A stability control systema dynamic active control system configured for total vessel pitch axis control by fast symmetric deployment of water engagement devices, coupled with engine trim adjustments and total roll and heading control by differentially deploying water engagement devices to counter rolling motions associated with water engagement device delta position. The software module is further configured with a control strategy that limits the bias of the water engagement devices as the marine vessel accelerates or decelerates in order to provide improved stability during marine vessel operation. The control strategy can maintain the bias static within a certain limited configuration (e.g., related to the speed of the marine vessel) until the limited configuration is no longer present.

A system and method involving hydro-lifters for achieving attitude and control of a watercraft including at least one elongate planar surface, at least one actuator mounted to the hull of the watercraft and pivotally connected to a planar surface. The system using at least one containment shelf-bracket fastened to the underside of the hull forming a non-fixed containment area, between an upper surface of the containment shelf-bracket and the hull, to capture the planar surface and provide a support surface on which the planar surface may rest and allowing forward, aft, and vertical slidability of the planar surface. A method for calculating optimal surface area of the planar surfaces for fuel efficiency by obtaining the measurements of an overall length of the hull and maximum beam of the hull, multiplying the measurement, multiplying the value by 1-3%, and dividing the resulting number by the quantity of planar surfaces.

A boat includes at least three trim devices positioned aft of the boat's transom. To improve the boat's ability to get on place, each trim device is initially positioned to a deployed position. The speed of the boat is then determined as the boat gains speed. When the speed of the boat exceeds a first predetermined threshold, the first trim device is moved from the deployed position to a non-deployed position. When the speed of the boat exceeds a second predetermined threshold, the second trim device is moved from the deployed position to a non-deployed position. When the speed of the boat exceeds a third predetermined threshold, the third trim device is moved from the deployed position to a non-deployed position. At least one of the first, second, and third predetermined thresholds is different from the other two of the first, second, and third predetermined thresholds.

A method for controlling a marine vessel having first and second steering nozzles and first and second trim deflectors comprises generating at least a first set of actuator control signals and a second set of actuator control signals. The first set of actuator control signals is coupled to and controls the first and second steering nozzles, and the second set of actuator control signals is coupled to and controls the first and second trim deflectors. The acts of generating and coupling the first set of actuator control signals and the second set of actuator control signals result in inducing any of a net yawing force, a net rolling force, and a net trimming force to the marine vessel without inducing any other substantial forces to the marine vessel by controlling the first and second steering nozzles and the first and second trim deflectors. Also disclosed is a system for controlling a marine vessel.

A wakeboat has a hull, the hull forming a wake when moving forward in the water, with a left quiet region and a right quiet region in the wake. The hull may exhibit rotation around its yaw axis which affects the quiet regions in the wake. Yaw rotation may be measured via one or more sensors. Yaw measurement may be used to control the hull and quiet regions. A trim tab is supported by the hull at the stern of the hull. The trim tab comprises a primary subtab and a secondary subtab. One or more actuators may be optionally included to reposition the trim tab more into, or more out of, the water to create a surf left and/or surf right configuration. Other systems and methods are also provided.

A recreational sport boat includes a hull, having starboard and port sides and a transom, and a wake-modifying devices positioned aft of the transom. The wake-modifying device includes a plate-like member and at least one downturned surface. The wake-modifying device is pivotable between a non-deployed position and a deployed position about a pivot axis. When a wake-modifying device is in the deployed position, the downturned surface is lower than it is in the non-deployed position so as to be able to modify the boat's wake.

A hull behavior control system includes a memory and at least one controller coupled to the memory. The at least one controller is configured or programmed to control a propulsion force of the marine vessel using a propeller of the marine vessel, obtain a water surface shape around the marine vessel, estimate movement of a wave based on the water surface shape, and reduce the propulsion force by controlling the propeller when it is determined that an impact force equal to or greater than a threshold value will act on the hull after the hull travels over the wave whose movement has been estimated.

A control assembly for a watercraft is presented comprising a housing defining at least one passage adapted to receive a steering column therethrough, a lever being pivotally connected to the housing about a first axis, the first axis being offset from the at least one passage, the lever being adapted to be disposed between a steering wheel of the watercraft and a dashboard of the watercraft, and an electronic motor control system operatively connected to the lever, the electronic motor control system producing signals operative to control a speed of a motor in response to the lever being rotated about the first axis. A watercraft including a control assembly is also disclosed.

A transom mounted fluid hinge bracket having one mounting plate that is connected at a lower distal end to a horizontal bracket portion which extends forward and aft of the transom of a watercraft in a bow to stern axial displacement, the horizontal bracket abutting the underside of the hull of a watercraft sitting flush with the underside of the watercraft, at least one fluid hinge receiver secured to the back side of the horizontal bracket portion on which the back of the substantially planar surface of the trim tab may rest, the at least one fluid hinge receiver containing the substantially planar surface in a position of the planar surface resting about parallel to the hull of the watercraft, and the at least one fluid hinge receiver without any load from the planar surface except at rest keeping the planar surface from descending below a horizon parallel to that of a horizon of the hull.

A locking system for assisting and supporting actuators of a trim-tab system, including a locking rod (20), slideable within a first slotted rod sleeve (28) into a locking dock within the sliding block (24). The invention further includes a second slotted rod sleeve (30) connected to a bottom side of the first slotted rod sleeve (28), a rotating rod (32) within second slotted rod sleeve (30) rotatable towards and away from the sliding block (24). The rotating rod (32) also contains a top driving rod (36) at one end, a bottom rotating rod (38) at an opposite end, and a perpendicular center driving rod (42) at the front-center side of the rotating rod (32). The center driving rod (42) moves the locking rod through contact with a thrusting rod (48). The sliding block (24) further contains a bottom contact rod (40) and a top contact rod (38).