A wake control system aft of the driveshaft, propeller, and rudder of a vessel includes a fin base and at least one fin slidingly engaged with the fin base. The fin(s) are vertically oriented and extend down into the water surface. The fins are transversely adjustable along the fin base to redirect a wake generated by the boat. In other embodiments, the control system comprises a starboard fin tab adjacent to a port fin tab, each of the independent fin tabs hingeably attached to the aft section of the hull, at the transom. Each fin tab includes at least one extending fin. Fin tabs are selectively deployable and retractable into and out of the water surface to redirect a wake generated by the vessel from one side to the other. A novel underwater exhaust system redirects exhaust depending on speed of the vessel and complements the wake control system.

A watercraft running system includes a propulsion device, a steering device, a course changing operator, a port-side attitude control plate and a starboard-side attitude control plate, a port-side actuator and a starboard-side actuator, and a controller. The controller is operable in a first control mode in which the steering device is controlled according to the operation of the course changing operator and a second control mode in which the port-side actuator and the starboard-side actuator are controlled according to the operation of the course changing operator. The controller is configured or programmed to prohibit shifting from the first control mode to the second control mode if the steering position of the steering device is not a neutral position, and to permit the shift from the first control mode to the second control mode if the steering position is the neutral position.

A watercraft running system includes a propulsion device, a steering device, a course changing operator, a port-side attitude control plate and a starboard-side attitude control plate, a port-side actuator and a starboard-side actuator, and a controller. The controller is operable in a first control mode in which the steering device is controlled according to the operation of the course changing operator and a second control mode in which the port-side actuator and the starboard-side actuator are controlled according to the operation of the course changing operator. The controller is configured or programmed to prohibit shifting from the first control mode to the second control mode if the steering position of the steering device is not a neutral position, and to permit the shift from the first control mode to the second control mode if the steering position is the neutral position.

A control system for posture control tabs of a marine vessel assists operations of a steering control. The posture control tabs are mounted on a stern of a hull to move up or down to control a posture of the hull. Actuators actuate the respective posture control tabs. When a steering instruction is provided through the steering control, a processor determines the posture control tab to be actuated and controls the actuator corresponding to the posture control tab determined to be actuated so as to change the position of the determined posture control tab.

A control system for posture control tabs of a marine vessel assists operations of a steering control. The posture control tabs are mounted on a stern of a hull to move up or down to control a posture of the hull. Actuators actuate the respective posture control tabs. When a steering instruction is provided through the steering control, a processor determines the posture control tab to be actuated and controls the actuator corresponding to the posture control tab determined to be actuated so as to change the position of the determined posture control tab.

This patent describes a method for steering an unmanned surface vessel consisting of a hull, keel, and non-self-tacking rigid wing sail. Unlike conventional vessels, it doesn't require a rudder. Steering is achieved by rotating the wing sail around a vertical axis using an actuator. The center of lateral resistance is spaced aft of the center of windage, balancing the vessel to the wind. The vessel maintains various angles relative to the wind and holds a port or starboard tack without active steering. The sail position only needs changing when a new course is desired. The vessel can progress at all angles to the wind, whether by a zigzagging course or a straight line. This method eliminates the need for an active rudder to maintain course, reducing power consumption and component wear.

This patent describes a method for steering an unmanned surface vessel consisting of a hull, keel, and non-self-tacking rigid wing sail. Unlike conventional vessels, it doesn't require a rudder. Steering is achieved by rotating the wing sail around a vertical axis using an actuator. The center of lateral resistance is spaced aft of the center of windage, balancing the vessel to the wind. The vessel maintains various angles relative to the wind and holds a port or starboard tack without active steering. The sail position only needs changing when a new course is desired. The vessel can progress at all angles to the wind, whether by a zigzagging course or a straight line. This method eliminates the need for an active rudder to maintain course, reducing power consumption and component wear.

A water craft comprising: an elongated hull comprising a passageway having an inlet and an outlet; a pump jet disposed within said passageway intermediate said inlet and said outlet; said pump jet being configured to receive water entering said passageway through said inlet and pump said water out of said outlet, whereby to propel said hull through water; a plurality of nozzles disposed on the outer surface of said hull, aft of said inlet, wherein said plurality of nozzles are configured to release a friction-reducing fluid, whereby the friction-reducing fluid displaces water from the surface of said hull so as to diminish friction on the outer surface of said hull and facilitate high speeds.

A water craft comprising: an elongated hull comprising a passageway having an inlet and an outlet; a pump jet disposed within said passageway intermediate said inlet and said outlet; said pump jet being configured to receive water entering said passageway through said inlet and pump said water out of said outlet, whereby to propel said hull through water; a plurality of nozzles disposed on the outer surface of said hull, aft of said inlet, wherein said plurality of nozzles are configured to release a friction-reducing fluid, whereby the friction-reducing fluid displaces water from the surface of said hull so as to diminish friction on the outer surface of said hull and facilitate high speeds.

A vessel braking control system for a marine vessel that utilizes one or more of the vessel's features and effectors to increase the drag on the vessel both through increased drag on the features and effectors themselves and by creating a downward force on the vessel as a whole, increasing the wetted hull area and increasing hull drag thereby; the control system operates to place the features and effectors in a braking state through rotation relative to the vessel's direction of travel and relative to the water's surface, and may automatically return the features and effectors to their normal operating state upon the vessel's reaching a detected, predetermined speed.