Systems and methods for tracking vessel activities are described. An exemplar method of tracking vessel activities includes: (i) receiving data, using one or more devices, including vessel positioning data and/or time associated with one or more vessels traversing one or more paths on a body of water; (ii) deducing, using the data received from step (i), vessel attributes of one or more the vessels at certain positions and/or time along one or more of the paths; (iii) identifying, based on the vessel attributes of step (ii), one or more types of vessel activities of one or more of the vessels at the certain positions along one or more of the paths; (iv) parsing an electronic map of the body of water and land surrounding the body of water into discrete geographic zones; (v) grouping one or more types of vessel activities being carried out in each of the discrete geographic zones to arrive at one or more types of grouped vessel activities; (vi) causing to display or displaying one or more types of the grouped vessel activities that are being carried out in at least some of the discrete geographic zones.

Systems and methods for tracking vessel activities are described. An exemplar method of tracking vessel activities includes: (i) receiving data, using one or more devices, including vessel positioning data and/or time associated with one or more vessels traversing one or more paths on a body of water; (ii) deducing, using the data received from step (i), vessel attributes of one or more the vessels at certain positions and/or time along one or more of the paths; (iii) identifying, based on the vessel attributes of step (ii), one or more types of vessel activities of one or more of the vessels at the certain positions along one or more of the paths; (iv) parsing an electronic map of the body of water and land surrounding the body of water into discrete geographic zones; (v) grouping one or more types of vessel activities being carried out in each of the discrete geographic zones to arrive at one or more types of grouped vessel activities; (vi) causing to display or displaying one or more types of the grouped vessel activities that are being carried out in at least some of the discrete geographic zones.

To stably estimate a service condition of a ship of interest at each time from a time-series position information of the ship, the service condition estimation device 20 includes service condition estimation means 21 which estimates a service condition of the ship using one or more parameters generated by learning of the ship movement learning device 10. The ship movement learning device 10 includes track pattern generation means which generates a track pattern on the basis of time-series position information and speed information of a ship, and pattern learning means which learns a ship movement on the basis of a relationship between the track pattern and the service condition of the ship.

A first sensor detects first environment information indicating a shape of a shore arrival location and a positional relationship between the shore arrival location and a boat body. A second sensor, different from the first sensor, detects second environment information indicating the shape of the shore arrival location and the positional relationship between the shore arrival location and the boat body. A controller is communicatively connected to the first sensor and the second sensor. When the distance from the boat body to the shore arrival location is greater than a predetermined distance threshold, the controller generates, based on the first environment information, an instruction signal to control a propulsion device to as to cause the boat body to arrive at the shore arrival location. When the distance from the boat body to the shore arrival location is equal to or less than the distance threshold, the controller generates an instruction signal based on the second environment information.

A first sensor detects first environment information indicating a shape of a shore arrival location and a positional relationship between the shore arrival location and a boat body. A second sensor, different from the first sensor, detects second environment information indicating the shape of the shore arrival location and the positional relationship between the shore arrival location and the boat body. A controller is communicatively connected to the first sensor and the second sensor. When the distance from the boat body to the shore arrival location is greater than a predetermined distance threshold, the controller generates, based on the first environment information, an instruction signal to control a propulsion device to as to cause the boat body to arrive at the shore arrival location. When the distance from the boat body to the shore arrival location is equal to or less than the distance threshold, the controller generates an instruction signal based on the second environment information.

Disclosed herein is a method of determining an optimal route for a vessel based on vessel traffic data. The method comprises receiving vessel traffic data relating to the movement of each of a plurality of vessels in a geographical region and defining sub-regions within the geographical region in which the vessel traffic data has similar characteristics. The method also comprises determining an optimal route for a vessel between two geographical points using a representation of the geographical region. The representation comprises nodes, and each node is associated with a respective defined sub-region.

Disclosed herein is a method of determining an optimal route for a vessel based on vessel traffic data. The method comprises receiving vessel traffic data relating to the movement of each of a plurality of vessels in a geographical region and defining sub-regions within the geographical region in which the vessel traffic data has similar characteristics. The method also comprises determining an optimal route for a vessel between two geographical points using a representation of the geographical region. The representation comprises nodes, and each node is associated with a respective defined sub-region.

A traveling route generating device is provided, which may include a user interface and processing circuitry. The user interface may receive a home route that is a route on which a ship travels upon departing from a home harbor or upon returning to the home harbor, the home harbor being a location from which the ship departs. The processing circuitry may generate a traveling route between one of a destination of the ship and a current location of the ship, and a location on the home route.

An information processing method includes displaying a water-based map on a display unit, accepting an operation by an administrator, storing a selected tile by the administrator in a storage unit as a particular tile from among a plurality of tiles resulting from division of an area on the water-based map into a mesh pattern, detecting a present location of a ship at a predetermined time interval, and notifying an alert when the ship enters a water area corresponding to the particular tile.

An information processing method includes displaying a water-based map on a display unit, accepting an operation by an administrator, storing a selected tile by the administrator in a storage unit as a particular tile from among a plurality of tiles resulting from division of an area on the water-based map into a mesh pattern, detecting a present location of a ship at a predetermined time interval, and notifying an alert when the ship enters a water area corresponding to the particular tile.