Abstract: A vehicle has an inflatable occupant restraint system that includes an inflatable occupant protection device and an inflator operable to inflate the inflatable occupant protection device when a predetermined event occurs. The vehicle also includes a child restraint system having a portable child seat with an inflatable child protection apparatus attached thereto. The child restraint system includes a connection interface connected to the child seat and adapted for connection to the occupant restraint system such that the child protection apparatus is inflated when the predetermined event occurs.

Abstract: A method for remotely controlling one or more vehicle components includes receiving over a telecommunications network signals originating from a remote terminal. The signals include remote operation instructions for remotely operating a vehicle entertainment system component. The remote operation instructions are executed. Operation status identifiers transmitted over a vehicle data bus are received from the vehicle entertainment system component. Based on the operation status identifiers, an operating status of the vehicle entertainment system component is determined. A return signal including an operation status message and an instruction for displaying the operation status message at the remote terminal is generated. The signal is transmitted to the remote terminal for display.

Abstract: A method for querying a vehicle system from a remote wireless device includes receiving an inquiry at a cellular transceiver included in a vehicle. The inquiry is sent from a remote server in communication with the remote wireless device and initiated by the remote wireless device. The method includes accessing one or more vehicle systems in accordance with the inquiry and querying the accessed one or more systems in accordance with the inquiry. The method also includes receiving information in accordance with the query from the one or more systems that were queried and transmitting the received information to the remote server through the cellular transceiver, for further transmission to the remote wireless device.

Abstract: Various embodiments may include methods and systems for determining a tire pressure status. The system may include at least one computer. An input defining an inflation status of one or more vehicle tires, as well as tire inflation data of the one or more tires, may be received. A specific value associated with an inflation event of the one or more vehicle tires may be calculated based on the inflation data. Further, one or more messages for outputting the specific value from one or more vehicle components may be generated and transmitted to the one or more vehicle components. The specific value may be output as one or more messages from the vehicle.

Abstract: A method of vehicle monitoring includes monitoring one or more vehicle safety systems while a vehicle is in operation to detect an unsafe condition. The method also includes sending an alert to a handheld device if an unsafe condition is detected.

Abstract: A computer-implemented method for detecting a working condition of one or more vehicle components includes communicating with a cellular communication module in a vehicle over a telecommunications network. A vehicle component characteristic or identifier for the vehicle components is received over the telecommunication network. One or more operation status identifiers for the one or more vehicle components based on data from the vehicle is also received. A location for servicing or purchasing the one or more vehicle components based on the vehicle component characteristic or identifier is determined. A service status of the one or more vehicle components based on the one or more operation status identifiers is also determined. Based on the service status, a message including an identification of the vehicle components and a service or purchase location for the vehicle components is generated. The message is transmitted to a terminal for display.

Abstract: A method for remotely controlling one or more vehicle components includes receiving over a telecommunications network signals originating from a remote terminal. The signals include remote operation instructions for remotely operating a vehicle entertainment system component. The remote operation instructions are executed. Operation status identifiers transmitted over a vehicle data bus are received from the vehicle entertainment system component. Based on the operation status identifiers, an operating status of the vehicle entertainment system component is determined. A return signal including an operation status message and an instruction for displaying the operation status message at the remote terminal is generated. The signal is transmitted to the remote terminal for display.

Abstract: In at least one embodiment, an apparatus for performing an alcohol monitor in a vehicle based on a driver being one of a primary driver and a secondary driver is provided. The apparatus comprises an electronic device that is positioned within the vehicle. The electronic device is configured to receive a driver status signal indicating that the driver of the vehicle is the secondary driver. The electronic device is further configured to receive an alcohol content measurement from an alcohol monitoring device (AMD) indicative of blood alcohol content for the secondary driver. The electronic device is further configured to compare the alcohol content measurement to a predetermined alcohol content.

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 system and method for transmitting a location signal indicative of the location of the vehicle to a first wireless device is provided. The system comprises a navigation module and a controller. The navigation module is positioned within the vehicle and is configured to transmit a location signal indicative of the physical location of the vehicle. The controller is configured to transmit the location signal as a radio frequency (RF) based signal to the at least one wireless device in response to detecting the occurrence of at least one predetermined vehicle event.

Abstract: A vehicle system for controlling at least one radio frequency (RF) receiver/control unit is provided. The system comprises a global positioning system (GPS) receiver, a vehicle controller, and a vehicle interface display. The GPS receiver is configured to generate a geographic location signal indicative of the first location of the RF receiver/control unit. The vehicle controller is configured to associate the geographic location signal to an RF control signal. The vehicle interface display is configured to present at least one menu option for occupant selection to control the operation of the RF receiver/control unit such that the vehicle interface display controls the vehicle controller to transmit the RF control signal to control the RF receiver/control unit to perform the predetermined operation in response to the occupant selecting the at least one menu option.

Abstract: A system, apparatus and method to automatically move a side mounted mirror on a vehicle from an inward position to an outward position in response to a signal from a detector indicative of an object outside an operator normal field of vision. The detector may be a blind spot detection system or a lane departure system, or any other system to detect vehicles in a blind spot. The system, apparatus and method further includes permitting an operator to manually actuate the movement of mirror on a vehicle to determine whether there are any objects in the operator's normal field of vision. The systems and method may optionally include hysteresis during mirror movement.

Abstract: A fuel usage of a comparator vehicle is calculated and compared to a fuel usage of a vehicle being driven. The fuel usage of the comparator vehicle is determined based on parameters of the vehicle being driven.

Abstract: A method for updating a map in a vehicle having an internal combustion engine and an auxiliary power source is provided. The method includes changing an input parameter; monitoring an actual output value corresponding to the changed input parameter; mapping the monitored actual output value to the changed input parameter; and compensating engine output with the auxiliary power source to account for changes to engine output resulting from changing the input parameter.

Abstract: A device (20) for an automotive vehicle (10) is provided to indicate the buckled and unbuckled status of a seatbelt (24). The device (20) has a self-powered wireless switch assembly (22) that is coupled to the seatbelt (24). It provides power to power a wireless transmitter (44) to transmit a wireless signal (45) corresponding to the buckled and unbuckled state of the seatbelt (24). The self-powered wireless switch assembly (22) harvests energy from the mechanical action of the seatbelt (24). The device (20) transmits a wireless signal (45) indicating the seatbelt (24) status. The receiver (18) located in the automotive vehicle (10) receives the wireless signal (45). The wireless signal (45) is processed by a safety information system (12) and then visually and audibly displayed by an indicator (16) to alert the driver of the seatbelt (24) status.

Abstract: A restraints control module (RCM) for a vehicle is provided including a memory device. The memory device stores a deployment time of a deployment event. A controller is electrically coupled to the memory device and deploys a restraint in response to a collision signal and stores the deployment time in the memory device. A method of time stamping and indicating a deployment event within an automotive vehicle, having a RCM, is also provided.

Abstract: An impact sensor is provided including a counter electrically coupled to the sensor and storing an impact sensor collision number. The impact collision number represents whether the impact sensor has been on a vehicle that has been involved in a collision. A method for indicating that the impact sensor has been on a vehicle that has been involved in a collision is also provided. The method includes sensing a collision and generating a collision signal in response to the collision. An impact sensor collision number is incremented and indicated in response to the collision signal.

Abstract: A method of deploying a passenger side airbag as a function of the actual mass of the occupant on the passenger seat. This is accomplished by providing force sensors at one or more of the anchor pieces at which a seat belt is connected to the vehicle. The sensors may be strain gauges that measure the deflection of bolts connecting the ends of the seat belt to the anchor pieces. By sizing the nominal resistance of strain gauges at two anchor pieces, the two resistors can be put in a series circuit such that only the sum of the two resistances need be measured. The measurements obtained are then used to obtain the vertical components of force due to the seat belt. This value is then be subtracted from the total vertical force measured by a seat cushion weight sensor to determine the mass of the seat occupant.

Abstract: A communication system is provided for an automotive vehicle (10) that uses existing vehicle components with only slight modifications that can be implemented in readily changeable software. The system includes a vehicle bus (14) and a vehicle information source coupled to the vehicle bus. The vehicle information source (28) couples vehicle information to the vehicle bus (14). The transmitter (16) transmits a first communication having a first transmitter identification code and first vehicle information. A receiver (22) is coupled to the vehicle bus. The receiver (22) couples a second communication word having second vehicle information to the vehicle bus. The automotive vehicle (10) also has a safety system and a safety system controller (34) coupled to the bus. The safety system controller (34) actuates the safety system (36) in response to the second vehicle information.

Abstract: A restraint and fuel pump cutoff control system is disclosed wherein a restraint control module controls the restraint system such as an air bag deployment system and a fuel system power supply based upon data inputs from sensors positioned at various locations on the vehicle. When data received from the sensors indicates that a collision event has occurred and has reached the predetermined level of severity, power to the fuel system is cut off to prevent undesired pumping of fuel. If power is interrupted during a collision event, the fuel system will be cut off and remain cut off until reset by turning the ignition switch to off and then to run/start indicating a clean shutdown. The restraint control module utilizes collision data profiles to distinguish between power shutdowns occurring during a collision event and power shutdowns occurring when only background data is being received from the sensors.