A system for operating a boat equipped with an electric drive includes a component controller. The component controller includes a component interface for connecting a system component of the electric drive, and a communication interface for connecting the component controller to a system bus of the drive control.

A method includes obtaining one or more images of a segment of a route from a camera while a vehicle is moving along the route. The segment of the route includes one or more guide lanes. The method also includes comparing, with one or more computer processors, the one or more images of the segment of the route with a benchmark visual profile of the route based at least in part on an overlay of the one or more images onto the benchmark visual profile or an overlay of the benchmark visual profile onto the one or more images. The one or more processors identify a misaligned segment of the route based on one or more differences between the one or more images and the benchmark visual profile and respond to the identification of the misaligned segment of the route by modifying an operating parameter of the vehicle.

A marine electronic device is provided including a user interface, a processor, and a memory having computer program code stored thereon. The memory and the computer program code are configured to, with the processor, cause the marine electronic device to receive a first user input defining a minimum water depth value for a route on a body of water, receive a second user input defining a maximum water depth value for the route, cause a chart to be displayed on the user interface, receive a third user input directed to the chart defining an ending point, and generate a continuous route from a starting location to an ending location corresponding to the ending point based on the maximum water depth value and the minimum water depth value.

A marine electronic device is provided including a user interface, a processor, and a memory having computer program code stored thereon. The memory and the computer program code are configured to, with the processor, cause the marine electronic device to receive a first user input defining a minimum water depth value for a route on a body of water, receive a second user input defining a maximum water depth value for the route, cause a chart to be displayed on the user interface, receive a third user input directed to the chart defining an ending point, and generate a continuous route from a starting location to an ending location corresponding to the ending point based on the maximum water depth value and the minimum water depth value.

A method comprising scanning at least one portion a hull of a vessel positioned below a waterline while the vessel is floating in water. The method further comprises generating multi-dimensional scans of the at least one portion of the hull based on data acquired during the scanning, generating a 3-dimensional (3D) model of the at least one portion of the hull, analyzing the 3D model to identify one or more features of the hull of the vessel below the waterline, generating docking information for drydocking the vessel based on the one or more features of the hull, and identifying, based on the generated docking information, a docking plan for supporting the vessel when the vessel is supported out of the water. The method further comprises outputting instructions to dry dock the vessel.

There is disclosed a system and method for forecasting the positions of marine vessels. In an aspect, the present system is adapted to execute a forecasting algorithm to forecast the positions of one or a great many marine vessel(s) based on one or more position reporting systems including coastal and satellite AIS (S-AIS) signals or LRIT received from the vessel. The forecasting algorithm utilizes location and direction information for the vessel, and estimates one or more possible positions based on previous paths taken by vessels from that location, and heading in substantially the same direction. Thus, a body of water can be divided into “bins” of location and direction information, and a spatial index can be built based on the previous paths taken by other vessels after passing through that bin. Other types of information may also be taken into account, such as ship-specific data, nearby weather, ocean currents, the time of year, and other spatial variables specific to that bin.

A system and method for deterring theft of a marine vehicles is provided. The system is designed to collect barometric pressure data and analyze it to determine whether there has been a sudden change in elevation that may be indicative of a theft. The system is also designed to collect environmental data pertaining to a marine vehicle's normal environment and compare it to a normal environmental state of the marine vehicle in order to detect changes that may be indicative of a theft. Additionally, the system is designed to monitor equipment of the marine vehicle and alert a user if the equipment has been moved in a way that may be indicative of a theft. When the system determines an event has occurred that may be indicative of a theft, the system may alert the user by triggering an alarm via a computer readable signal.

A system comprises an elastic mount configured to support a propulsion device with respect to a marine vessel. The elastic mount contains an electromagnetic fluid. An electromagnet is configured so that increasing an amount of electricity applied to the electromagnet increases the shear strength of the electromagnetic fluid in the elastic mount and thereby decreases elasticity of the elastic mount, and so that decreasing the amount of electricity applied to the electromagnet decreases the shear strength of the electromagnetic fluid in the elastic mount and thereby increases the elasticity of the elastic mount. A controller automatically adapts the amount of electricity applied to the electromagnet based on one or more sensed conditions so as to improve performance and/or handling of the marine vessel.

A sensor, sensor system and methods that measure surfer metrics and ride data and display the data.

A drilling or work-over vessel (10) is disclosed comprising a number of operational equipment (300), wherein the drilling or work-over vessel comprises at least one operational control and/or state unit (100) comprising at least one processing unit (102), wherein the at least one operational control and/or state unit (100) comprises or are in connection with a memory and/or storage (103), and at least one sensor unit (200), wherein the at least one sensor unit (200) is adapted to obtain one or more measured physical values and to provide data representing the one or more measured physical values and/or derived values thereof to the at least one operational control and/or state unit (100), the memory and/or storage (103) comprises a data representation of a computational physics model of at least a part of the drilling or work-over rig, and the at least one processing unit (102) is adapted to derive data representing an estimation of one or more physical states (such as defined by limits of forces, relative motion between operational equipment and vessel, or between other two pieces of operational equipment) estimated to act on at least one operational equipment (300) in response to the data representing the one or more measured physical values and/or derived values thereof as provided by the at least one sensor unit (200).