A small watercraft system includes: a watercraft body; a watercraft body manipulation member through which a watercraft body manipulation command is input by an operator; a drive source that allows the watercraft body to plane; a steering device that allows the watercraft body to be steered; and a control device that controls the drive source and the steering device to operate the watercraft body. The control device determines whether a mode switching condition is satisfied, the mode switching condition including an operator's absence condition that the operator is absent from the watercraft body. Upon determining that the mode switching condition is satisfied, the control device executes an operator-absent manipulation mode in which the control device moves the watercraft body by controlling the drive source and the steering device based on an operator-absent manipulation command independent of the watercraft body manipulation command.

A system may include a memory and a processor in communication with the memory. The processor may be configured to perform operations. The operations may include collecting organism data and analyzing the organism data. The operations may also include predicting a organism movement pattern based on the organism data and relaying the organism movement pattern to a participant.

A software-based commissioning strategy for customization of a new marine vessel having a newly installed stability/dynamic active control system. The commissioning strategy will be implemented by using a proprietary customer-facing software embedded within a software module of a newly installed dynamic active control system for a new marine vessel (and a new hull type). The software-controlled commissioning strategy is configured to automatically determine the appropriate feedback gains for the marine vessel by controlling the deployment of the water engagement devices while simultaneously measuring and capturing the data generated from the resulting list angle, roll angle, roll rate, and yaw rate changes associated with the deployment. The software driven commissioning strategy is further configured for auto-calibrating the following functional parameters of the new marine vessel: (1) Speed-Based Bias Adjustments (SBBAs), (2) Roll Overall Gain (ROG), (3) Pitch Overall Gain (POG) and (4) Yaw Rate Gain (YRG) of the marine vessel.

A software-based commissioning strategy for customization of a new marine vessel having a newly installed stability/dynamic active control system. The commissioning strategy will be implemented by using a proprietary customer-facing software embedded within a software module of a newly installed dynamic active control system for a new marine vessel (and a new hull type). The software-controlled commissioning strategy is configured to automatically determine the appropriate feedback gains for the marine vessel by controlling the deployment of the water engagement devices while simultaneously measuring and capturing the data generated from the resulting list angle, roll angle, roll rate, and yaw rate changes associated with the deployment. The software driven commissioning strategy is further configured for auto-calibrating the following functional parameters of the new marine vessel: (1) Speed-Based Bias Adjustments (SBBAs), (2) Roll Overall Gain (ROG), (3) Pitch Overall Gain (POG) and (4) Yaw Rate Gain (YRG) of the marine vessel.

A ship assistance device including a storage medium storing a computer-readable command and a processor connected to the storage medium, the processor executing the computer-readable command to: calculate a pitching amount of a ship body based on a plurality of images photographed by a camera mounted on the ship body; estimate a pitching cycle of the ship body at least based on the calculated pitching amount; predict pitching of the ship body based on the estimated pitching cycle; and control a throttle of the ship body so as to reduce the predicted pitching of the ship body.

A ship assistance device including a storage medium storing a computer-readable command and a processor connected to the storage medium, the processor executing the computer-readable command to: calculate a pitching amount of a ship body based on a plurality of images photographed by a camera mounted on the ship body; estimate a pitching cycle of the ship body at least based on the calculated pitching amount; predict pitching of the ship body based on the estimated pitching cycle; and control a throttle of the ship body so as to reduce the predicted pitching of the ship body.

A marine vessel control system operable to be used with a shallow water anchor and a motor. The marine vessel control system comprising a memory and a processor. The processor is configured to receive a user command to maintain a position of a marine vessel, receive sonar data, determine a water depth relative to a water bottom based on the sonar data in response to receiving the user command, and transmit a command to use the shallow water anchor and/or the motor based on the water depth.

A marine vessel control system operable to be used with a shallow water anchor and a motor. The marine vessel control system comprising a memory and a processor. The processor is configured to receive a user command to maintain a position of a marine vessel, receive sonar data, determine a water depth relative to a water bottom based on the sonar data in response to receiving the user command, and transmit a command to use the shallow water anchor and/or the motor based on the water depth.

A route planning apparatus is provided for planning a navigation route of a ship. The route planning apparatus includes a display to display a chart on a screen; and an operation interface configured to designate a position in the screen. In addition, the route planning apparatus includes a storage configured to store one or more potential base points that may be a potential base point of a waypoint; a processing circuitry configured to: set a waypoint on the chart in response to a navigator's operation; extract the base points within a predetermined range of the set waypoint as a reference from the storage; and a determine the extracted potential base point to be the base point of the set waypoint.

There are described herein methods and systems for operating an electric motor of a watercraft. In one method, the electric motor of the watercraft is controlled based on commands received from an accelerator of the watercraft, a sensor signal is received from at least one sensor of the watercraft while the electric motor is in operation, the sensor signal indicative of an undesirable condition of a water intake of the watercraft, and a change is effected to the controlling of the electric motor in response to receiving the sensor signal.