A marine autopilot system is disclosed. While in autopilot mode, the marine vessel's autopilot system autonomously steers the marine vessel's rudder. Steering input provided using the helm typically results in counter-steering to the autopilot. If the autopilot is following a current heading or course (route), the autopilot may continue its efforts to remain on the heading or course in response to the deviation caused by steering input to the helm. The disclosed autopilot system improves this problem by including one or more sensors that measure helm movement and wirelessly transmit helm movement data to one or more components of the marine vessel's electronic network. If the operator of the marine vessel manually steers the helm to deviate from a current heading or course, helm movement exceeding a predetermined autopilot disengagement threshold may cause the autopilot control to temporarily disengage, allowing a user to manually steer the marine vessel.

A sensor detects a shape of a shore arrival location and a positional relationship of the shore arrival location and a boat body and outputs environment information indicating the shape of the shore arrival location and the positional relationship. A controller receives the environment information and generates an instruction signal to control a propulsion device to cause the boat body to move toward the shore arrival position set based on the environment information and to push the boat body to the shore arrival location.

A sensor detects a shape of a shore arrival location and a positional relationship of the shore arrival location and a boat body and outputs environment information indicating the shape of the shore arrival location and the positional relationship. A controller receives the environment information and generates an instruction signal to control a propulsion device to cause the boat body to move toward the shore arrival position set based on the environment information and to push the boat body to the shore arrival location.

A camera produces image data representing an image of a surrounding view of a watercraft. A controller obtains the image data. The controller recognizes an image representing a specific mark in the image data. With reference to a control data set, the controller obtains watercraft operating information associated with the specific mark recognized in the image data. The control data set defines a relationship between the specific mark and the watercraft operating information.

A camera produces image data representing an image of a surrounding view of a watercraft. A controller obtains the image data. The controller recognizes an image representing a specific mark in the image data. With reference to a control data set, the controller obtains watercraft operating information associated with the specific mark recognized in the image data. The control data set defines a relationship between the specific mark and the watercraft operating information.

Techniques are disclosed for systems and methods to disengage an autopilot drive of a mobile structure based on a steering wheel torque applied manually by a user. A system includes a logic device in communication with a torque sensor unit, such as a strain gauge, load pin, or load cell. Sensor data and/or signals provided by the TSU are used to determine a force applied to a steering mechanism of the mobile structure while the mobile structure is on a heading provided by an autopilot drive of the mobile structure. The force may be a torque applied to the steering mechanism corresponding to manual control of the mobile structure. The system disengages the autopilot device of the mobile structure based, at least in part, on the determined force.

Techniques are disclosed for systems and methods to disengage an autopilot drive of a mobile structure based on a steering wheel torque applied manually by a user. A system includes a logic device in communication with a torque sensor unit, such as a strain gauge, load pin, or load cell. Sensor data and/or signals provided by the TSU are used to determine a force applied to a steering mechanism of the mobile structure while the mobile structure is on a heading provided by an autopilot drive of the mobile structure. The force may be a torque applied to the steering mechanism corresponding to manual control of the mobile structure. The system disengages the autopilot device of the mobile structure based, at least in part, on the determined force.

A ship maneuvering system includes a propulsion unit to steer a ship body, a trim adjuster disposed on the ship body, and a controller. The controller is configured or programmed to correct a change in the traveling state of the ship body due to operation of the trim adjuster.

A ship maneuvering system includes a propulsion unit to steer a ship body, a trim adjuster disposed on the ship body, and a controller. The controller is configured or programmed to correct a change in the traveling state of the ship body due to operation of the trim adjuster.

A method, and a support vessel for use in the system. The system can in various embodiments include: a carrier vessel for carrying fluid hydrocarbon cargo across sea, the hydrocarbon cargo to be loaded into at least one cargo tank of the vessel; a support vessel; VOC recovery means on the support vessel for recovering volatile organic compounds, VOCs, the VOCs being produced from the cargo tank in loading the cargo tank, in use; and at least one hose extending between the carrier vessel and the support vessel for communicating gas having volatile organic compounds, VOCs, through the hose from the cargo tank of the carrier vessel to the VOC recovery means on the support vessel.