The present disclosure relates to an apparatus and method for controlling a vehicle. The processor determines whether a current driving situation of a broken vehicle in which the failure occurs is a parking mode or a driving mode, executes the parking mode logic such that the parking mode logic searches for a parking location of the broken vehicle and parks the broken vehicle at the parking location, when the current driving situation is the parking mode, executes the driving mode logic such that the broken vehicle drives on driving route excluding a ramp while the broken vehicle maintains a first inter-vehicle distance from a forward vehicle, when the current driving situation is the driving mode, and executes the driving mode logic such that the broken vehicle drives while the broken vehicle maintains a second inter-vehicle distance longer than the first inter-vehicle distance, when the driving route includes a congestion section.

The subject disclosure relates to techniques for enabling autonomous vehicles to reason about similarities of features between drivable areas. A process of the disclosed technology can include receiving first sensor data corresponding with a first roadway segment, receiving second sensor data corresponding with a second roadway segment, encoding the first sensor data into a first vector, wherein the first vector represents a first roadway characteristic associated with the first roadway segment, encoding the second sensor data into a second vector, wherein the second vector represents a second roadway characteristic associated with the second roadway segment, and determining a similarity between the first roadway segment and the second roadway segment based on the first vector and the second vector.

An energy-optimal vehicle control system for at least one vehicle including a roadway data source configured for providing traffic and map data including at least one drive segment of the at least one vehicle, and an electrical processing system operably coupled with the roadway data source. The electrical processing system includes an optimizer for generating an energy-optimal speed profile for the at least one drive segment, and the electrical processing system is configured for controlling the speed of the at least one vehicle in accordance with the energy-optimal speed profile.

An ACC function for performing constant speed cruise according to a target speed when there is no preceding other vehicle in a vehicle's own driving lane and performing following cruise by maintaining a predetermined inter-vehicle distance when there is a preceding other vehicle, an LKA function for maintaining cruise in the vehicle's own driving lane by following control to a target path, a function for performing automated lane change to a neighboring lane when there is no other vehicle in a predetermined range in the neighboring lane, an override function for stopping the automated lane change function by a driver's operation intervention, and a function for performing fallback control of the automated lane change function, with notifying the driver of stopping the automated lane change function and operation takeover.

A vehicle control system includes a position recognition part that recognizes a position of a vehicle, a trajectory generating part that generates a trajectory which includes a plurality of future target positions to be reached by the vehicle, the plurality of future target positions being consecutively aligned in time series, and a travel controller that derives a target speed when the vehicle is caused to travel along the trajectory on the basis of a distance between the plurality of target positions included in the trajectory and that corrects the target speed on the basis of a first deviation between the position of the vehicle recognized by the position recognition part and a first target position corresponding to a recognition time at which the recognition of the position of the vehicle has been performed among the plurality of target positions.

An automatic driving system includes a control device that controls automatic driving of a vehicle, and a storage device that contains external environment information indicating an external environment of the vehicle. A driving transition zone is a zone in which a driver of the vehicle takes over at least a part of driving of the vehicle, from the control device. A termination target velocity is a target velocity of the vehicle at an end point of the driving transition zone. The control device variably sets the termination target velocity, depending on the external environment at the end point or the external environment surrounding the end point. Then, the control device controls the velocity of the vehicle in the driving transition zone, such that the velocity of the vehicle at the end point is the termination target velocity.

The present technology relates to a vehicle control device, a vehicle control method, a program, and a vehicle that enable automatic driving to safely bring a vehicle from a parking position to a vehicle traffic region.

A vehicle control device includes a notification control unit that controls a notification to surroundings in a case where a vehicle moves from a parking position and an operation control unit that automatically moves the vehicle from the parking position to make the vehicle join a vehicle traffic region and temporarily stops the vehicle before the vehicle enters the vehicle traffic region. The present technology is applied to, for example, a vehicle that automatically drives.

Methods and systems for enhancing the functionality of a semi-autonomous vehicle are described herein. The semi-autonomous vehicle may receive a communication from a fully autonomous vehicle within a threshold distance of the semi-autonomous vehicle. If the vehicles are travelling on the same route or the same portion of a route, the semi-autonomous vehicle may navigate to a location behind the fully autonomous vehicle. Then the semi-autonomous vehicle may operate autonomously by replicating one or more functions performed by the fully autonomous vehicle. The functions and/or maneuvers performed by the fully autonomous vehicle may be detected via sensors in the semi-autonomous vehicle and/or may be identified by communicating with the fully autonomous vehicle to receive indications of upcoming maneuvers. In this manner, the semi-autonomous vehicle may act as a fully autonomous vehicle.

The present invention provides a vehicle control apparatus for controlling traveling of a vehicle, the apparatus comprising: a stop control unit configured to move the vehicle in a vehicle width direction and stop the vehicle in a traveling state; a notification unit configured to make a notification of the stop of the vehicle; and a change unit configured to change a notification method by the notification unit in accordance with a stop mode of the vehicle stopped by the stop control unit.

To minimize a pedal operation of a driver and to provide convenience of driving by flexibly controlling a maximum creep speed during a creep driving in a traffic congestion section, a vehicle includes: a radar configured to obtain speed information of a preceding vehicle and distance information to the preceding vehicle; a sensor configured to acquire behavior information of the vehicle; a controller configured to determine whether or not the vehicle has entered the traffic congestion section based on the behavior information of the vehicle, to determine a safety distance and a surplus distance related to the preceding vehicle, to determine a maximum creep speed and a creep torque based on the surplus distance, and to control operation of at least one of a motor or an engine to transmit the creep torque to a wheel of the vehicle.