Abstract: A system includes a processor configured to wirelessly connect to a wearable device. The processor is also configured to determine a device-wearer identity. Further, the processor is configured to receive a biometric value from the wearable device. The processor is additionally configured to compare the biometric value to thresholds associated with a user profile selected based on the device-wearer identity and, in response to the biometric value exceeding a threshold, engage in a predefined response associated with the threshold.

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 system includes a processor configured to load a dashboard application including control over a secondary application. The processor is also configured to determine, via the dashboard application, a condition associated with the launch of the secondary application. Further, the processor is configured to determine if the condition has occurred and, upon occurrence of the condition, instruct launch of the secondary application from the dashboard application.

Abstract: A vehicle computing system comprising at least one controller configured with a transceiver to connect with a server via a communication network connection. The controller may be configured to login to the server via a vehicle identification comprising at least one of a user-name and password for access to profile data. The controller is further configured to transmit at least one of contact identification, a message to communicate with a contact, and vehicle information. The controller is further configured to receive at least a portion of a contact and vehicle profile based on at least one of the contact and vehicle identification. The controller is further configured to transmit the at least a portion of the contact and vehicle profile to one or more systems.

Abstract: A vehicle system includes a sensor that outputs an impact signal and a processing device that is programmed to calculate an acceleration envelope from the impact signal, determine a number of times the impact signal crosses a predetermined threshold, and determine whether the impact signal represents a pedestrian impact. Whether the impact is a pedestrian impact is based at least in part on the acceleration envelope and the number of times the impact signal crosses the predetermined threshold.

Abstract: An interior arrangement for a vehicle including a front passenger seat having a head restraint, a rear seat, seat occupant sensors fitted to the seats, a head restraint position sensor, a motor for moving the head restraint between its functional position and its lowered position, and a central controller operatively associated with the sensors and the motor. The front passenger head restraint is moved up to its functional position from a stowed position each time a front seat passenger presence is detected according to one embodiment. According to another embodiment the front passenger head restraint is moved from a functional or upright position to a stowed or hidden position if the front seat is unoccupied and the rear seat is occupied.

Abstract: A vehicle includes a controller that communicates with a wearable device having a haptic mechanism. In response to an alert event detected by the vehicle, the controller outputs a signal to activate the haptic mechanism. The wearable device may detect a physiological or biometric characteristic such as pulse rate. The controller may output a signal to activate the haptic mechanism further in response to the pulse rate being less than a threshold. Also, the controller may output a signal to activate the haptic mechanism while the vehicle is operating autonomously.

Abstract: Data is collected from vehicle sensors to generate a virtual map of objects proximate to the vehicle. Based on the virtual map, an in-vehicle computer determines a traffic condition in front of and behind a host vehicle. The in-vehicle computer determines collision avoidance maneuvers. The computer instructs vehicle control units to implement the collision avoidance maneuvers. The computer may additionally or alternatively communicate the collision avoidance maneuvers to a driver via an interface. In the case of unavoidable collisions, the computer determines and initiates damage mitigation actions.

Abstract: A vehicle system includes a sensor configured to output an impact signal and a processing device programmed to calculate an acceleration envelope from the impact signal, calculate a velocity envelope from the acceleration envelope, determine a threshold value based at least in part on a vehicle speed, and compare the acceleration envelope to the threshold value. The processing device is further programmed to output a control signal to deploy a pedestrian protection countermeasure if the acceleration envelope exceeds the threshold value.

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 includes a processor configured to determine that a vehicle accident has occurred. The processor is also configured to connect to a detected wearable device. The processor is additionally configured to request measured present biometric information from the wearable device, in response to the accident determination. Also, the processor is configured to receive measured present biometric information from the wearable device and relay the biometric information to a connected emergency operator.

Abstract: A vehicle system includes at least two sensors. A first sensor is configured to output a child restraint signal indicating a presence of a child restraint system. A second sensor is configured to output a belt tension signal representing a tension associated with a seat belt. A processing device is programmed to determine whether the child restraint system includes a child seat or a booster seat based on the child restraint signal and the belt tension signal.

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 sensing device for actuating an airbag system in a motor vehicle comprises an airbag having a stowed condition and an inflated condition, an inflator operationally coupled with the airbag responsive to electrical actuation for inflating the airbag with a gas, an impact detection sensor for generating a signal upon an offset impact event, and a controller for processing the signal generated by the sensor and electrically actuating the inflator upon computing a predetermined impact severity to a forward corner of the motor vehicle. The motor vehicle further comprises a front bumper beam attached proximate a distal end of a front rail and the sensor comprises a flexible electro-resistive sensor mounted to a rear side of an outboard portion of the front bumper beam.

Abstract: A vehicle system includes a communication interface and a processing device. The communication interface is programmed to pair with at least one mobile device. The processing device is programmed to receive a data file, which includes occupant information, sent from the mobile device. The processing device is further programmed to update at least one vehicle setting based on the occupant information.

Abstract: A vehicle computing system may execute a recommendation application to identify driver characteristics descriptive of the driving style of a driver of the vehicle based at least in part on captured vehicle data, determine an application recommendation for a mobile application to be installed by the driver based on the driver characteristics, and to send the application recommendation to the driver.

Abstract: A vehicle system includes an autonomous mode controller and an entertainment system controller. The autonomous mode controller controls a vehicle in an autonomous mode. The entertainment system controller presents media content on a first display while the vehicle is operating in the autonomous mode and on a second display when the vehicle is operating in a non-autonomous mode. A method includes determining whether a vehicle is operating in an autonomous mode, presenting media content on a first display while the vehicle is operating in the autonomous mode, and transferring presentation of the media content to a second display when the vehicle is operating in a non-autonomous mode.

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 method and apparatus for controlling deployment of pedestrian head protection devices on a motor vehicle having a metal bumper is disclosed. The disclosed inventive concept involves strategic placement of accelerometer sensing devices and the derivation of a real time impact signal from the signals generated by the accelerometers. This real time impact signal is used along with thresholds and a time window to control deployment. The apparatus includes a metal bumper, two support brackets attaching the bumper to the vehicle and at least two accelerometers fitted to the bumper proximate the brackets. The derivation and use of a single impact signal from said first and second signal-generating accelerometers is achieved by taking the larger of two absolute values derived from the accelerometers.

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.