Abstract: A vehicle includes a controller programmed to identify a seating position in the vehicle corresponding to each of a plurality of nomadic devices in communication with the vehicle. The controller is configured to receive at least one seating profile from each of the nomadic devices and adjust seating parameters for each of the seating positions according to the seating profile received from the corresponding nomadic device.

Abstract: A vehicle includes a controller programmed to identify a seating position in the vehicle corresponding to each of a plurality of nomadic devices in communication with the vehicle. The controller is configured to receive at least one seating profile from each of the nomadic devices and adjust seating parameters for each of the seating positions according to the seating profile received from the corresponding nomadic device.

Abstract: A hands-free power closure system for a vehicle includes a a power-operated closure, a proximity sensor system defining a predetermined sensing range, and a remote entry device adapted to store a power-operated closure open command in memory for a predetermined time period. The system further includes a power-operated closure control module in operative communication with the remote entry device, the proximity sensor system, and the power-operated closure. The remote entry device processor is adapted to disable the power-closure open command on expiration of the predetermined time period.

Abstract: A front end structure is provided for a vehicle that includes a bracket for attaching front crash sensors to the vehicle. The front end structure includes an engine compartment and a hood connected to the engine compartment by a hood latch and a pair of hinges. The bracket is connected to the hood latch and the front crash sensors to maintain palpability with the vehicle through the hood in a collision.

Abstract: A front end structure is provided for a vehicle that includes a bracket for attaching front crash sensors to the vehicle. The front end structure includes an engine compartment and a hood connected to the engine compartment by a hood latch and a pair of hinges. The bracket is connected to the hood latch and the front crash sensors to maintain palpability with the vehicle through the hood in a collision.

Abstract: A method of controlling a vehicle includes providing a vehicle having a brake system configured to operate according to a nominal mode in which applied braking pressure is based on a driver braking request, a first active braking mode in which applied braking pressure is based on maximum ABS braking pressure and decreased in response to a driver brake pedal release, and a second active braking mode in which applied braking pressure is based on maximum braking pressure. In response to a detected collision, the system is controlled according to the first active braking mode. In response to the first active braking mode being active and no driver braking request being anticipated, the system is controlled according to the second active braking mode. In response to the first or second active braking modes being active and a termination criterion being satisfied, the system is controlled according to the nominal mode.

Abstract: A method of controlling a vehicle includes providing a vehicle having a brake system configured to operate according to a nominal mode in which applied braking pressure is based on a driver braking request, a first active braking mode in which applied braking pressure is based on maximum ABS braking pressure and decreased in response to a driver brake pedal release, and a second active braking mode in which applied braking pressure is based on maximum braking pressure. In response to a detected collision, the system is controlled according to the first active braking mode. In response to the first active braking mode being active and no driver braking request being anticipated, the system is controlled according to the second active braking mode. In response to the first or second active braking modes being active and a termination criterion being satisfied, the system is controlled according to the nominal mode.

Abstract: A method for controlling a vehicle braking system includes commanding vehicle brakes to provide braking torque based on a driver braking request in response to a detected collision and an anticipated application of a driver-actuated brake pedal after the collision. The method additionally includes activating the vehicle brakes in the absence of application of the brake pedal in response to a subsequent application and release of the brake pedal while a motion sensor reading exceeds a predefined threshold.

Abstract: A vehicle comprises an acceleration sensing module and a crash direction-computing module. The acceleration-sensing module is configured for generating acceleration information resulting from a vehicle collision event. The acceleration information includes a first direction acceleration value and a second direction acceleration value. The crash direction-computing module is coupled to the acceleration-sensing module for receiving the acceleration information therefrom and is configured for determining impact direction information resulting from the vehicle collision event.

Abstract: A vehicle comprises an acceleration sensing module and a crash direction-computing module. The acceleration-sensing module is configured for generating acceleration information resulting from a vehicle collision event. The acceleration information includes a first direction acceleration value and a second direction acceleration value. The crash direction-computing module is coupled to the acceleration-sensing module for receiving the acceleration information therefrom and is configured for determining impact direction information resulting from the vehicle collision event.

Abstract: A method for controlling a vehicle braking system includes commanding vehicle brakes to provide braking torque based on a driver braking request in response to a detected collision and an anticipated application of a driver-actuated brake pedal after the collision. The method additionally includes activating the vehicle brakes in the absence of application of the brake pedal in response to a subsequent application and release of the brake pedal while a motion sensor reading exceeds a predefined threshold.

Abstract: A method of controlling a vehicle braking system, includes: (i) detecting whether a collision has occurred; (ii) detecting whether a predetermined condition follows the collision; (iii) determining whether a driver has applied the brakes; and (iv) when a driver has not applied the brakes, autonomously initiating braking.

Abstract: A vehicle comprises an acceleration sensing module and a crash direction-computing module. The acceleration-sensing module is configured for generating acceleration information resulting from a vehicle collision event. The acceleration information includes a first direction acceleration value and a second direction acceleration value. The crash direction-computing module is coupled to the acceleration-sensing module for receiving the acceleration information therefrom and is configured for determining impact direction information resulting from the vehicle collision event.

Abstract: A method of controlling a vehicle braking system, includes: (i) detecting whether a collision has occurred; (ii) detecting whether a predetermined condition follows the collision; (iii) determining whether a driver has applied the brakes; and (iv) when a driver has not applied the brakes, autonomously initiating braking.