A vehicle for assisting a docking operation for a marine vessel. The vehicle includes a position sensor operable to detect a position of the marine vessel. A first controller is communicatively coupled with the position sensor. The first controller is operable to receive a first instruction from a second controller corresponding to the marine vessel to monitor the position sensor. The first controller is further operable to receive positional data corresponding to the position of the marine vessel relative to a dock. The first controller is further operable to communicate the positional data to the second controller to assist with the docking operation.

A vehicle for assisting a docking operation for a marine vessel. The vehicle includes a position sensor operable to detect a position of the marine vessel. A first controller is communicatively coupled with the position sensor. The first controller is operable to receive a first instruction from a second controller corresponding to the marine vessel to monitor the position sensor. The first controller is further operable to receive positional data corresponding to the position of the marine vessel relative to a dock. The first controller is further operable to communicate the positional data to the second controller to assist with the docking operation.

A vertically adjustable jack plate configured to attach an outboard motor (or analogous device) to the transom of a marine vessel. A transom bracket is provided for connection to the vessel. A motor mounting plate is connected to the transom bracket. An electrical lift jack vertically adjusts the position of the motor mounting plate with respect to the transom bracket. The electrical lift jack is powered by a rechargeable battery that is preferably attached and detached from a controller housing. A separate remote control is provided to control the operation of the jack plate.

A vertically adjustable jack plate configured to attach an outboard motor (or analogous device) to the transom of a marine vessel. A transom bracket is provided for connection to the vessel. A motor mounting plate is connected to the transom bracket. An electrical lift jack vertically adjusts the position of the motor mounting plate with respect to the transom bracket. The electrical lift jack is powered by a rechargeable battery that is preferably attached and detached from a controller housing. A separate remote control is provided to control the operation of the jack plate.

There is described a watercraft comprising a housing having a hull and a deck, the hull shaped to cause the watercraft to operate in a displacement state and a planing state, a powerplant in the housing, and a propulsion device drivingly engaged to the powerplant to generate a propulsive force to propel the watercraft. A controller is configured for monitoring an operational parameter of the watercraft, the watercraft having a range-efficient operating regime following a transition of the watercraft from the displacement state to the planing state, the operational parameter having an optimal state for the range-efficient operating regime. A user interface is coupled to the controller and configured for providing a visual indication of a status of the watercraft in relation to the range-efficient operating regime.

There is described a watercraft comprising a housing having a hull and a deck, the hull shaped to cause the watercraft to operate in a displacement state and a planing state, a powerplant in the housing, and a propulsion device drivingly engaged to the powerplant to generate a propulsive force to propel the watercraft. A controller is configured for monitoring an operational parameter of the watercraft, the watercraft having a range-efficient operating regime following a transition of the watercraft from the displacement state to the planing state, the operational parameter having an optimal state for the range-efficient operating regime. A user interface is coupled to the controller and configured for providing a visual indication of a status of the watercraft in relation to the range-efficient operating regime.

Methods and systems for operating powersport vehicles during an operator-vehicle separation condition are provided. One method includes detecting the operator-vehicle separation condition using a first tetherless criterion and a second tetherless criterion. In response to detecting the operator-vehicle separation condition using both the first tetherless criterion and the second tetherless criterion, the method includes preventing propulsion of the powersport vehicle.

Methods and systems for operating powersport vehicles during an operator-vehicle separation condition are provided. One method includes detecting the operator-vehicle separation condition using a first tetherless criterion and a second tetherless criterion. In response to detecting the operator-vehicle separation condition using both the first tetherless criterion and the second tetherless criterion, the method includes preventing propulsion of the powersport vehicle.

A calibration method for at least one propulsion unit of a marine vessel, the at least one propulsion unit being arranged to provide a propulsive force to the vessel, the at least one propulsion unit being adjustable so as to change a respective steering angle of the at least one propulsion unit in relation to a hull of the vessel. The method includes controlling the at least one propulsion unit so as to provide at least one acceleration sequence, wherein the vessel is accelerated stepwise or continuously in each acceleration sequence, adjusting, continuously or repeatedly, during the acceleration sequence, the steering angle of the at least one propulsion unit, to keep the path of the vessel straight during the acceleration sequence, registering, during the acceleration sequence, a plurality of values of the respective steering angle of the at least one propulsion unit, and determining, based at least partly on the registered steering angle values, a respective reference steering angle of the at least one propulsion unit, which reference steering angle minimizes a deviation of an actual course over ground of the vessel from a desired course over ground of the vessel.

A marine drive unit for a boat includes a cooling compartment arranged in a drive unit body. The cooling compartment forms part of a closed cooling circuit, where the cooling circuit is arranged to cool propulsion components of the boat, where the cooling compartment comprises an inlet opening, an inlet channel, a lower end, an outlet channel and an outlet opening, where the inlet channel forms a first flow path for a cooling fluid from the inlet opening to the lower end of the cooling compartment. The outlet channel forms a second flow path for the cooling fluid from the lower end of the cooling compartment to the outlet opening, thereby allowing heat from the cooling fluid to dissipate through the outer wall of the drive unit.