A calling system for a personal watercraft includes processing circuitry. The processing circuitry is configured to: obtain a specific state signal indicating that the personal watercraft is in a given specific state; and wirelessly transmit a calling signal based on the specific state signal.

A deck extender for a personal watercraft can include a deck member supported in a cantilevered configuration over an edge of the deck of the personal watercraft. The deck extender can include mounting sleeves fixed to an upper deck of a personal watercraft with mounting tabs of the deck member received within the mounting sleeves. The deck member can include mounting mechanisms having a receptacle and a pivoting cleat mounted above the receptacle configured for mounting accessories to the deck member. The deck member can have recessed channel members for mounting accessories.

A deck extender for a personal watercraft can include a deck member supported in a cantilevered configuration over an edge of the deck of the personal watercraft. The deck extender can include mounting sleeves fixed to an upper deck of a personal watercraft with mounting tabs of the deck member received within the mounting sleeves. The deck member can include mounting mechanisms having a receptacle and a pivoting cleat mounted above the receptacle configured for mounting accessories to the deck member. The deck member can have recessed channel members for mounting accessories.

A battery enclosure for a personal watercraft is provided. Different configurations of the battery enclosure are disclosed, as well as different arrangements of the battery enclosure within the personal watercraft and with respect to other features of the personal watercraft. According to one embodiment, a personal watercraft includes a deck and a hull defining an interior volume. An electric motor is housed within the interior volume, the electric motor being operable to rotate a drive shaft. A battery pack having a battery enclosure housing one or more batteries is also positioned within the interior volume. A portion of at least one battery of the one or more batteries is positioned vertically above the drive shaft.

A battery enclosure for a personal watercraft is provided. Different configurations of the battery enclosure are disclosed, as well as different arrangements of the battery enclosure within the personal watercraft and with respect to other features of the personal watercraft. According to one embodiment, a personal watercraft includes a deck and a hull defining an interior volume. An electric motor is housed within the interior volume, the electric motor being operable to rotate a drive shaft. A battery pack having a battery enclosure housing one or more batteries is also positioned within the interior volume. A portion of at least one battery of the one or more batteries is positioned vertically above the drive shaft.

A system for a traveling history report of a personal watercraft includes processing circuitry. The processing circuitry is configured to: generate traveling history data based on positional information indicating a position of the personal watercraft, the traveling history data including information indicating a movement route of the personal watercraft; and output the traveling history data.

A system for a traveling history report of a personal watercraft includes processing circuitry. The processing circuitry is configured to: generate traveling history data based on positional information indicating a position of the personal watercraft, the traveling history data including information indicating a movement route of the personal watercraft; and output the traveling history data.

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.