A seating detection method includes: detecting whether a seat belt sensor in a vehicle seat is in an ON state or an OFF state; detecting whether a pressure sensitive sensor in a seat skin constituting a seating surface is in an ON state or an OFF state; and determining a foreign object insertion state in which a foreign object is inserted between the seating surface and a child seat based on whether the seat belt sensor is in the ON state or the OFF state and whether the pressure sensitive sensor is in the ON state or the OFF state. When the pressure sensitive sensor is changed from the ON state to the OFF state in a state in which the seat belt sensor is maintained in the ON state after the seat belt sensor is changed to the ON state, it is determined as the foreign object insertion state.

A sensor disposition structure in a seat includes a cushion pad and a board-like member which is disposed under the cushion pad. A concave is formed in an upper surface of the board-like member, and a sensor is disposed in the concave.

A method for actively adjusting an adjustable component in a vehicle seat includes the steps of: (1) providing a seat assembly having a seat portion with first and second side bolsters disposed on opposite sides of the seat portion, first and second adjustable components and first and second sensors disposed in the first and second side bolsters, and a controller operably coupled to both the first and second adjustable components and the first and second sensors; (2) detecting a pressure value using one of the first and second sensors; (3) determining if the pressure value exceeds a threshold value; and moving an articulating support plate of the adjustable component associated with the sensor detecting the pressure value towards an extended position from a retracted position to a degree commensurate with pressure value detected.

A method for adjusting an adjustable component in a seat assembly includes the steps of: (1) providing a seat assembly having an adjustable support plate and a sensor; (2) supporting a seat occupant on the seat assembly; (3) moving the support plate into contact with the seat occupant; (4) sensing a pressure value applied to the support plate using the sensor as the support plate contacts the seat occupant; and (5) retaining the support plate in a deployed position. The movement of the support plate is configured to cease when the pressure value is initially detected or when the pressure value exceeds a predetermined threshold.

A vehicle includes a compressor; a first accumulator fluidly connected with the compressor; a second accumulator fluidly connected with the compressor; a first nozzle directed at a first sensor and fluidly connected with the first accumulator; a second nozzle directed at a second sensor and fluidly connected with the second accumulator; an occupancy sensor; and a computer in communication with the compressor, the accumulators, and the occupancy sensor. The computer is programmed to, upon determining that the vehicle is unoccupied based on data received from the occupancy sensor, instruct the compressor to pressurize the accumulators of the vehicle.

An integrated safety seat permanently built into a vehicle. The safety seat may be united with other seats or separated from other seats, or other integrated safety seats. The integrated safety seat is configured to accommodate an occupant from newborn to adulthood in a seat bottom, as well as in a back, whereby the seat bottom, back and a cradle in between may incline upward and downward by an internal mechanism, to a plurality of angles, ranging from rear facing to forward facing. The integrated safety seat includes a headrest and footrests support in the forward facing position, which serve as a footrest and headrest support, respectively in the rear facing position. The integrated safety seat includes harnesses and lap-belts with hasps, armrests, and headrests, footrests, inserts, within that elevate. The safety seat further includes integrated safety controls that operate regardless of whether the vehicle is in operation.

An operating device for an actuator-adjustable motor vehicle seat includes a control element and multiple force sensors. The control element has a contour which simulates the outline shape of the motor vehicle seat. Pressing actuations directed to various locations on the contour of the control element trigger different adjustment movements of the vehicle seat. The pressing actuations are detected by the force sensors which can measure horizontal and vertical forces. The actuation position and the actuation direction of a finger on the control element may be detected from the reaction forces of the force sensors. The force sensors are designed as three force sensors that measure in one dimension; two of the force sensors are situated in parallel to one another; and a third force sensor is situated perpendicularly with respect to the other two force sensors.

A control system for an inflatable support mechanism having a fluid inlet includes at least one inflate valve including an inlet, and a purge valve including an inlet portion and an outlet portion. The inlet portion is fluidically connected to the inlet. No more than one absolute pressure sensor is fluidically connected between the fluid inlet and the inlet of the at least one inflate valve and the inlet portion of the purge valve the no more than one absolute pressure sensor selectively sensing pressure within the inflatable support mechanism and atmospheric pressure.

A method of producing a functional vehicle component includes fixing a leather sheet over a surface of a vehicle component, applying a flexible electronic circuit to an A-surface of the leather sheet, and arranging a pigmented coating over the circuit. The pigmented coating inhibits or prevents the circuit from being visible through the pigmented coating. The method may include attaching an electronic element, such as a light source, a sensor, a wireless transmitter, or a switch, to the circuit. When the circuit includes a light source, the pigmented coating inhibits or prevents the light source from being visible through the pigmented coating, but light emitted by the light source is visible through the pigmented coating.

System, methods, and other embodiments described herein relate to adaptively communicating notices to passengers within a vehicle. In one embodiment, a method includes in response to receiving a notice about an occurrence of an event, determining a viewing orientation of a passenger in the vehicle according to at least one electronic input that indicates information about a physical position of the passenger within the vehicle. The event is an incident associated with the vehicle for which the passenger is to be informed. The method also includes selecting at least one alerting device from available communication devices in the vehicle according to the viewing orientation by determining which of the available communication devices correspond with the viewing orientation of the passenger. The method further includes controlling the at least one alerting device to communicate the notice to the passenger about the occurrence of the event.