Embodiments of the present invention provide computer-implemented methods, computer program products and systems. Embodiments of the present invention can receive position and location information. Embodiments of the present invention can generate a risk score for one or more maneuvers associated with a predicted trajectory of a vehicle. Embodiments of the present invention can generate a visual representation for each of the one or more maneuvers associated with the predicted trajectory of the vehicle based on the generated risk score associated with each maneuver. Embodiments of the present invention can integrate the generated visual representation into a user display.

An information processing apparatus includes a processor configured to cause thing objects respectively corresponding to things in a real world to be displayed in a virtual space. Each thing object for a corresponding one of the things is displayed in a location closer to a person related to the things than in a location of a different one of the things if a degree of matching between a condition required for the thing by the person related to the things and an attribute of the thing is higher than a degree of matching of the different thing.

The present disclosure relates to systems and processes for interacting with mapping applications. In one example, a virtual assistant server can efficiently communicate with a map server to provide a user with map data in response to spoken user requests received at a user device. In another example, communicatively coupled electronic devices can be synchronized such that a location marker generated on one device can be displayed on the other device. In another example, an electronic device can display simplified views of individual route directions that can be updated based on movement of the user or in response to user requests. In another example, an electronic device can selectively display an interface including a current location of a user or an interface including a route to a predicted destination based on contextual information associated with the user. The interfaces can include affordances for launching an associated mapping application.

Systems and methods are described for improved navigation assistance by providing overview directions focusing on points where other users tend to make mistakes or display emotional responses, such as stress, that indicate that they feel they may make mistakes. In an exemplary method, a navigation process receives information about a present user's navigation route, the present user's status, and the user history. The navigation service compiles the received information and determines an enhanced navigation route.

A system and method for automated semantic map generation includes at least a processing system with at least one processing device. The processing system is configured to generate a probabilistic road model for road elements. The processing system is configured to generate a probabilistic traffic model for the road model. The processing system is configured to perform statistical inference on the road model and the traffic model. The processing system is configured to generate an estimate of a semantic road model based on the statistical inference. The processing system is configured to generate a semantic map that includes the estimate of the semantic road model.

One example provides a computing device configured to capture, via the camera, first image data imaging a first physical world location, create a first spatial representation of the first physical world location based on the first image data, receive a user input defining a pose of a first virtual spatial anchor point relative to a feature imaged in the first image data, track user movement to a second physical world location, capture second image data imaging the second physical world location, receive a user input defining a pose of a second virtual spatial anchor point relative to a feature imaged in the second image data, and send, to a remote computing device, data representing the first spatial representation, the pose of first spatial anchor point, the second spatial representation, the pose of second spatial anchor point, and a positional relationship between first and second spatial anchor points.

The vehicle navigation device guides a user of a vehicle to a destination. The vehicle navigation device includes a car navigation system that acquires the destination, a head-up display that displays various information, and a body ECU that controls the information displayed on the head-up display based on the destination acquired by the car navigation system. The body ECU is configured to cause, on the assumption that the user alights from the vehicle at a current location, the head-up display to display post-alighting guidance information which is information for guiding the user to the destination regarding, for example, walking.

An investigation assist device includes a processor and a storage that records information on a road map including a plurality of intersections and captured videos of a plurality of cameras in correlation with a capturing time, camera information, and intersection information. The processor retrieves at least one vehicle satisfying a retrieval condition and extracts a traveling direction of the vehicle when passing through each of the plurality of intersections based on the captured videos of the plurality of cameras in response to a designation of the retrieval condition including information on time when an incident occurs and feature information on a vehicle causing the incident. The processor superimposes a traveling route of the vehicle on the road map based on the traveling direction extracted for each of the intersections and outputs the traveling route to an output unit.

A method for depicting location attributes in a map environment. The method includes receiving a request for parameters about a first type of location. The method includes determining a first set of directional arrows, where each directional arrow is associated with a location and has a first set of properties based on the parameters about the first type of location. The method further includes determining a selection of a first directional arrow, which is associated with a first location, from the first set of directional arrows. Modifications to the first set of directional arrows are made based on the selection of the first directional arrow.

According to some aspects, a wearable device is provided. The wearable device includes a memory, one or more antennas, one or more processors coupled with the memory and the one or more antennas, a location manager component executable by the one or more processors and configured to determine a location of the wearable device, and a direction manager component executable by the one or more processors. The direction manager component may be configured to receive, via the one or more antennas, information descriptive of a location of the medical device, determine a path between the location of the wearable device and the location of the medical device, and provide information descriptive of the path.