A controller receives a signal indicating an operating amount and an operating direction of a steering member. When the operating amount of the steering member is greater than or equal to a steering threshold, the controller causes right and left propulsion devices to generate thrusts oriented in opposite directions in a back-and-forth direction such that a vessel body is turned in a corresponding direction to the operating direction of the steering member.

A hydraulic steering system for vehicles includes a steering control member; a hydraulic pump provided with a rotatable driving shaft on which the control member is fitted; a hydraulic actuating cylinder connected with two ports of the pump alternately operating as delivery side and return side of the pump and mechanically connected with a direction changing member, which determines a change in the direction by modifying orientation via an actuating cylinder as a function of the supply of hydraulic fluid to the cylinder from the pump by the steering control member. The driving shaft is dynamically connected with an electric motor/transmission assembly, which is activated alternatively by generating a rotational force auxiliary to the movement manually exerted on the steering control member or opposing the manually exerted movement, or by driving to rotate the driving shaft of the pump in place of the manual action driving the steering control member.

A boat maneuvering support device supports maneuvering of a boat including a first propulsion device having a variable turning angle, a second propulsion device for generating a propulsive force for moving the boat in a left-right direction, and a steering mechanism for changing a turning angle of the first propulsion device and an output of the second propulsion device. The boat maneuvering support device includes a control unit which controls the turning angle of the first propulsion device and/or the output of the second propulsion device, a detection unit which detects a rotational speed of a propeller of the first propulsion device, and a calculation unit which obtains a rotational power of the boat based on the turning angle designated by the operation of the steering mechanism and the rotational speed. The control unit controls the output of the second propulsion device based on the rotational power.

A redundant steering system for watercraft that transfers rudder control to an electronic steering system when a hydraulic steering system either fails or is under repair. The electronic steering system utilizes either a fueled generator or a battery or series of batteries to power electric steering and flanking motors that serve control the angular position of the rudders.

A method for maintaining a marine vessel propelled by a marine propulsion device in a selected position includes determining a current global position of the marine vessel and receiving a signal command to maintain the current global position. The current global position is stored as a target global position in response to receiving the signal command. A subsequent global position of the marine vessel is determined and a position error difference between the subsequent global position and the target global position is determined. The method includes determining marine vessel movements required to minimize the position error difference, and causing the marine propulsion device to produce a thrust having a magnitude, a direction, and an angle calculated to result in achievement of the required marine vessel movements. At least one of timing and frequency of discontinuity of thrust production is controlled while the position error difference is minimized.

A method includes accepting inputs to a marine vessel's control module, the inputs defining first and second waypoints and a desired heading, and defining a desired track between the first and second waypoints. Ideal steering and thrust commands required to orient the vessel at the desired heading and to maneuver the vessel from the first to the second waypoint are generated and carried out. The method includes measuring a current position and heading of the vessel; calculating a cross-track error based on the current position as compared to the desired track; and calculating a heading error based on the current heading as compared to the desired heading. The method includes generating corrective steering and thrust commands that are required to minimize the cross-track error and the heading error. The propulsion system propels the marine vessel according to the corrective steering and thrust commands, as appropriate.

A steering system for a marine vessel comprises a helm, a control head, and a joystick. The helm and control head may respectively provide user inputted steering commands and user inputted shift and throttle commands on a first CAN network. The joystick and the control head may respectively provide user inputted steering commands and user inputted shift and throttle commands on a second CAN network. The helm may provide user inputted steering commands on the first CAN network. The control head may provide user inputted shift and throttle commands on the second CAN network. The joystick may provide user inputted steering commands and user inputted shift and throttle commands on either the first CAN network or the second CAN network.

Disclosed herein is an aquatic towable device comprising a body, a towline connector, a rudder fin, and a steering apparatus. The towline connector is placed at one end of the body and above a waterline of the body when the device is occupied by a passenger. The rudder fin is attached pivotably to an underside of the body and placed toward the towline connector and positioned so at least part of the rudder fin will be underwater when the device is occupied by a passenger. The steering apparatus is attached to the rudder fin that pivots the rudder fin and is accessible from a top side of the body.

A steering system for a vessel includes an electric actuator that generates power to rotate a steering wheel, a transmitting mechanism that transmits a rotation of the electric actuator to the steering wheel, and a power supply controller that supplies electric power to the electric actuator according to an input signal that is not based on a rotation of the steering wheel.

A steering device includes a sensor and a rotor, each of which rotates together with a steering wheel around a rotational axis, and a stator whose position in a circumferential direction is stationary. The steering device includes a harness that connects a target component and the sensor together, a first fastener that fixes the harness to the rotor, and a second fastener that fixes the harness to the stator. An intermediate portion between the first fastener and the second fastener in the harness includes a first extension and a second extension each of which extends along the circumferential direction and a connector that connects the first extension and the second extension together.