Abstract: A method for alerting a driver of an automotive vehicle (or other responsible party) to the presence or inferred presence of an object, a person, or a pet animal in rear seating rows of the vehicle. The open/closed condition of rear vehicle doors is monitored to determine whether the driver may have placed an object, child, or pet in the rear seating rows prior to the start of a drive-cycle, and an alert is generated at the end of the drive-cycle to remind the driver to check the rear seat. Sound detection and analysis may also be used to identify sounds characteristic of a human (a young child, for example) or a non-human animal (a pet, for example) and thereby verify that a child or pet is present.

Abstract: A control system (11) for a vehicle (10) includes vehicle dynamics sensors (35-47) providing a vehicle dynamics signal. Tire monitoring system sensors (20) in each wheel generate tire signals including temperature, pressure and acceleration data. A controller (26) communicates with the tire monitoring system sensors (20) and at least one vehicle dynamics sensor, and generates a suspension value as a function of the multi-axis acceleration data of the tire signals. The suspension value is transmitted to a suspension control system (33) to adjust the vehicle suspension characteristics in response to the suspension value.

Abstract: A control system (11) for a vehicle (10) includes vehicle dynamics sensors (35-47) providing a vehicle dynamics signal. Tire monitoring system sensors (20) in each wheel generate tire signals including temperature, pressure and acceleration data. A controller (26) communicates with the tire monitoring system sensors (20) and at least one vehicle dynamics sensor, and generates a brake signal as a function of the multi-axis acceleration data of the tire signals. The brake signal is transmitted to a brake system (64) to apply a brake torque in response to the brake signal.

Abstract: A system and method are disclosed for detecting an occupant in a vehicle. Successive images from an infrared camera are analyzed to detect thermal characteristics of an occupant as well as movement. If an operator of the vehicle has exited the vehicle, the vehicle is deactivated, an occupant is detected, and a temperature in the cabin of the vehicle is higher or lower than desired, a report is made to the operator via a mobile phone or key fob.

Abstract: A control system (11) for a vehicle (10) includes vehicle dynamics sensors (35-47) providing a vehicle dynamics signal. Tire monitoring system sensors (20) in each wheel generate tire signals including temperature, pressure and acceleration data. A controller (26) communicates with the tire monitoring system sensors (20) and at least one vehicle dynamics sensor, and generates a roadway surface condition estimation value as a function of the multi-axis acceleration data of the tire signals. The roadway surface condition estimation value is transmitted to a suspension control system (33) to adjust the vehicle suspension characteristics in response to the roadway surface condition estimation value.

Abstract: The invention is a control system for adjusting at least one vehicle system in a plurality of vehicle systems comprising at least one polymer-based biometric sensor positioned proximate a driver for monitoring at least one vital sign of a driver of the vehicle and configured to produce data in response to changes in the at least one vital sign. The system also comprises at least one camera system positioned to view the driver. A first processing system is configured to receive sensor data and input collected by the camera system to determine a biometric state of the driver. The biometric state of the vehicle driver is then used to determine an adjustment setting for the at least one vehicle system thereby controlling the vehicle system in response to the adjustment setting in accordance with the determined biometric state of the vehicle driver.

Abstract: A system for detecting a passenger in a rear seating row of a vehicle and alerting an occupant of a vehicle when a passenger safety device in a rear row is not properly used. Occupancy is determined by sensing any actuation of a switch or control in the rear row along with detecting sounds made by the rear row passenger. A processor receives control activity signals indicating that a control has been actuated, receives audio signals generated by a microphone, and uses the control activity signals and the audio signals in combination to determine that the passenger is present. The processor also receives a status signal from the passenger safety device indicating that it is not in proper use. An occupant alerting device provides an alert to the occupant if the processor determines that the passenger is present and the passenger safety device is not in proper use.

Abstract: A system for alerting a responsible party to the presence of an occupant in a passenger compartment of a vehicle includes a vibration sensor detecting movement of an occupant, a microphone detecting sound made by the occupant, a processor configured to receive signals output from the vibration sensor and the microphone and to use a combination of the signals to determine whether the occupant is present, and an alerting device to provide an alert to the responsible party if the processor determines that the occupant is present. The microphone may also be used in a communication or voice-recognition command system. Two or more microphones may be used to locate the sound's source of origin.

Abstract: An air bag deployment system includes a pre-impact sensor operative to detect an imminent impact and at least one post-impact sensor operative to detect an impact. An air bag has a non-deployed volume, a pre-impact deployed volume, and a post-impact deployed volume smaller than the pre-impact deployed volume. The air bag is deployed to the pre-impact volume wherein the air bag deployment system is arranged to deploy the air bag before the impact and the at least one air bag is deployed into the pre-impact deployed volume, in reaction to the imminent impact, and to the post-impact deployed volume in reaction to the impact. The system provides for enhanced occupant safety during a collision by allowing pre-impact deployment of the air bag in order to utilize the full possible length of deceleration for the occupant as the impact pulse affects the occupant.

Abstract: A control system (11) for a vehicle (10) includes vehicle dynamics sensors (35-47) providing a vehicle dynamics signal. Tire monitoring system sensors (20) in each wheel generate tire signals including temperature, pressure and acceleration data. A controller (26) communicates with the tire monitoring system sensors (20) and at least one vehicle dynamics sensor, and generates a tire abnormality value as a function of the multi-axis acceleration data of the tire signals. Tire multi-axis acceleration data is also used to detect a roadway departure, and an oversteer or understeer event.

Abstract: A dual-mode rear vision system for an automotive vehicle includes an electro-optical imaging device operable in a short range mode to image a backup region immediately rearward of the vehicle and operable in a long range mode to image a collision threat region rearward of the backup region. The imaging device assumes the short range mode when the vehicle is in a reverse travel mode and assumes the long range mode when the vehicle is in a non-reverse travel mode. An electronic control module (ECM) analyzes imagery from the imaging device to detect backup hazards when in the reverse travel mode, and to detect rear collision threats when in the non-reverse travel mode. The ECM activates an occupant protection system if a collision threat is detected, and generates a driver alert and/or a braking intervention if a backup hazard is detected.

Abstract: An electrically activated, electronically controlled web grabber in conjunction with a pre-impact braking system that holds the vehicle safety belt from the moment of activation, restricting forward movement of the occupant and can be activated prior to the impact to ensure occupant containment and deactivated upon command in order to release after an accident is avoided, or once the impact has started to allow other safety devices to take over control of the belts, for example, by load limiters.

Abstract: A method and system to control a side mirror are disclosed in which a blind spot detector is used to determine whether an alien vehicle is present in a blind spot of a host vehicle. A sensor proximate a driver's seat detects whether the seat is in a first range or a second range. The side mirror is rotated a first predetermined angle when the alien vehicle is detected and the seat is in the first range; and the side mirror is rotated a second predetermined angle when the alien vehicle is detected and the seat is in a second range.

Abstract: A control system (10) for a vehicle (16) includes a sensor (35-47) that generates a sensor signal and a stability control system (26). Tire monitoring sensors (20) in each wheel generate tire signals including temperature, pressure and acceleration. The controller (26) is coupled to the sensors (20, 25-47), and generates a first roll condition signal as a function of the sensor signal, and generates a second roll condition signal as a function of the tire signals. The first or second roll condition signals control the rollover control system to mitigate a vehicle rollover event.

Abstract: A dual-mode imaging system for a vehicle includes an electro-optical camera mounted inside the passenger cabin and a drive unit for rotating the camera between a rear view position wherein the camera images an area rearward of the vehicle and a seating view position wherein the camera images a seating area within the cabin. When the vehicle is in a non-reverse travel mode, an electronic control module (ECM) directs the camera to the seating view position and analyzes imagery to determine an occupancy status for at least one seating position. A safety system undergoes a function change based on the occupancy status. When the powertrain is in a reverse travel mode, the ECM directs the camera to the rear view position and imagery from the camera is presented on a display screen displays for viewing by the vehicle operator while backing up.

Abstract: An air bag deployment system includes a pre-impact sensor operative to detect an imminent impact and at least one post-impact sensor operative to detect an impact. An air bag has a non-deployed volume, a pre-impact deployed volume, and a post-impact deployed volume smaller than the pre-impact deployed volume. The air bag is deployed to the pre-impact volume wherein the air bag deployment system is arranged to deploy the air bag before the impact and the at least one air bag is deployed into the pre-impact deployed volume, in reaction to the imminent impact, and to the post-impact deployed volume in reaction to the impact. The system provides for enhanced occupant safety during a collision by allowing pre-impact deployment of the air bag in order to utilize the full possible length of deceleration for the occupant as the impact pulse affects the occupant.

Abstract: A seat belt retractor system for a vehicle having a vehicle safety system. The seat belt is retracted at a faster rate when a threat is detected using a high-voltage generated by a local power source.

Abstract: A system for monitoring the deployment of an airbag. The system includes a sensor adapted to generate a signal and a flexible member having an indicator portion. The indicator portion inhibits at least a portion of the signal from transmitting through the flexible member.

Abstract: A vehicle is equipped with blind spot detection and rear crossing path collision warning system. Programmable maximum range limit radar sensors mounted on the vehicle are used to provide blind spot object detection warning when the vehicle is traveling in a forward direction and rear crossing path collision warning when the vehicle is traveling in a rearward direction.

Abstract: A control system (11) for a vehicle (10) includes vehicle dynamics sensors (35-47) providing a vehicle dynamics signal. Tire monitoring system sensors (20) in each wheel generate tire signals including temperature, pressure and acceleration data. A controller (26) communicates with the tire monitoring system sensors (20) and at least one vehicle dynamics sensor, and generates a tire abnormality value as a function of the multi-axis acceleration data of the tire signals. Tire multi-axis acceleration data is also used to detect a roadway departure, and an oversteer or understeer event.