A system for measuring angular misalignment between marine propulsion devices. The system includes first and second members with mounting ends and distal ends. Attachment features are positioned at the mounting ends to attach the members to first and second propulsion shafts of the marine propulsion devices. Emitters configured to emit light are coupled to the first and second members. When the first and second member are attached to the propulsion shafts, a first emitter emits the light towards a target on the second member and a second emitter emits the light towards a target on the first member. The angular misalignment between the propulsion shafts is measurable based on a first offset between the target and where the light from the first emitter shines on the second member, and based on a second offset between the target and where the light from the second emitter shines on the first member.

A system for controlling one or more propulsion devices of a marine vessel. The system includes circuitry configured to: receive a steering angle command for a propulsion device of the marine vessel; receive a trim position of the propulsion device; and generate a steering actuator position command for the propulsion device based on the steering angle command and the trim position of the propulsion device.

A system for controlling one or more propulsion devices of a marine vessel. The system includes circuitry configured to: receive a steering angle command for a propulsion device of the marine vessel; receive a trim position of the propulsion device; and generate a steering actuator position command for the propulsion device based on the steering angle command and the trim position of the propulsion device.

A pod system for use with a houseboat assembly is disclosed herein, with the pod system comprising a first pod and a second pod. The first pod and the second pod are configured to be selectively disposed in a pod slot defined by the houseboat assembly. The first pod is generally free of any locomotive capabilities, while the second pod includes a movement element. When the second pod is disposed in the pod slot, the movement element may be actuated from a helm of the houseboat assembly to impart locomotive capabilities to the houseboat assembly. When locomotive capabilities are not desired, the second pod may be replaced by the first pod in the pod slot. Connectors are provided on the houseboat assembly, first pod, and second pod to removably secure the first pod and the second pod in the pod slot as desired.

A pod system for use with a houseboat assembly is disclosed herein, with the pod system comprising a first pod and a second pod. The first pod and the second pod are configured to be selectively disposed in a pod slot defined by the houseboat assembly. The first pod is generally free of any locomotive capabilities, while the second pod includes a movement element. When the second pod is disposed in the pod slot, the movement element may be actuated from a helm of the houseboat assembly to impart locomotive capabilities to the houseboat assembly. When locomotive capabilities are not desired, the second pod may be replaced by the first pod in the pod slot. Connectors are provided on the houseboat assembly, first pod, and second pod to removably secure the first pod and the second pod in the pod slot as desired.

An outboard motor for a marine vessel application, and related methods of making and operating same, are disclosed herein. In at least one embodiment, the outboard motor includes a horizontal-crankshaft engine in an upper portion of the outboard motor, positioned substantially positioned above a trimming axis of the outboard motor. In at least another embodiment, first, second and third transmission devices are employed to transmit rotational power from the engine to one or more propellers at a lower portion of the outboard motor. In at least a further embodiment, the outboard motor is made to include a rigid interior assembly formed by the engine, multiple transmission devices, and a further structural component. In further embodiments, the outboard motor includes numerous cooling, exhaust, and/or oil system components, as well as other transmission features.

A marine vessel electric propulsion system includes an electric motor, a propulsive force generator to be driven by the electric motor to generate a propulsive force, an operator to be operated by a user to adjust the power output of the electric motor, and a controller. The controller is configured or programmed to control the power output of the electric motor based on an operation of the operator, and to change a power output gain characteristic of the electric motor with respect to an operation amount of the operator in response to a gain change command.

A marine vessel electric propulsion system includes an electric motor, a propulsive force generator to be driven by the electric motor to generate a propulsive force, an operator to be operated by a user to adjust the power output of the electric motor, and a controller. The controller is configured or programmed to control the power output of the electric motor based on an operation of the operator, and to change a power output gain characteristic of the electric motor with respect to an operation amount of the operator in response to a gain change command.

A tiller assist hydraulic marine dampener and brake assembly has a fluid flow path with two potential flow restrictors in series. These include a solenoid valve and a hydraulic needle valve. A single cylinder piston serves to close both ends of the flow path. The tiller assist marine dampener and brake assembly in a second embodiment has a central coupling rod with recesses, a coupling link to a tiller arm, a co-axial tube, a nut adjacent each distal end of the co-axial tube securing the co-axial tube to a mounting bracket, a pair of springs co-axial with and surrounding the coupling rod and interior of the co-axial tube, a pair of adjustable end caps closing the gap between the ends of the co-axial tube and the coupling rod while also acting as stops for the springs, and a slide located between the pair of springs, and a set pin.

A tiller assist hydraulic marine dampener and brake assembly has a fluid flow path with two potential flow restrictors in series. These include a solenoid valve and a hydraulic needle valve. A single cylinder piston serves to close both ends of the flow path. The tiller assist marine dampener and brake assembly in a second embodiment has a central coupling rod with recesses, a coupling link to a tiller arm, a co-axial tube, a nut adjacent each distal end of the co-axial tube securing the co-axial tube to a mounting bracket, a pair of springs co-axial with and surrounding the coupling rod and interior of the co-axial tube, a pair of adjustable end caps closing the gap between the ends of the co-axial tube and the coupling rod while also acting as stops for the springs, and a slide located between the pair of springs, and a set pin.