A wrong way vehicle countermeasure system may include at least one movement sensor positioned along a roadway and a wireless communications device. The system may further include a controller configured to cooperate with the at least one movement sensor to detect a wrong way vehicle on the roadway, and responsive to the detection of the wrong way vehicle on the roadway by the movement sensor, wirelessly send a countermeasure command to the wrong way vehicle via the wireless communications device to cause the wrong way vehicle to perform at least one wrong way driving countermeasure.

The present invention extends to methods, systems, and computer program products for controlling skidding vehicles. In general, a vehicle adjusts its configuration to mitigate the skidding. The vehicle can recognize dynamic skid situations and apply strategies to avoid an accident. In response to a signal that a vehicle is in a specified type of skid, the vehicle's configuration can be automatically changed to recover from the skid. Different configuration changes can be used to recover from different skid types, including: oversteer, understeer and counter steer. Changing vehicle configuration can include utilizing vehicle systems such as, for example, steering, braking, cruise control, lane keeping, etc.

A control system which for use in a host motor vehicle is configured and intended for recognizing motor vehicles traveling ahead, to the side, and/or behind and preferably stationary objects situated ahead, based on surroundings data obtained from at least one surroundings sensor associated with the host motor vehicle. The at least one surroundings sensor is configured for providing an electronic controller of the control system with surroundings data that represent an area in front of the host motor vehicle. The control system is at least configured and intended for detecting another motor vehicle, using the road, in front of the host motor vehicle by means of the at least one surroundings sensor, and determining movements of the other motor vehicle relative to a lane in which the other motor vehicle or the host motor vehicle is present, or relative to the host motor vehicle, determining, starting from an instantaneous location, a set having a predefined number of trajectories, differing with regard to their length and/or their course, for possible paths of the host motor vehicle, wherein the course of neighboring trajectories differs by a predefined difference between possible different steering angles of the host motor vehicle, and varying the predefined number of trajectories, the length, and/or the course of the trajectories as a function of a driving situation of the host motor vehicle, and generating at least one signal that assists a driver of the host motor vehicle in controlling the host motor vehicle in order to guide the host motor vehicle at least along a collision-free trajectory, or generating at least one associated control command that causes the host motor vehicle to follow at least one of the collision-free trajectories.

A lane keeping assistance system (LKAS) is a system that detects a lane through a sensor and prevents a vehicle from deviating from the lane by changing positional information of the detected lane to a torque value. Disclosed are an apparatus and a method for controlling lane keeping of a vehicle that start or cancel a lane keeping function based on driving state of the vehicle.

A vehicle travel control apparatus includes an anomaly monitoring section for determining, through monitoring, whether or not a driver is in an anomalous state in which the driver has lost his or her ability to drive the vehicle, and a deceleration section for automatically stopping the vehicle by decelerating the vehicle after a final anomaly determined time which is a point in time when the anomaly monitoring section finally determines that the driver is in the anomalous state. The deceleration section prohibits deceleration of the vehicle in the case where the deceleration section determines that the vehicle is present in the deceleration prohibited section after the final anomaly determination time.

A vehicle controller performs traveling control of a vehicle. The traveling control includes lane departure prevention control of turning the vehicle in a direction in which lane departure of the vehicle is avoided and roll stiffness control of changing a roll stiffness of the vehicle. The vehicle controller executes the roll stiffness control by coupling with execution of the lane departure prevention control.

A driving control system for a vehicle is provided. The vehicle includes a steering device, a steering operation amount sensor that detects a steering operation amount of the driver, and an abnormality determining device configured to determine whether the driver is in an abnormal state. The driving control system includes: an actuator configured to adjust a turning state quantity; and an electronic control unit configured to calculate a target turning state quantity of the vehicle based on the steering operation amount and control the turning state quantity adjusting device. The electronic control unit is configured to correct the target turning state quantity such that a magnitude of the target turning state quantity does not exceed a predetermined allowable range and to control the actuator based on the corrected target turning state quantity when the driver is in the abnormal state.

A vehicle includes: motor(s), steering, processor(s) configured to: (a) receive a current heading; (b) receive a desired heading; (c) calculate a first steering angle (FSA) based on (a) and (b); (d) move the vehicle, via the motor(s) and steering: (i) in a first direction based on the FSA; (ii) in a second, opposing direction, based on an opposite of the FSA.

A driving support apparatus performing a plurality of driving support includes: a reliability acquiring unit that acquires each reliability of a plurality of detection apparatus, the reliability representing likelihood of a detection result of the detection apparatus; a determination unit that determines whether or not each of the detection apparatus is a high reliability apparatus determined based on a reliability threshold; a correspondence acquiring unit that acquires correspondence information representing a correspondence between combinations of the plurality of detection apparatus including information of whether or not each apparatus is a high reliability apparatus, and types of driving support to be performed; a setting unit that sets a driving support to be performed, based on a result of the determination; an executing unit that executes the driving support to be performed; and an output unit that outputs a command to allow the executing unit to execute the driving support.

A target steering angle calculator calculates, based on a target curvature, a target steering angle representing a steering angle of the vehicle at a target position. A current steering-angle obtainer obtains a current steering angle representing a steering angle of the vehicle at a current position. A steering controller controls the steering of the vehicle to cause the current steering angle to follow the target steering angle. A distance estimator estimates, based on at least one of the environmental information around the vehicle and control information about the vehicle, a visible distance representing a distance visibly recognizable by the driver of the vehicle to a front of the vehicle. The target curvature obtainer uses the visible distance as the target distance to obtain the target curvature at the predetermined target position that has the visible distance away from the current position along the road in the travelling direction.