The objective is to obtain an azimuth control apparatus and an azimuth control method that require no excessive memory capacity and calculation time for information processing and can cope with a disturbance by adaptively adjusting a control gain while calculating changing vessel parameters online. The vessel azimuth control apparatus has

an azimuth control unit that outputs a steering-angle command signal for making a vessel turn to an azimuth to which the vessel should travel, based on an azimuth command signal generated by an azimuth command generation unit, a yaw-angle signal, and a yaw-angular-velocity signal,

a steering-angle control unit that controls a rudder based on the steering-angle command signal, and

a control gain adjustment unit that calculates respective frequency responses of the yaw-angle signal and the yaw-angular-velocity signal to a steering-angle signal outputted by a steering-angle detection unit and then adjusts a control gain of the azimuth control unit.

The position of a watercraft is detected by monitoring GPS position data, and the speed of the watercraft is reduced to a selected limit upon detecting that the watercraft has traveled outside of a selected boundary and is maintained until it is detected that the watercraft has been back within the boundary for a selected time interval, thereby avoiding up and down jerking motion of the watercraft which can occur when only a single location test is used to confirm that the watercraft is back in bounds. An RF transceiver and related control apparatus is employed for detecting other watercraft approaching too closely to the watercraft, and a display is provided for displaying various status and warning indications.

The application relates to systems and techniques for remotely navigating a marine vessel. The systems can include a dynamic positioning system and/or a marine location management system for remotely navigating a marine vessel. The marine location management system can include a communication module for receiving a geographic location of the marine vessel and transmitting a navigation plan to a vessel control system. The marine location management system can also include a processor adapted to determine the geographical coordinates of the marine location and the marine vessel. In some cases, the marine vessel can include a thruster system adapted to receive the navigation plan and determine a set of thrust vectors based on the navigation plan.

A trolling motor has a steering motor transmitting torque to a steering shaft, which is coupled to a lower propulsion unit such that rotation of the steering shaft rotates the propulsion unit about a steering axis. A controller is in signal communication with the steering motor. A foot pedal in signal communication with the controller has a foot pad pivotable about a pivot axis and sends electrical steering signals to the controller (and thus steering motor) in response to pivoting of the foot pad. A variable resistance device is coupled to the foot pedal and controllable to vary resistance to pivoting of the foot pad about the pivot axis based on a position, velocity, acceleration, and/or jerk of the steering shaft. Additionally or alternatively, the variable resistance device provides haptic feedback to a user via the foot pad to inform the user about information related to the trolling motor system.

A marine vessel control system comprises a propulsion unit and a steering actuator for steering the propulsion unit. There is a shift actuator for shifting gears in the propulsion unit and a throttle actuator for increasing or decreasing throttle to the propulsion unit. There is an input device for providing user inputted steering commands to the steering actuator and for providing user inputted shift and throttle commands to the shift actuator and the throttle actuator. There is a sensor for detecting a global position and a heading direction of the marine vessel. A controller receives position and heading values of the marine vessel from the sensor. The controller compares the received position value to a pre-programmed position value to determine a position error difference. The controller also compares the received heading value to a pre-programmed heading value to determine a heading error difference.

A system for autonomous ocean data collection includes at least one sensor capable of collecting sensor data, at least one transmission device, and at least one computing device comprising one or more hardware processors and memory coupled to the one or more hardware processors, the memory storing one or more instructions which, when executed by the one or more hardware processors, cause the at least one computing device to generate data for transmission based on the sensor data collected by the at least one sensor, and cause the at least one transmission device to transmit the data.

A method of automatically moving, by an automatic location placement system, a marine vessel includes receiving, by a central processing unit, from a vision ranging photography system, at least one optical feed including data providing a mapping of an environment surrounding a marine vessel. The method includes displaying, by the central processing unit, on a touch screen monitor, the mapping of the environment. The method includes receiving, by the central processing unit, from the touch screen monitor, target location data. The method includes directing, by the central processing unit, at least one element of a propulsion system of the marine vessel, to move the marine vessel to the targeted location, using the mapping.

A traveling route generating device is provided, which may include a user interface and processing circuitry. The user interface may receive a home route that is a route on which a ship travels upon departing from a home harbor or upon returning to the home harbor, the home harbor being a location from which the ship departs. The processing circuitry may generate a traveling route between one of a destination of the ship and a current location of the ship, and a location on the home route.

A watercraft control system is configured to maintain a prescribed distance between a host watercraft and a stationary or anchored object. The watercraft control system can be integrated with a main watercraft control system of the host watercraft, or can be an add-on watercraft control system that supplements the main watercraft control system of the host watercraft. The watercraft control system basically includes a detector and a digital controller. The detector is configured to detect a stationary or anchored object spaced from a host watercraft. The digital controller is configured to communicate with the detector to receive a detection signal from the detector. The digital controller is configured to output at least one control command to a propulsion unit of the host watercraft to maintain a prescribed distance between the host watercraft and the stationary or anchored object.

Aquatic environment monitoring devices, systems and methods are provided. An aquatic vehicle includes a body supporting a drive sub-system configured to drive the aquatic vehicle along a travel path, at least one sensor configured to obtain a plurality of sensor data points at a plurality of different locations along the travel path, a GPS module configured to track movement of the aquatic vehicle along the travel path, and a microcontroller configured to compile the sensor data points with GPS location data corresponding to a location where each of the sensor data points was obtained. A remote computer is configured to receive the compiled data from the microcontroller and, based thereon, provide an output correlating the sensor data points with the GPS location data.