Abstract: A method and apparatus for controlling a deployable pedestrian protection leg stiffener of a motor vehicle based upon the vehicle braking status and longitudinal acceleration.

Abstract: A lighted vehicle bin assembly that activates a light source based on motion and recalibrates a sensor is provided. The lighted vehicle bin assembly includes a vehicle storage bin, a light source arranged to illuminate the bin, and a proximity sensor for sensing an object in the bin based on a sensor signal relative to a threshold. The lighted vehicle bin assembly also includes a controller that activates the light source when the sensor signal exceeds a threshold and recalibrates the sensor when the sensor signal exceeds the threshold for a time period.

Abstract: A system and method for controlling the performance of complex operations on a dashboard-mounted touchscreen in a vehicle moving above a predetermined minimal speed. The system includes a sensor for determining that the touchscreen is intended or going to be touched by driver and/or front seat passenger. A control, responsive to operation of the sensor, disallows or allows the touchscreen to be responsive to a touching. The touchscreen is not allowed to perform a complex operation when the vehicle is moving above the minimal speed if the touchscreen is touched by the driver. The touchscreen is allowed to perform a complex operation when the vehicle is moving above the minimal speed if the touchscreen is not going to be touched by the driver and is touched by the passenger.

Abstract: A vehicle includes at least one autonomous driving sensor and an autonomous mode controller configured to receive signals generated by the autonomous driving sensor. The autonomous mode controller controls at least one vehicle subsystem based at least in part on the signals received. Furthermore, the autonomous mode controller is configured to shade at least one vehicle window when the vehicle is operating in an autonomous mode.

Abstract: A vehicle includes a passenger compartment and at least one seat located in the passenger compartment. The seat can be moved from a front-facing position to a rear-facing position for when the vehicle is operating in an autonomous mode. The vehicle may further include autonomous driving sensors and an autonomous controller that receives signals generated by the autonomous driving sensors and controls at least one vehicle subsystems according to the signals received.

Abstract: A flexible optical impact detection sensor is mounted on an outboard portion of the front bumper for signaling an offset rigid barrier impact event to a forward corner of a motor vehicle and deployment of a small offset rigid barrier airbag mounted on the front rail. The airbag is attached proximate a distal end of a front rail. The flexible optical impact detection sensor, attached to a rear surface of an outboard portion of the front bumper, generates a signal upon a corner impact event, whereby a controller processes the signal generated by the impact detection sensor and electrically actuates an inflator upon a predetermined impact severity. The airbag in the inflated condition acts against the offset rigid barrier to generate a lateral force against the offset rigid barrier to push the motor vehicle away from the barrier and thereby redirect impact energy by lateral movement of the motor vehicle.

Abstract: An apparatus for positioning a vehicle restraint is provided herein having a track and a restraint support configured to slide along the track. A positioner is coupled to the restraint support and a motor, coupled to the positioner, is operable to adjust a position of the restraint support. A switch is in communication with the motor and the motor is operable to adjust the position of the restraint support in response an input to the switch. An apparatus for identifying the occupant and automatically positioning of a vehicle restraint is also provided.

Abstract: A method and apparatus for controlling a deployable pedestrian protection leg stiffener of a motor vehicle based upon the vehicle steering angle and/or braking status and/or speed.

Abstract: A method and apparatus for controlling a deployable pedestrian protection leg stiffener of a motor vehicle based upon the vehicle steering angle and/or braking status and/or speed.

Abstract: A vehicle includes a passenger compartment and at least one seat located in the passenger compartment. The seat can be moved from a front-facing position to a rear-facing position for when the vehicle is operating in an autonomous mode. The vehicle may further include autonomous driving sensors and an autonomous controller that receives signals generated by the autonomous driving sensors and controls at least one vehicle subsystems according to the signals received.

Abstract: A vehicle includes a steering wheel located in a passenger compartment. The steering wheel is configured to be moved from an operational position to a stowed position. In the event of a collision, a first airbag is configured to deploy when the steering wheel is in the operational position and a second airbag is configured to deploy when the steering wheel is in the stowed position.

Abstract: A vehicle includes a passenger compartment with an instrument panel located near a front of the passenger compartment. The vehicle further includes at least one seat located in the passenger compartment. The seat can be stowed under the instrument panel for when the vehicle is operating in an autonomous mode.

Abstract: A flexible optical impact detection sensor is mounted on an outboard portion of the front bumper for signaling an offset rigid barrier impact event to a forward corner of a motor vehicle and deployment of a small offset rigid barrier airbag mounted on the front rail. The airbag is attached proximate a distal end of a front rail. The flexible optical impact detection sensor, attached to a rear surface of an outboard portion of the front bumper, generates a signal upon a corner impact event, whereby a controller processes the signal generated by the impact detection sensor and electrically actuates an inflator upon a predetermined impact severity. The airbag in the inflated condition acts against the offset rigid barrier to generate a lateral force against the offset rigid barrier to push the motor vehicle away from the barrier and thereby redirect impact energy by lateral movement of the motor vehicle.

Abstract: A vehicle includes a steering wheel located in a passenger compartment. The steering wheel is configured to be moved from an operational position to a stowed position. In the event of a collision, a first airbag is configured to deploy when the steering wheel is in the operational position and a second airbag is configured to deploy when the steering wheel is in the stowed position.

Abstract: A flexible electro-resistive impact detection sensor is mounted on an outboard portion of the front bumper for signaling an offset rigid barrier impact event to a forward corner of a motor vehicle and deployment of a small offset rigid barrier airbag mounted on the front rail. The airbag, is attached proximate a distal end of a front rail. The flexible electro-resistive impact detection sensor, attached to a rear surface of an outboard portion of the front bumper, generates a signal upon a corner impact event, whereby a controller processes the signal generated by the impact detection sensor and electrically actuates an inflator upon a predetermined impact severity. The airbag in the inflated condition acts against the offset rigid barrier to generate a lateral force against the offset rigid barrier to push the motor vehicle away from the barrier and thereby redirect impact energy by lateral movement of the motor vehicle.

Abstract: A vehicle includes a passenger compartment and at least one seat located in the passenger compartment. The seat can be moved from a front-facing position to a rear-facing position for when the vehicle is operating in an autonomous mode. The vehicle may further include autonomous driving sensors and an autonomous controller that receives signals generated by the autonomous driving sensors and controls at least one vehicle subsystems according to the signals received.

Abstract: A vehicle includes a passenger compartment and a bench seat located in the passenger compartment. The bench seat has a bottom portion and a back portion and is configured to move from a front-facing position to a rear-facing position by moving the back portion toward a front of the passenger compartment for when the vehicle is operating in an autonomous mode.

Abstract: An imaging and reporting system includes a wireless communication device having a user-installed program for forwarding a received image to a remote monitor and a vehicle-based network that includes an impact event sensing system, an imaging module including a camera for capturing an image of the vehicle's interior, and a transceiver for sending the captured image to the communication device. Operating software controls the imaging and reporting system. Thereafter the wireless communication device automatically forwards an image to the remote monitor that may be part of a community's 911 system. The operator reviews the one or more images received by the remote monitor and takes necessary action in response. The imaging and forwarding steps are accomplished without the need for human intervention. The software associated with the imaging and reporting system and the software associated with the wireless communication device disallows the retention of any captured image.

Abstract: A system includes a processor configured to request vehicle sensor data upon crash detection. Further, the processor is configured to assemble the data into a graphic representation of a vehicle, including graphic representations of conditions represented by sensor data. The processor is also configured to send the graphic representation to an emergency operator in communication with a vehicle computing system.

Abstract: A vehicle system includes an autonomous mode controller that controls a vehicle in an autonomous mode and an entertainment system controller that presents media content while the vehicle is operating in the autonomous mode. The entertainment system actuates a projection screen inside a passenger compartment of the vehicle and enables a projector to project media content onto the projection screen. A method includes determining whether a vehicle is operating in an autonomous mode, and if so, actuating a projection screen inside a passenger compartment of the vehicle and enabling a projector to project media content onto the projection screen.