Abstract: A method for maneuvering a marine vessel powered by a propulsion system includes accepting inputs to an electronic navigation device and generating a desired track based on the inputs. The desired track includes a series of waypoints, each waypoint in the series of waypoints being associated with a respective heading. The method also includes sending position and orientation information corresponding to each waypoint and its associated heading to a control module. Based on the position and orientation information, the control module generates steering and thrust commands that are required to maneuver the marine vessel from a current waypoint and heading in the series to a following waypoint and heading in the series. According to the steering and thrust commands, the propulsion system thereafter propels the marine vessel along the desired track to each waypoint and its associated heading in succession. A corresponding system is also disclosed.

Abstract: A method for setting an engine speed of an internal combustion engine in a marine propulsion device of a marine propulsion system to an engine speed setpoint includes determining the engine speed setpoint based on an operator demand and predicting a position of a throttle valve that is needed to achieve the engine speed setpoint. The method also includes determining a feed forward signal that will move the throttle valve to the predicted position, and after moving the throttle valve to the predicted position, adjusting the engine speed with a feedback controller so as to obtain the engine speed setpoint. An operating state of the marine propulsion system is also determined. Depending on the operating state, the method may include determining limits on an authority of the feedback controller to adjust the engine speed and/or determining whether the operator demand should be modified prior to determining the engine speed setpoint.

Abstract: A method for setting an engine speed of an internal combustion engine in a marine propulsion system to an operator-selected engine speed includes predicting a position of a throttle valve of the engine that is needed to provide the operator-selected engine speed, and determining a feed forward signal that will move the throttle valve to the predicted position. After moving the throttle valve to the predicted position, the method next includes controlling the engine speed with a feedback controller so as to obtain the operator-selected engine speed. The feed forward signal is determined based on at least one of the following criteria: an operator-selected control mode of the marine propulsion system; and an external operating condition of the marine propulsion system. A system for setting the engine speed to the operator-selected engine speed is also described.

Abstract: A method for maneuvering a marine vessel powered by a propulsion system includes accepting inputs to an electronic navigation device and generating a desired track based on the inputs. The desired track includes a series of waypoints, each waypoint in the series of waypoints being associated with a respective heading. The method also includes sending position and orientation information corresponding to each waypoint and its associated heading to a control module. Based on the position and orientation information, the control module generates steering and thrust commands that are required to maneuver the marine vessel from a current waypoint and heading in the series to a following waypoint and heading in the series. According to the steering and thrust commands, the propulsion system thereafter propels the marine vessel along the desired track to each waypoint and its associated heading in succession. A corresponding system is also disclosed.

Abstract: A method for controlling movement of a marine vessel includes controlling a propulsion device to automatically maneuver the vessel along a track including a series of waypoints, and determining whether the next waypoint is a stopover waypoint at or near which the vessel is to electronically anchor. If the next waypoint is the stopover waypoint, a control module calculates a distance between the vessel and the stopover waypoint. In response to the calculated distance being less than or equal to a threshold distance, the propulsion device's thrust is decreased. In response to sensing that the vessel thereafter slows to a first threshold speed, the vessel's speed is further reduced. In response to sensing that the vessel thereafter slows to a second, lower threshold speed or passes the stopover waypoint, the propulsion device is controlled to maintain the vessel at an anchor point that is at or near the stopover waypoint.

Abstract: A system and method are for controlling handling of a marine vessel having a steerable component that is steerable to a plurality of positions to vary a direction of movement of the vessel. A controller is communicatively connected to an actuator of the steerable component and a user input device provides to the controller an operator-initiated steering command to steer the steerable component to one of the plurality of positions. A sensor provides to the controller an indication of an undesired course change of the marine vessel. The controller has a vessel direction control section that outputs a command to the actuator to change a position of the steerable component from the one of the plurality of positions so as to automatically counteract the undesired course change. The vessel direction control section is active only when the operator-initiated steering command is less than or equal to a predetermined threshold.

Abstract: A method for setting an engine speed of an internal combustion engine in a marine propulsion device to an engine speed setpoint includes receiving an operator demand from an input device and learning an adapted maximum engine speed. An engine speed setpoint is calculated by scaling the adapted maximum engine speed relative to the operator demand. The method includes predicting a position of a throttle valve of the engine that is needed to achieve the engine speed setpoint, and determining a feed forward signal that will move the throttle valve to the predicted position. A marine propulsion system has an electronic control unit that learns the adapted maximum engine speed, calculates the engine speed setpoint by scaling the adapted maximum engine speed relative to the operator demand, predicts the position of the throttle valve, and determines the feed forward signal that will move the throttle valve to the predicted position.

Abstract: A system for notifying an operator of a marine vessel that a marine propulsion device is not at an efficient trim angle includes a notification device and a controller that sends a signal to the notification device to provide a trim up notification when the controller determines that the marine propulsion device is not at the optimal trim angle. The controller determines this based on at least one of the following: a current load on an engine of the marine propulsion device; a current fuel flow provided to the engine; a current air flow provided via a throttle valve to the engine; or an output from a PID control section of the controller that controls a position of the throttle valve. A method that compares a measured engine speed to an optimal engine speed corresponding to operation of the marine propulsion device at an optimal trim angle is also provided.

Abstract: A method for setting an engine speed of an internal combustion engine in a marine propulsion device of a marine propulsion system to an engine speed setpoint includes determining the engine speed setpoint based on an operator demand and predicting a position of a throttle valve that is needed to achieve the engine speed setpoint. The method also includes determining a feed forward signal that will move the throttle valve to the predicted position, and after moving the throttle valve to the predicted position, adjusting the engine speed with a feedback controller so as to obtain the engine speed setpoint. An operating state of the marine propulsion system is also determined. Depending on the operating state, the method may include determining limits on an authority of the feedback controller to adjust the engine speed and/or determining whether the operator demand should be modified prior to determining the engine speed setpoint.

Abstract: A system for controlling a rotational speed of a marine internal combustion engine has a first operator input device for controlling a speed of the engine in a trolling mode, in which the engine operates at a first operator-selected engine speed so as to propel a marine vessel at a first non-zero speed. A second operator input device controls the engine speed in a non-trolling mode, in which the engine operates at a second operator-selected engine speed so as to propel the marine vessel at a second non-zero speed. A controller is in signal communication with the first operator input device, the second operator input device, and the engine. In response to an operator request to transition from the trolling mode to the non-trolling mode, the controller determines whether to allow the transition based on the second operator-selected engine speed and a current engine speed.

Abstract: A hybrid propulsion system has an internal combustion engine and an electric motor that each selectively powers a marine propulsor to propel a marine vessel. A plurality of batteries discharges current to power the motor. A controller is programmed to aggregate the recharge and/or discharge limits of plurality of batteries and then operate the system according to a method that preferably prevents internal fault and disconnection of batteries in the plurality.

Abstract: A system for providing fuel to an internal combustion engine comprises a fuel reservoir for containing fuel for use by the internal combustion engine; a first pump that pumps fuel from a supply tank into the fuel reservoir; and a battery that provides electrical power to the first pump. A control circuit sends signals to selectively run the first pump so as both to minimize a total amount of electrical power consumed by the system and to maintain at least a minimum amount of fuel in the reservoir. Methods for filling a fuel reservoir that contains fuel for use by an internal combustion engine are also provided.

Abstract: A method for determining a heading value of a marine vessel includes determining a first estimate of a direction of the marine vessel based on information from a first source and determining a second estimate of a direction of the marine vessel based on information from a second source. The method includes inputting the first estimate and the second estimate to a control circuit, which scales each of the first estimate and the second estimate and adds the scaled estimates together so as to determine the heading value. A system for determining a heading value of a marine vessel is also disclosed.

Abstract: Systems and methods are for drive-by-wire control of a marine engine. An input device is manually operated to provide operator inputs to an engine control unit (ECU) located with the engine. The ECU has a main processor that controls speed of the engine based upon the inputs. The ECU also has a watchdog processor that receives the inputs and that monitors operations of the main processor based upon the inputs. The operations of the main processor are communicated to the watchdog processor via a communication link. When communication between the main processor and watchdog processor fails, the watchdog processor determines whether the main processor is properly functioning based upon the speed of the engine.

Abstract: A system that controls the speed of a marine vessel includes first and second propulsion devices that produce first and second thrusts to propel the marine vessel. A control circuit controls orientation of the first and second propulsion devices about respective steering axes to control directions of the first and second thrusts. A first user input device is moveable between a neutral position and a non-neutral detent position. When a second user input device is actuated while the first user input device is in the detent position, the control circuit does one or more of the following so as to control the speed of the marine vessel: varies a speed of a first engine of the first propulsion device and a speed of a second engine of the second propulsion device; and varies one or more alternative operating conditions of the first and second propulsion devices.

Abstract: A system and method is provided for efficiently changing controlled engine speed of a marine internal combustion engine in a marine propulsion system for propelling a marine vessel. The system responds to the operator changing the operator-selected engine speed, from a first-selected engine speed to a second-selected engine speed, by predicting throttle position needed to provide the second-selected engine speed, and providing a feed forward signal moving the throttle to the predicted throttle position, without waiting for a slower responding PID controller and/or overshoot thereof, and concomitant instability or oscillation, and then uses the engine speed control system including any PID controller to maintain engine speed at the second-selected engine speed.

Abstract: Drive-by-wire control systems and methods for a marine engine utilize an input device that is manually positionable to provide operator inputs to an engine control unit (ECU) located with the marine engine. The ECU has a main processor that receives the inputs and controls speed of the marine engine based upon the inputs and a watchdog processor that receives the inputs and monitors operations of the main processor based upon the inputs. The operations of the main processor are communicated to the watchdog processor via a communication link. The main processor causes the watchdog processor to sample the inputs from the input device at the same time as the main processor via a sampling link that is separate and distinct from the communication link. The main processor periodically compares samples of the inputs that are simultaneously taken by the main processor and watchdog processor and limits the speed of the engine when the samples differ from each other by more than a predetermined amount.

Abstract: A system that controls speed of a marine vessel includes first and second propulsion devices that produce first and second thrusts to propel the marine vessel. A control circuit controls orientation of the propulsion devices between an aligned position in which the thrusts are parallel and an unaligned position in which the thrusts are non-parallel. A first user input device is moveable between a neutral position and a non-neutral detent position. When the first user input device is in the detent position and the propulsion devices are in the aligned position, the thrusts propel the marine vessel in a desired direction at a first speed. When a second user input device is actuated while the first user input device is in the detent position, the propulsion devices move into the unaligned position and propel the marine vessel in the desired direction at a second, decreased speed without altering the thrusts.

Abstract: Systems and methods are for orienting a marine vessel having a marine propulsion device. A control circuit controls operation of the marine propulsion device. A user input device inputs to the control circuit a user-desired global position and a user-desired heading of the marine vessel. The control circuit calculates a position difference between the user-desired global position and an actual global position of the marine vessel and controls the marine propulsion device to minimize the position difference. The control circuit controls the marine propulsion device to orient an actual heading of the marine vessel towards the user-desired global position when the position difference is greater than a threshold. When the position difference is less than the threshold, the control circuit controls the marine propulsion device to minimize a difference between the actual heading and the user-desired heading while minimizing the position difference.

Abstract: Systems and methods are for cooling a marine propulsion system on a marine vessel. A lift pump pumps raw cooling water from a body of water in which the marine vessel is situated. The lift pump pumps the raw cooling water through an open cooling circuit from an upstream inlet for receiving the raw cooling water to a downstream outlet for discharging the cooling water back to the body of water. A control circuit controls operation of the lift pump. At least one sensing device indicates whether the lift pump is connected to the body of water. The sensing device is in communication with the control circuit. The control circuit prevents operation of the lift pump when the sensing device indicates that the lift pump is not connected to the body of water.