A vehicle control device causes an automatic brake to function even for an obstacle suddenly appearing from outside a sensor detection range in a place estimated to be dangerous such as an intersection. A vehicle control device calculates time-to-collision TTC based on a detection result of an obstacle sensor, and controls a brake, which is an actuator of a vehicle, based on the calculated time-to-collision TTC. The vehicle control device includes a determination unit that determines right turn or left turn of the vehicle, and a command unit that sends a command according to a determination result of the determination unit to the brake. When determining that the vehicle is turning right or left, the determination unit changes the time-to-collision TTC to a longer value by extending more than that at the time of traveling straight.

A prediction apparatus for predicting a predicted trajectory for a safety driver assistant system for a vehicle includes a receiving unit and a determination unit. The receiving unit is configured to receive at least one sensor information from at least one vehicle sensor of the vehicle and at least one trajectory information from at least one further driver assistant system of the vehicle. The determination unit is configured to determine the predicted trajectory for the vehicle using planned the trajectory information or the sensor information.

An evaluation apparatus for evaluating a predefined trajectory hypothesis for a vehicle includes a calculation unit, a detection unit and an assigning unit. The calculation unit is configured to calculate at least one necessary driving parameter for the vehicle to follow the predefined trajectory hypothesis. The detection unit is configured to detect a current driving parameter of the vehicle. The assigning unit is configured to assign a probability value for the vehicle to follow the predefined trajectory hypothesis using the current driving parameter and the necessary driving parameter.

A vehicle collision avoidance and driver notification system includes an object detection unit configured to detect environmental obstacles and a collision detection unit for assessing risk of collision. Depending on risk assessment, a collision avoidance unit gives feedback to the driver or directly interacts with the vehicle engine.

Provided are systems for switchable wheel view mirrors, which can selectively provide views of one or more wheels of a vehicle to, for example, check for obstructions. A system for a switchable wheel view mirror can include an image sensor coupled to a vehicle, a reflective surface, and an actuator. The image sensor can capture an image within a field of view of the image sensor. The reflective surface can be coupled to the actuator which moves the reflective surface between a first position and a second position. In the first position, a view of at least a portion of a wheel of the vehicle is visible within the reflective surface and the reflective surface is disposed at least partially within the field of view of the image sensor. Methods and computer program products are also provided.

A vehicle-exterior-notification control device includes processing circuitry to detect a person present around a crosswalk present in a traveling direction of a first vehicle on a basis of information output from a surrounding information detecting device to detect information around the first vehicle, to detect whether or not the person has an intention to cross the crosswalk before the first vehicle, a vehicle control unit to execute stop control to stop the first vehicle in a case where it is detected that the person has an intention to cross the crosswalk before the first vehicle, to detect a second vehicle present around the first vehicle on a basis of information output from the surrounding information detecting device, and to issue a vehicle-notification instruction for making a notification to the second vehicle in a case where the stop control is executed.

A method includes, in response to an ignition on signal: determining, using one or more sensors, whether a host vehicle is moving from a first lane to a second lane; determining, using one or more sensors, whether an object is in at least one of a blind zone of the host vehicle and in the second lane within a threshold distance of the host vehicle; in response to a determination that an object is in at least one of the blind zone of the host vehicle and in the second lane within the threshold distance of the host vehicle, performing at least one operator assistance maneuver; and, in response to a determination that an object is not in at least one of the blind zone of the host vehicle and in the second lane within the threshold distance of the vehicle, not performing the at least one operator assistance maneuver.

A collision visualization device includes an identification unit analyzing vehicle traveling information in which information representing at least a type and occurrence time of an event generated in a vehicle to be analyzed in a time period including occurrence time of a collision or each of a series of collisions occurring for the vehicle, is recorded in accordance with occurrence order, and identifying a state of the vehicle in the time period, and a visualization unit causing a display device to display an iconic image representing the state of the vehicle identified by the identification unit.

Systems and methods for controlling navigation of an autonomous vehicle for making an unprotected turn while traversing an intersection. The methods may include identifying a loiter pose of an autonomous vehicle for stopping at a point in an intersection before initiating an unprotected turn, initiating navigation of the autonomous vehicle to the loiter pose when a traffic signal is at a first state, determining whether the traffic signal has changed to a second state during or after navigation of the autonomous vehicle to the loiter pose, and in response to determining that the traffic signal has changed to the second state, generating a first trajectory for navigating the autonomous vehicle to execute the unprotected turn if the expected time for moving the autonomous vehicle from a current position to a position when the autonomous vehicle has fully exited an opposing conflict lane is less than a threshold time.

A vehicular collision avoidance system includes a forward-viewing camera viewing through the windshield at least forward of the equipped vehicle, a rearward-sensing radar sensor sensing at least rearward of the equipped vehicle, and an electronic control unit. The vehicular collision avoidance system detects vehicles present forward and/or rearward of the equipped vehicle. Responsive to data processing of radar data captured by the rearward-sensing radar sensor, the vehicular collision avoidance system detects another vehicle approaching the equipped vehicle from the rear, determines distance between the equipped vehicle and the other vehicle, and determines speed difference between the equipped vehicle and the other vehicle. Based at least in part on the determined distance between the equipped vehicle and the other vehicle and the determined speed difference between the equipped vehicle and the other vehicle, the vehicular collision avoidance system controls the equipped vehicle to mitigate impact by the other vehicle.