A seat-mounted airbag device includes an inflator that is operated when a vehicle collision is detected or predicted and ejects gas and an airbag body that includes a front-rear chamber and a tip chamber. The front-rear chamber is deployed forward of a seat through a clearance between a window and a head of an occupant from a side portion of a headrest on a window side by the gas ejected from the inflator and disposed between the window and the head of the occupant. The tip chamber is deployed inward in a seat width direction from an end portion of the front-rear chamber on a seat front side and disposed forward of a face of the occupant on the seat front side. The airbag body housed in the side portion includes Fan outward wound portion wound outward in a roll shape with a seat up-down direction as an axial direction.

A vehicle includes: a bumper assembly defining opposite lateral ends and an overall width extending therebetween, the bumper assembly defining a recessed area located between the opposite lateral ends thereof; an electronic sensor supported by the bumper assembly in cantilevered relation; and an energy absorber positioned within the recessed area to protect the electronic sensor and reduce dislocation of the electronic sensor by absorbing energy resulting from an impact between the vehicle and an external object. The energy absorber defines opposite lateral ends and an overall width extending therebetween less than that the overall width of the bumper assembly such that the opposite lateral ends of the energy absorber are spaced inwardly from the opposite lateral ends of the bumper assembly.

A method for controlling the actuation of an actuatable restraint to help protect a vehicle occupant in response to a rollover event is implemented in a controller of a vehicle safety system that includes the actuatable restraint. To implement the method, the controller is configured to execute a roll discrimination metric that discriminates the occurrence of a ramp rollover event or an embankment rollover event in response to a vehicle roll rate (R_RATE) having a magnitude that exceeds a predetermined threshold roll rate (R_RATE). The controller is also configured to execute a switching metric that is operative to reduce the predetermined threshold roll rate (R_RATE) in response to a vehicle pitch rate (P_RATE) having a magnitude that exceeds a predetermined threshold pitch rate (P_RATE).

Methods and systems for autonomous vehicle recharging or refueling are disclosed. Autonomous vehicles may be automatically refueled by routing the vehicles to available fueling stations when not in operation, according to methods described herein. A fuel level within a tank of an autonomous vehicle may be monitored until it reaches a refueling threshold, at which point an on-board computer may generate a predicted use profile for the vehicle. Based upon the predicted use profile, a time and location for the vehicle to refuel the vehicle may be determined. In some embodiments, the vehicle may be controlled to automatically travel to a fueling station, refill a fuel tank, and return to its starting location in order to refuel when not in use.

A control device to be mounted on a vehicle, includes: a board; a control circuit which is provided on the board and is configured to execute a control in a case of a collision of the vehicle; a case in which the board is accommodated; and a bracket that extends from a side surface of the case and is to be fixed to the vehicle with a fastening member, and the bracket includes: a groove portion that extends in an intersection direction intersecting an extending direction of the bracket from the case; and a protrusion that closes a part of the groove portion.

A system and method are provided for controlling an interior configuration of a vehicle. The system may include an interior vehicle component; an actuator component configured to adjust/restrict movement of a physical configuration of the interior vehicle component; one or more sensors configured to collect data corresponding to a state of the vehicle, an action of the vehicle, and/or an internal or external environment of the vehicle; and one or more processors configured to receive sensor data and detect, by processing the sensor data, a vehicle accident condition. After the one or more processors detect the vehicle accident condition, the one or more processors may cause the actuator component to adjust the interior vehicle component from a first physical configuration to a second physical configuration, or may cause the actuator component to restrict movement of the interior vehicle component to a predetermined range of physical configurations.

A measurement apparatus unit is mountable to a vehicle. The measurement apparatus unit includes a first sensor, a first storage apparatus, and a first relay. The first sensor is arranged in a first area among a plurality of areas that are segmented in advance in the vehicle. The first storage apparatus stores therein detection data that is acquired from the first sensor. The first storage apparatus is arranged in a second area that differs from the first area among the plurality of areas. The first relay communicably connects at least the first sensor and the first storage apparatus. The first area and the second area are separated from each other in a traveling direction of the vehicle.

A crash sensor system includes an electronic control unit (ECU). The ECU has an accelerometer to measure longitudinal acceleration of the vehicle. Front crash satellite sensors are mounted at the front of the vehicle to detect a front or a rear crash event. When a front or rear crash event occurs, the first accelerometer is utilized to determine if the crash occurred at the front or the rear of the vehicle, regardless of the polarity of the front crash satellite sensors.

To shorten a time required to predict collision with other vehicles, a collision prediction device includes: a detection unit configured to detect each of a front, a rear, and a side of other vehicles located around a vehicle from a captured image of one frame in which surroundings of the vehicle are imaged; and a determination unit configured to determine a likelihood of collision with the other vehicles based on a detection result of the detection unit. The determination unit determines that the likelihood of collision with the other vehicle of which only the front or only the rear is detected is high in the other vehicles of which one or more of the front, the rear, and the side are detected by the detection unit.

Methods and systems for communicating between autonomous vehicles are described herein. Such communication may be performed for signaling, collision avoidance, path coordination, and/or autonomous control. A computing device may receive data for the same road segment from autonomous vehicles, including (i) an indication of a location within the road segment, and (ii) an indication of a condition of the road segment. The computing device may generate, from the data for the same road segment, an overall indication of the condition of the road segment, which may include a recommendation to vehicles approaching the road segment. Additionally, the computing device may receive a request from a computing device within a vehicle approaching the road segment to display vehicle data. The overall indication for the road segment may then be displayed on a user interface of the computing device.