A destination from a plurality of destinations is identified. A plurality of routes associated with the destination is calculated. A determination is made that the device is travelling along a route in the plurality of routes without receiving user input selecting the route. Navigational data associated with the route is displayed in response to determining that the device is travelling along the route.

Provided are an image control program, and the like, that make it possible for a user to easily ascertain the correspondence relationship between points on a route and point information symbols even after an image has been switched from an image including a route line, which has a line shape expressing the route and the points on the route, and the point information symbols to an image including a route line having a different shape and the point information symbols. The following processing is carried out in the present invention: first processing for displaying, on a display unit, a first image including a first line, which indicates a route and has a line shape expressing points on the route, and point information symbols expressing information relating to the points; and second processing for displaying, on the display unit, a second image that is displayed by being switched to from the first image and displays a second line, which indicates the route and has a different shape from that of the first line, such that the points and point information symbols are associated with each other.

An exemplary geospatial navigation system provides, to a user of a mobile navigation device, navigational guidance along a route from a starting location to a destination location. The geospatial navigation system also identifies a first transportation mode being employed by the user to traverse the route. While the navigational guidance is being provided, the geospatial navigation system receives sensor data generated by a sensor within the mobile navigation device, and determines, based on the sensor data, that the user switches from the first transportation mode to a second transportation mode. In response to the determining that the user switches from the first to the second transportation mode, the geospatial navigation system suspends and/or engages one or more features of the navigational guidance being provided to the user. Corresponding methods and systems are also disclosed.

A method for controlling an XR device outputting a navigation screen. The method may comprise receiving first GPS information, acquiring second GPS information corresponding to a current position of a vehicle, determining whether the first GPS information matches the second GPS information, and displaying a navigation screen based on a map DB stored in the server if the first GPS information is matched with the second GPS information. If the first GPS information is not matched with the second GPS information, the method may further comprise taking a driving image through a camera, comparing the driving image with an image of the map DB stored in the server, searching for a video frame including the most similar point from the image of the map DB, and changing the navigation screen based on the video frame searched from the map DB.

A navigation system includes: a control unit; a communication unit, coupled to the control unit, configured to determine a lane position on a current roadway for a free-drive mode; identify a restricted use lane based on a distance and the lane position ahead on the current roadways; and determine a roadway lane along with the restricted use lane and the lane position for displaying on a device.

Systems and methods are disclosed for the development and management of curated navigational routes are disclosed. The curated navigational route can be a particular path of travel that is specifically designed for one or more users. The curated navigational routes are carefully constructed paths of travel that are custom defined by a route manager.

An information processing device includes a processor including hardware. The processor is configured to: communicate with an information communication device associated with a mobile object on which a user rides and configured to output user skill information related to driving skill of the user and a sensor configured to sense other mobile objects inside and around an intersection and output sensing information; derive entering timing at which the mobile object enters the intersection based on the sensing information acquired from the sensor and the user skill information acquired from the information communication device; and output timing information including the entering timing of the mobile object to the information communication device before the mobile object enters the intersection.

An advanced driver assistance system configured to implement one or more automotive V2V applications designed to assist a driver in driving a Host Motor-Vehicle. The advanced driver assistance system is configured to be connectable to an automotive on-board communication network to communicate with automotive on-board systems to implement one or different automotive functionalities aimed at assisting the driver in driving the Host Motor-Vehicle, controlling the Host Motor-Vehicle, and informing the driver of the Host Motor-Vehicle of the presence of Relevant Motor-Vehicles deemed to be relevant to the driving safety of the Host Motor-Vehicle. The advanced driver assistance system comprises an automotive V2V communication system operable to communicate with automotive V2V communication systems of Remote Motor-Vehicles via V2V messages containing motor-vehicle position-related, motion-related, and state-related data. The advanced driver assistance system is further configured to receive V2V messages transmitted by V2V communications systems of Remote Motor-Vehicles; identify from among the Remote Motor-Vehicles in communication with the Host Motor-Vehicle, Nearby Motor-Vehicles that may represent potential threats to the driving safety of the Host Motor-Vehicle, based on motor-vehicle position-related, motion-related, and state-related data in received V2V messages and on motor-vehicle position-related, motion-related, and state-related data of the Host Motor-Vehicle; and process the data contained in the V2V messages received from the Nearby Motor-Vehicles to identify from among the Nearby Motor-Vehicles Relevant Motor-Vehicles that may be relevant to the automotive functionalities aimed at assisting the driver in driving the Host Motor-Vehicle, controlling the Host Motor-Vehicle, at informing the driver of the Host Motor-Vehicle of the presence of Relevant Motor-Vehicles deemed to be relevant to the driving safety, and dispatch on the automotive on-board communication network a list of virtual objects containing information on the Host Motor-Vehicle and on the Relevant Motor-Vehicles, for exploitation by one or more of the functionalities aimed at assisting the driver in driving the Host Motor-Vehicle, controlling the Host Motor-Vehicle, and informing the driver of the Host Motor-Vehicle of the presence of the Relevant Motor-Vehicles deemed to be relevant to the driving safety of the Host Motor-Vehicle, or exploit the information on the Host Motor-Vehicle and on the Relevant Motor-Vehicles in the implementation of one or more of the automotive functionalities aimed at assisting the driver in driving the Host Motor-Vehicle, controlling the Host Motor-Vehicl

A device includes a storage device configured to store a program; and a hardware processor, wherein, the hardware processor executes the program stored in the storage device to: recognize positions of a plurality of traffic participants; determine a temporary goal which each of the plurality of traffic participants is trying to reach in the future, based on the recognition results; and simulate a movement process in which each of the plurality of traffic participants moves toward the temporary goal using a movement model to estimate an action in the future of each of the plurality of traffic participants.

A system for gathering perception-data includes a transceiver and a controller-circuit. The transceiver is for installation on a host-vehicle. The transceiver is configured to receive perception-data from a perception-sensor installed on an assisting-vehicle proximate to the host-vehicle. The controller-circuit is in communication with the transceiver. The controller-circuit is configured to determine a preferred-perspective for gathering perception-data by the perception-sensor of the assisting-vehicle, and operate the transceiver to transmit a path-request to the assisting-vehicle that changes a planned-path of the assisting-vehicle to move the perception-sensor of the assisting-vehicle to the preferred-perspective