A tiller for an outboard motor has a throttle grip that is manually rotatable through first and second ranges of motion into and between an idle position in which the outboard motor is controlled at an idle speed, and first and second open-throttle positions, respectively, in which the outboard motor is controlled at an above-idle speed. A throttle shaft is coupled to the throttle grip and is configured so that rotation of the throttle grip causes rotation of the throttle shaft, which changes a throttle position of a throttle of the outboard motor. A rotation direction switching mechanism is manually positionable into a first position in which rotation of the throttle grip through the first range of motion controls the throttle of the outboard motor and alternately manually positionable into a second position in which rotation of the throttle grip through the second range of motion controls the throttle position.

A user input assembly for controlling operation of a trolling motor assembly including a propulsion motor is provided herein. The user input assembly includes a support plate and a foot pedal defining a top surface that is configured to receive a user's foot thereon. The foot pedal is pivotably mounted to the support plate. A deflection sensor is in communication with the foot pedal and is configured to detect an angle of orientation of the foot pedal and output a signal corresponding with the angle of orientation of the foot pedal. The signal is receivable by a controller that is configured to control a direction of the propulsion motor of the trolling motor assembly. A feedback device is coupled with the foot pedal and configured to, in response to pivotal movement of the foot pedal about the first axis, provide a resistance force to the pivotal movement.

A user input assembly for controlling operation of a trolling motor assembly including a propulsion motor is provided herein. The user input assembly includes a support plate and a foot pedal defining a top surface that is configured to receive a user's foot thereon. The foot pedal is pivotably mounted to the support plate. A deflection sensor is in communication with the foot pedal and is configured to detect an angle of orientation of the foot pedal and output a signal corresponding with the angle of orientation of the foot pedal. The signal is receivable by a controller that is configured to control a direction of the propulsion motor of the trolling motor assembly. A feedback device is coupled with the foot pedal and configured to, in response to pivotal movement of the foot pedal about the first axis, provide a resistance force to the pivotal movement.

An outboard motor having an idling stop function, which includes a starter motor configured to start up an engine, a capacitor configured to serve as a power source of the starter motor, a restarting circuit that includes a restart switch configured to activate the starter motor by electric power supplied from the capacitor in conjunction with a shift lever directly operated by a ship operator at a time of restarting after idling stop, a changeover switch configured to switch to an idling stop mode that enables the restarting circuit, and an engine control device configured to control shifting to the idling stop in the idling stop mode. The capacitor is disposed in an engine compartment of the outboard motor.

An aquatic motor mounting system enables the adjustment of a boat motor with respect to its hull. The motor is attached to swivel mount that enables the motor to rotate about a first axis and pivot about a second axis generally perpendicular to the first. The system uses tongue and groove concepts to provide strength and durability while enabling the adjustment of the motor.

An aquatic motor mounting system enables the adjustment of a boat motor with respect to its hull. The motor is attached to swivel mount that enables the motor to rotate about a first axis and pivot about a second axis generally perpendicular to the first. The system uses tongue and groove concepts to provide strength and durability while enabling the adjustment of the motor.

Combination of boat and outboard engine, in which at least one outboard engine is fastened to the transom of the boat in a prearranged position, the engine being mounted to translate along a path with at least one motion component having a vertical orientation in a direction away from or close to the waterline of the boat, that is, of smaller or greater propeller draft, and a motion component having a horizontal or longitudinal orientation in a direction away from or close to the transom of the boat.

A boat includes a boat body, a propulsion unit, a steering wheel that turns about a first turning axis and has a circular or substantially circular shape or an arcuate or substantially arcuate shape about the first turning axis, and an operator unit on the steering wheel including a first operator which is located in a first direction with respect to the first turning axis and a second operator which is located in a second direction with respect to the first turning axis, and that performs a throttle operation and a shift operation on the propulsion unit.

A user input assembly for controlling operation of a trolling motor assembly including a propulsion motor is provided herein. The user input assembly includes a support plate and a foot pedal defining a top surface that is configured to receive a user's foot thereon. The foot pedal is pivotably mounted to the support plate. A deflection sensor is in communication with the foot pedal and is configured to detect an angle of orientation of the foot pedal and output a signal corresponding with the angle of orientation of the foot pedal. The signal is receivable by a controller that is configured to control a direction of the propulsion motor of the trolling motor assembly. A feedback device is coupled with the foot pedal and configured to, in response to pivotal movement of the foot pedal about the first axis, provide a resistance force to the pivotal movement.

A user input assembly for controlling operation of a trolling motor assembly including a propulsion motor is provided herein. The user input assembly includes a support plate and a foot pedal defining a top surface that is configured to receive a user's foot thereon. The foot pedal is pivotably mounted to the support plate. A deflection sensor is in communication with the foot pedal and is configured to detect an angle of orientation of the foot pedal and output a signal corresponding with the angle of orientation of the foot pedal. The signal is receivable by a controller that is configured to control a direction of the propulsion motor of the trolling motor assembly. A feedback device is coupled with the foot pedal and configured to, in response to pivotal movement of the foot pedal about the first axis, provide a resistance force to the pivotal movement.