Methods and systems for managing traversals of one or more vehicles through a traffic intersection are proposed. In one example, a method comprises: receiving a first message including one or more motion characteristics of one or more vehicles approaching the traffic intersection; forming a motion group; grouping a subset of the one or more vehicles into the motion group based on the one or more motion characteristics; assigning a leader vehicle for the motion group; determining a group maneuver target for the motion group to traverse through the traffic intersection; and transmitting, to the leader vehicle of the motion group, a second message including the group maneuver target for the motion group, to enable the leader vehicle of the motion group to control a motion of each member vehicle of the motion group based on the group maneuver target.

Systems and methods for managing speed thresholds for a fleet of vehicles are disclosed. Input is used to provide associations between particular weather-relation conditions (such as rain) and arithmetic operations, that may be used to determine a current speed threshold as a function of a local posted speed limit at the current location of a vehicle. The current speed threshold is subsequently used to detect whether vehicles are exceeding the current speed threshold.

A travelling support system includes a receiving unit configured to receive parked/stopped vehicle information indicating a detection of a parked/stopped vehicle on a travelling road from a preceding vehicle which is travelling or a sensor on the travelling road; and a predicting unit that predicts, based on the parked/stopped vehicle information and a duration predicting model that predicts a parked/stopped duration as a duration in which the parked/stopped vehicle continues to park or stop, the parked/stopped duration.

A motor vehicle has at least one driver assistance system and a navigation system that generates a three-dimensional map and a route-related navigation representation when route guidance is activated by the navigation system. When the at least one driver assistance system is activated, sensor data describing the surroundings of the motor vehicle are acquired by at least one sensor unit of the motor vehicle according to a data acquisition rule of the driver assistance system. The acquired sensor data is evaluated to generate at least one driver assistance related additional information representation. The map with the route-related navigation representation and the driver assistance related additional information representation are output by a display device in the motor vehicle.

A computing framework for addressing a variety of vehicle conditions includes receiving, from a first set of sensors by an edge compute node, first transportation network data associated with a transportation network region, receiving, from a second set of sensors by a cloud computing node, second transportation network data associated multiple transportation network regions, providing, by the edge compute node to one or more autonomous vehicles at the transportation network region, real-time transportation network region information based on at least the first transportation network data to facilitate control decisions by the one or more autonomous vehicles, and providing, by the cloud computing node to at least the one or more autonomous vehicles, non-real-time transportation network region information based on at least the second transportation network data to facilitate the control decisions by the at least one or more autonomous vehicles.

Embodiments of the present disclosure set forth techniques for providing speed limit information to a vehicle. In an aspect, a computer-implemented method includes receiving, from a vehicle, navigation information associated with the vehicle; determining one or more predicted positions associated with the vehicle based on the navigation information; determining one or more candidate map regions associated with the vehicle based on the one or more predicted positions; associating corresponding speed limit information with each of the one or more candidate map regions; and transmitting, to the vehicle, the one or more candidate map regions; wherein the one or more candidate map regions are usable by the vehicle to provide speed limit information to a driver of the vehicle.

Systems, methods, computer-readable media, and apparatuses for providing hazard detection and broadcast functions are provided. In some examples, sensor data may be captured by a mobile device, vehicle, or the like. The data may be used to detect a hazard, identify a type of hazard, and the like. One or more users or groups of users for notification of the hazard may be identified and one or more notifications may be transmitted to users within the group.

A facility for providing vehicle to vehicle event notification for connected and/or unconnected vehicles is disclosed. The facility enables a vehicle to detect an occurrence of a vehicle status trigger event and identify information describing an event type. The facility determines a priority of the vehicle status event based at least in part on the type of the vehicle status event. When the vehicle status event is to be reported to at least one other vehicle, the facility enables the vehicle to generate a vehicle status event message that includes the priority of the vehicle status event and at least a portion of the information describing the type of the vehicle status event. The vehicle status event message is then transmitted/broadcasted to at least one other vehicle.

Various aspects of a system and method for driving assistance along a path are disclosed herein. In accordance with an embodiment, a unique identifier is received from a communication device at an electronic control unit (ECU) of a first vehicle. The unique identifier is received when the first vehicle has reached a first location along a first portion of the path. A communication channel is established between the first vehicle and the communication device based on the received unique identifier. Data associated with a second portion of the path is received by the ECU from the communication device based on the established communication channel. Alert information associated with the second portion of the path is generated by the ECU based on the received data.

This disclosure relates to a distributed data center that includes resources carried by a fleet of vehicles. The system includes sensors configured to generate output signals conveying information related to the vehicles and/or the surroundings of vehicles. The system includes a remote computing server configured to maintain map data and distribute it to the fleet, including local map data to individual vehicles pertaining to their surroundings. Individual vehicles may compare the local map data with the information related to their individual surroundings. Based on such comparisons, individual vehicles may detect discrepancies between the local map data and the information related to their individual surroundings. The remote computing server may modify and/or update the map data based on the detected discrepancies.