Abstract: A vehicle control system (10) including a vehicle motion control subsystem (12) that has an input receiving an intended driving demand (14) and a plurality of coordinator subsystems (16) for coordinating actuators of the vehicle. The vehicle motion control subsystem (12) communicates with the coordinator subsystems (16) to determine whether a single coordinator subsystem (16) can carry out the intended driving demand (14). The vehicle motion control subsystem (12) will distribute demand signals among one or more of the coordinator subsystems (16) to allow the vehicle to implement the intended driving demand (14).

Abstract: An automotive vehicle includes a vehicle body and at least one reservoir containing a fire suppressant agent. A distribution system receives the fire suppression agent from the reservoir and conducts the agent to at least one location about the vehicle's body in response to the determination by a sensor system and controller that the vehicle has been subjected to a significant impact. The sensor system and controller determine not only the magnitude of an impact upon the vehicle, but also track subsequent motion of the vehicle, as well as the time which has elapsed since an impact, so as to decide if and when the fire suppressant agent should be dispersed. Alternatively, the fire suppressant agent may be dispersed following activation of a manual switch.

Abstract: An imaging system for a vehicle is provided. The system includes an image sensor generating a plurality of image frames, and a controller coupled to the image sensor. The controller is programmed to detect an obstructed image frame from the plurality of image frames. The obstruction corresponds to a windshield wiper of the vehicle. In response to detecting an obstructed image, the controller optimizes the obstructed image for display or use by a vehicle system. The controller detects an obstructed image by at least one of object sensing confirmation, edge detection, negative shift detection or headlight illumination detection.

Abstract: An active light source operating system (10,11) for a vehicle (14) includes a light source (50) that generates an initial illumination beam (54). A selective attenuation filter (27,52) forms an emitted illumination beam (56), with an associated light attenuation matrix (32,33), in response to the initial illumination beam (54). A sensor (31) detects an object and generates an object detection signal. A controller (35) is coupled to the selective attenuation filter (27,52) and said sensor (31). The controller (35) attenuates a pixel (104) in the light attenuation matrix (32,33) in response to the object detection signal.

Abstract: The present invention is an automotive collision mitigation system comprising at least one sensor for sensing first and second detection zones. A controller, responsive to the at least one sensor, determines at least one countermeasure attribute for reducing occupant injury potential.

Abstract: A device for use together with a seat belt (3) of a seat in a vehicle (6), comprising a sensor (2) for measuring tension in the seat belt and a member (4) for limiting the load transferable by the seat belt, the seat belt tension sensor being arranged to provide information based on which an airbag intended for said seat may be disconnected. One of either the seat belt tension sensor (2) or the load limiter member (4) is connectable to a first end of the seat belt (3) and the other of the seat belt tension sensor and the load limiter member is connectable to the vehicle (6), the seat belt tension sensor and the load limiter member being connected to each other so that at least a part of the seat belt tension sensor (2) and a part of the load limiter member (4) overlap with each other.

Abstract: A vehicle control system adapted to facilitate exiting of ruts includes an active steering system having a steerable wheel defining a steering angle. The active steering system also includes a steering wheel providing a driver input control angle, the active steering system further including a coupler component, an actuator component, a controller component, and a sensor component. The components of the active steering system are operably interconnected such that the controller component can selectively vary the steering angle relative to the driver input control angle. The steering angle defines an expected vehicle yaw when the steerable wheel is not slipping on a contact surface such as a road surface. The sensor component is configured to provide the controller with a signal corresponding to an actual yaw angle of a vehicle. The vehicle control system also includes a braking system adapted to brake selected wheels of a vehicle.

Abstract: A system and method for preemptively sensing an object in the potential drive path of an automotive vehicle and selectively operating both a collision countermeasure system and a parking assistance system aboard the automotive vehicle are disclosed herein. The system includes a radar sensor, ultrasonic sensors, and a data processing system mounted aboard the automotive vehicle. The data processing system is electrically connected to the radar sensor, the ultrasonic sensors, the collision countermeasure system, and the parking assistance system. The sensors are operable to cooperatively sense the position of the object in the potential drive path of the automotive vehicle and accordingly transmit sensor data to the data processing system. The data processing system is operable to receive the sensor data, selectively process the sensor data, and accordingly transmit operating instructions to the collision countermeasure system and the parking assistance system so as to selectively operate both systems.

Abstract: A drowsy driver detection system (10) for an automobile (12) is coupled to a service center (16) through a communication system (14). A drowsy driver sensor (30) coupled to a controller (32) and a communication device (60) is used to determine the drowsiness of a vehicle operator by monitoring actions of the vehicle operator. When it is determined by the controller (32) that a vehicle operator is drowsy, controller (32) initiates communication device (60) to communicate a communication signal to service center (16). A response signal is generated by the service center (16) to the vehicle operator through communication device (60) to alert the driver and direct the driver to a rest area.

Abstract: A tool for measuring force associated with engaging an anchorage of a child restraint anchorage system of a motor vehicle. The tool includes a force measuring device, an engagement arm having a slot, and a guide mechanism. The engagement arm transmits force to the measuring device when the anchorage is seated within the slot.

Abstract: A color-corrected lighting system for night vision applications includes a near infrared light source and a thin-sheet optical element disposed a distance from the near infrared source. The optical element includes an input surface for receiving light from the near infrared source and an output surface for emitting the received light in a desired emission pattern. The system also includes a visible, non-red light source in the form of a plate having a plurality of non-red LEDs arranged thereon. The plate is proximate a surface of the optical element such that the output surface of the optical element emits the visible light to mask the emitted near infrared light. A camera is adapted to receive the near infrared light from the near infrared light source reflected off an object within a camera field of view, and a display images objects detected within the camera field of view.

Abstract: A vehicle control system (10) including a vehicle motion control subsystem (12) that has an input receiving an intended driving demand (14) and a plurality of coordinator subsystems (16) for coordinating actuators of the vehicle. The vehicle motion control subsystem (12) communicates with the coordinator subsystems (16) to determine whether a single coordinator subsystem (16) can carry out the intended driving demand (14). The vehicle motion control subsystem (12) will distribute demand signals among one or more of the coordinator subsystems (16) to allow the vehicle to implement the intended driving demand (14).

Abstract: A door assembly is provided having an ergonomic egress handle. The egress handle includes a door release lever that is pivotally connected to an automotive vehicle door about an axis that is generally perpendicular to the door for unlatching the door so that the door may be opened relative to the vehicle. A method is also provided for operation of the door assembly.

Abstract: An airbag (10) is provided that can be sequentially deployed for minimizing the risk of injury to a vehicle occupant (12). This airbag (10) is an inflatable bag having a primary chamber (34) and a secondary chamber (36) that is adjacent to the primary chamber (34). The primary chamber (34) is configured for inflating before the secondary chamber (36). In addition, this primary chamber (34) is utilized for applying a generally downward force the vehicle occupant's lap (14) and abdomen (16). In this way, a substantial portion of the initial deployment force of the airbag (10) is allocated to the occupant's more durable lower body. Also, the primary chamber (34) can be utilized for positioning the occupant's body (12) in a manner best suited for impacting the airbag (10). This airbag (10) is then sequentially deployed in a generally linear direction upward from the primary chamber (34) to the secondary chamber (36).