configured to correct control of the propulsion unit, based on the ship condition and the berthing route.

The information processing device includes an acquisition means and a display processing means. The acquisition means acquires measurement data generated by a measurement device provided on a ship. The display processing means performs a process for displaying information relating to a relative positional relationship between the ship and a berthing area on a display device based on the measurement data, the berthing area being an area where the ship should be positioned when the ship is berthed to a berthing place.

A remote watercraft maneuvering system includes a watercraft and an input device. The watercraft includes an actuator having a function of generating a propulsion force of the watercraft and a function of causing the watercraft to generate a moment, a manipulation unit, a watercraft control device, a watercraft position detection unit, and a communication unit. The input device includes a communication unit, an input device position detection unit, a manipulation unit, and a notification unit. The watercraft control device has a normal watercraft maneuvering mode and a remote watercraft maneuvering mode. In the remote watercraft maneuvering mode, the communication unit of the watercraft receives information indicating the position of the input device from the input device, the watercraft control device calculates a distance between the input device and the watercraft, and the communication unit of the watercraft transmits information indicating that the distance between the input device and the watercraft is greater than or equal to a threshold value to the input device and the notification unit provides a notification for a remote watercraft maneuverer using the input device when the distance between the input device and the watercraft is greater than or equal to the threshold value. The threshold value is smaller than a maximum value of the distance between the input device and the watercraft when communication between the communication unit of the input device and the communication unit of the watercraft is possible.