The disclosure includes implementations for modifying an operation of an Advanced Driver Assistance System (“ADAS system”) of a vehicle based on one or more preferences of a user for the operation of the ADAS system. Some implementations of a method may include receiving a wireless message from a wireless network. The wireless message may include optimization settings data describing how to modify an operation of the ADAS system of the vehicle based on one or more preferences of a user for the operation of the ADAS system. The user may include a human who has reserved the vehicle for their use. The method may include modifying one or more control parameters of the ADAS system based on the optimization settings data so that the operation of the ADAS system conforms with the one or more preferences of the user for the operation of the ADAS system.

Autonomous control of a subject vehicle including a longitudinal motion control system includes determining states of parameters associated with a trajectory for the subject vehicle and parameters associated with a control reference determined for the subject vehicle. A range control routine is executed to determine a first parameter associated with a range control command based upon the states of the plurality of parameters, and a speed control routine is executed to determine a second parameter associated with a speed control command based upon the states of the plurality of parameters. An arbitration routine is executed to evaluate the range control command and the speed control command, and operation of the subject vehicle is controlled to achieve a desired longitudinal state, wherein the desired longitudinal state is associated with a minimum of the range control command and the speed control command.

An autonomous system may selectively displace human driver control of a host vehicle. The system may receive an image representative of an environment of the host vehicle and detect an obstacle in the environment of the host vehicle based on analysis of the image. The system may monitor a driver input to a throttle, brake, and/or steering control associated with the host vehicle. The system may determine whether the driver input would result in the host vehicle navigating within a proximity buffer relative to the obstacle. If the driver input would not result in the host vehicle navigating within the proximity buffer, the system may allow the driver input to cause a corresponding change in one or more host vehicle motion control systems. If the driver input would result in the host vehicle navigating within the proximity buffer, the system may prevent the driver input from causing the corresponding change.

A method for operating a control device for the autonomous guidance of a motor vehicle, wherein a nominal speed is predetermined as a driving speed to be set by the control device and another vehicle driving in front more slowly than the nominal speed is detected by a detection device of the control device, wherein a speed difference of a driving speed of the other vehicle with respect to the nominal speed is greater than zero but smaller than a predetermined maximum value. In this case, an accumulator value is set to a starting value and a current speed value of the speed difference is detected and depending on the speed value, an advantage value is formed and the advantage value is added to the accumulator value. If the accumulator value meets a predetermined overtaking criterion, an overtaking signal is generated for allowing an overtaking maneuver.

A driving consciousness estimation device includes a driving readiness estimation unit configured to estimate a driving readiness relating to a driving consciousness of the driver from a driver's reaction to the travelling environment, a driving task demand estimation unit configured to estimate a driving task demand which is an index required for the driver with respect to the driving readiness from the travelling environment, and an attention awakening unit configured to execute awakening of attention for the driver relating to the driving of the vehicle based on the result of comparison between the driving readiness and the driving task demand.

Provided is a driving assist device 10 that recognizes an object in the vicinity of a moving body, and assists a driver in driving the moving body, the apparatus including: an object detecting unit 12 that detects the object in the vicinity of the moving body; a three dimensional object detecting unit 13 that detects a three dimensional object in the vicinity of the moving body; and an object recognition unit 18 that recognizes the object at a predetermined detection position as a non-obstacle when the object information storing unit 16 stores the position of the object, and the three dimensional object information storing unit 17 does not store the position of the three dimensional object at the predetermined position in which detection is performed by both of the object detecting unit 12 and the three dimensional object detecting unit 13.

In a vehicle travel control apparatus configured to determine a target acceleration of an own vehicle based on an inter-vehicle distance to a predicted cutting-in vehicle predicted to cut in between the own vehicle and a following target vehicle as well as an inter-vehicle distance to the following target vehicle, it is necessary to notify a driver of the presence of the predicted cutting-in vehicle at an appropriate timing. A cutting-in probability, which is a probability that the predicted cutting-in vehicle carries out the cutting in, is acquired, and information on the predicted cutting-in vehicle is notified to the driver from a time point when a state where the cutting-in probability is higher than a start probability threshold has continued for a predetermined period to a time point when a state where the cutting-in probability is lower than an end probability threshold has continued for a predetermined period.

Systems, methods, and other embodiments described herein relate to providing cooperative control according to system conditions of a vehicle. In one embodiment, a method includes determining a system condition associated with operation of functions associated with an assistance system within an ego vehicle. The system condition is based, at least in part, on environmental conditions around the ego vehicle. The method includes defining available modes according to which control modes of the ego vehicle can operate with the system condition. The method includes controlling the ego vehicle according to a selected mode of the available modes.

A communication system for a vehicle, with a processor designed to determine a driving situation of the vehicle, and a communication interface designed to receive V2X communication data of a first additional vehicle, wherein the V2X communication data defines a driving situation of the first additional vehicle, wherein the processor is designed to detect a second additional vehicle which is located between the vehicle and the first additional vehicle on the basis of the determined driving situation of the vehicle and the driving situation of the first additional vehicle.

A convoy travel control apparatus includes: a communication portion; a travel control portion; and a joining control portion, wherein when an own vehicle is travelling in convoy while being incorporated in a group of convoy vehicles travelling in convoy, if the communication portion has received, from an independent vehicle not incorporated in the group of convoy vehicles travelling in convoy, request information to incorporate the independent vehicle into the group of convoy vehicles, then the joining control portion determines a positional relationship between a position of the group of convoy vehicles and a position of the independent vehicle, and wherein if the independent vehicle is travelling along a side of the group of convoy vehicles, then in order to incorporate the independent vehicle into the group of convoy vehicles, the joining control portion exercises control on the group of convoy vehicles via the communication portion.