A vehicle control device recognizes surrounding circumstances of a vehicle, controls steering and acceleration/deceleration of the vehicle without depending on an operation of a driver of the vehicle, determines any one of a plurality of driving modes including a first driving mode and a second driving mode as a driving mode of the vehicle, changes the driving mode of the vehicle to a driving mode in which the task is heavier when a task associated with the determined driving mode is not executed by the driver, determines whether or not the map information includes an error and determines whether or not a road division line is included in the surrounding circumstances, and sets a longer traveling continuation distance in the second driving mode in a case where it is determined that the map information includes an error, the road division line is not included in the surrounding circumstances, and a preceding vehicle has been recognized.

In an apparatus and a method for providing information on autonomous driving of a vehicle to a passenger of the vehicle, when it is recognized whether partial autonomous driving of a vehicle is activated, information on whether a user operates a device including a display may be acquired, and it is determined the user operates the display in a state in which the partial autonomous driving is activated, information on the autonomous driving of the vehicle may be output through the display. An effect of inducing an alert measure of the driver against a dangerous situation may be provided by providing driving information at a site, at which a sight of the driver stays.

A vehicle control device recognizes a surrounding situation of a vehicle, controls steering and acceleration or deceleration of the vehicle without depending on an operation of a driver of the vehicle based on the surrounding situation and map information, determines a driving mode of the vehicle to be one of a plurality of driving modes including a first driving mode and a second driving mode, determines whether there is an error in the map information based on the surrounding situation and the map information, and in a case where an error is determined in the map information while the vehicle is driving in the second driving mode, continues the second driving mode when a preceding vehicle is recognized within a first predetermined distance, or changes the second driving mode to the first driving mode when a preceding vehicle is not recognized within the first predetermined distance.

The techniques of this disclosure relate to a driver-monitoring system. The system includes a controller circuit that receives monitoring data from a driver-monitor sensor that is configured to monitor a driver of a vehicle while the vehicle operates in an autonomous-driving mode. The controller circuit determines a score of one or more driver-supervisory metrics based on the monitoring data, each of the driver-supervisory metrics being indicative of whether the driver is supervising the operation of the vehicle. The controller circuit determines a supervision score based on the score of the driver-supervisory metrics. The supervision score is indicative of whether the driver is ready to resume control of the vehicle. The controller circuit indicates a driver-awareness status on a display in a field of view of the driver based on the supervision score. The system can improve vehicle safety by alerting the driver when the driver exhibits reduced driver awareness behavior.

A method for determining event data including: sampling a first data stream within a first time window at a first sensor of an onboard vehicle system coupled to a vehicle, extracting interior activity data from the first data stream; determining an interior event based on the interior activity data; sampling a second data stream within a second time window at a second sensor of the onboard vehicle system; extracting exterior activity data from the second image stream; determining an exterior event based on the exterior activity data; correlating the exterior event and the interior event to generate combined event data; automatically classifying the combined event data to generate an event label; and automatically labeling the first time window of the first data stream and the second time window of the second data stream with the combined event label to generate labeled event data.

A control system of a vehicle determines whether to require a shift from a first travel state in which an operation by a driver is not required to a second travel state in which the operation by the driver is required; makes an operation request to the driver when the shift is required; determines whether the driver has performed an operation in response to the request; and stops the vehicle in a predetermined position when the driver has not performed the operation, wherein in a case in which a lane change operation is required to stop the vehicle in the predetermined position, a speed of travel of the self-vehicle is reduced in accordance with each of a vehicle speed set for a first lane before the lane change operation and a vehicle speed set for a second lane after the lane change operation.

An offroad travel assistance system for a user vehicle includes one or more processors and a memory communicably coupled to the one or more processors and storing a user vehicle configuration evaluation module including computer-readable instructions that when executed by the one or more processors cause the one or more processors to determine if user vehicle configuration information describing the user vehicle is consistent with ride information similar to the user vehicle configuration information and describing a traversal of an offroad trail by a reference vehicle and, responsive to a determination that the user vehicle configuration information is not consistent with the ride information, autonomously control at least one portion of the user vehicle so as to prevent operation of the user vehicle to traverse the offroad trail.

A computer includes a processor and a memory storing instructions executable by the processor to determine, for a host vehicle operating in a first operation mode, a first operation mode transition location based on a time to transition the host vehicle from the first operation mode to a second operation mode, a current speed of the host vehicle, and a distance from the host vehicle to an operation mode transition boundary location, to determine a second operation mode transition location that is a specified distance from the first operation mode transition location, the specified distance based on the current host vehicle speed, to transition from the first operation mode to the second operation mode upon reaching the first operation mode transition location, and to transition from the second operation mode to the first operation mode when the second operation mode transition location is between a current location of the host vehicle and the operation mode transition boundary location.

A system includes an acquisition unit that acquires an operation amount or a duration count, and a switching unit that switches a driving state. The switching unit switches the driving state to the cooperative driving state when the operation amount is equal to or greater than an intervention threshold and less than a start threshold or the duration count is equal to or greater than a first threshold and less than a second threshold during the autonomous driving state, switches the driving state to the autonomous driving state when the operation amount is less than the intervention threshold or the duration count is less than the first threshold during the cooperative driving state, and switches the driving state to the manual driving state when the operation amount is equal to or greater than the start threshold or the duration count is equal to or greater than the second threshold.

The present disclosure provides a method and an apparatus for vehicle control. The method includes: obtaining (101) manual operation information of a vehicle; determining (102) an intervention intention of a driver based on the manual operation information; and controlling (103), when the vehicle is currently in an automated driving mode and the intervention intention is determined to be a slow intervention, the vehicle to reach a predetermined safe state and handing corresponding control of the vehicle over to the driver. The method and apparatus can solve potential safety problems in vehicle control and improve safety of the vehicle control.