A computer that includes memory that stores instructions executable by a processor. The computer may be programmed to: receive image data that includes a vehicle seat and an occupant within a vehicle cabin; determine, using the received data, an orientation of the seat and an orientation of the occupant; and perform a vehicle function based on the determination.

A seating assembly for a vehicle includes a seat having an extendable leg support. A seatback is operably coupled with the seat. The seating assembly includes an occupant detection system. A rear seat lift device is disposed in the seat and operable between a lowered position and a heightened position. A rear portion of the seat is elevated relative to the seatback to minimize a height difference between the rear portion of the seat and a bottom portion of the seatback when the seatback is in a fully reclined position. A control module is in communication with the occupant detection system, the seat, and the seatback. The control module is configured to activate an actuation assembly of the seatback to rotate the seatback rearward, extend the extendable leg support forward, and raise the rear seat lift device to provide optimal rest conditions for the occupant.

A seating assembly for a vehicle includes a seat having an extendable leg support. A seatback is operably coupled with the seat. The seating assembly includes an occupant detection system. A rear seat lift device is disposed in the seat and operable between a lowered position and a heightened position. A rear portion of the seat is elevated relative to the seatback to minimize a height difference between the rear portion of the seat and a bottom portion of the seatback when the seatback is in a fully reclined position. A control module is in communication with the occupant detection system, the seat, and the seatback. The control module is configured to activate an actuation assembly of the seatback to rotate the seatback rearward, extend the extendable leg support forward, and raise the rear seat lift device to provide optimal rest conditions for the occupant.

A vehicle seat includes a seat bottom and a seat back coupled to the seat bottom to extend upwardly away from the seat bottom. The vehicle seat further includes a seat-bottom foundation arranged to interconnect the seat bottom and seat back to translate back and forth relative to a vehicle floor.

A vehicle seat is adapted to be moved relative to a floor of a vehicle. The seat includes a seat bottom that can be moved relative to the floor and a seat back that can be moved relative to the seat bottom.

A vehicle seat control system (1) includes a first backrest portion (302) rotatably connected to a seating portion (301) by a first connection unit (308), a second backrest portion (302) rotatably connected to the first backrest portion by a second connection unit (309), a folding adjustment unit (304) that adjusts an angle of the second connection unit, a seat surface adjustment unit (304) that adjusts a height of the seating portion, a first angle detection unit (308a) that detects a first angle that is formed between the first backrest portion and a floor surface, a second angle detection unit (309a) that detects a second angle that is formed between the second backrest portion and the first backrest portion, and a control unit (160) that controls the folding adjustment unit on the basis of the first angle at the time of automatic driving of the vehicle to adjust the second angle, and controls the seat surface adjustment unit to maintain a height of a reference position in the second backrest portion to be equal to or greater than a reference height in a case that the height of the reference position in the second backrest portion is smaller than the reference height.

A vehicle seating system includes a vehicle seat, piezoelectric sensors individually positioned at respective locations within the seat corresponding to anatomical locations of a person sitting in the seat, and a controller. The sensors to generate electrical signals in response to mechanical stress applied on the sensors from biologically motivated force inputs of the person. The controller to detect from the electrical signals generated by the sensors biometric information of the person corresponding to the biologically motivated force inputs of the person.

Systems and methods for controlling movement of an active payload support system. In one example, a seat system for a vehicle includes a seat, a support structure coupled to the seat and including an actuator configured to move the seat at a command angle relative to a floor of the vehicle responsive to movement of the vehicle, at least one sensor positioned to detect movement of the vehicle, and a controller configured to receive a signal from the at least one sensor, generate a command signal to instruct the actuator to move the seat relative to a floor of the vehicle, determine whether the command signal will cause the seat to exceed a limit, scale the command signal to conform to movement of the vehicle within the limit, and provide a force command to the actuator to move the seat based on the scaled command signal.

In order to improve steering operation operability during cornering while maintaining a driver holding property, a seat apparatus is provided with: a seat back frame; a cornering sensor for detecting a cornering direction of a vehicle; and a control unit that controls the seat back frame on the basis of the result of detection by the cornering sensor. The seat back frame is provided with: left and right side frames disposed on both sides of the seat back frame; a back plate disposed between the left and right side frames; and a swinging mechanism for swinging the back plate with respect to the direction of movement of the vehicle. The control unit controls the swinging mechanism such that, upon detection of a cornering direction of the vehicle by the cornering sensor, the inner one of the sides of the back plate with respect to the cornering direction is positioned rearward of the outer one of the sides with respect to the cornering direction.

Various systems and methods for providing an occupant profiling system are described herein. A system for profiling a vehicle occupant includes a vehicle control system, comprising: a sensor fusion circuit coupled to a plurality of sensors installed a vehicle seat, the sensor fusion circuit to: determine that a human occupant is seated in the vehicle seat; sample a backrest sensor arrangement and a base cushion sensor arrangement of the vehicle seat to obtain backrest sensor data and base cushion sensor data, when the human occupant is determined to be seated in the vehicle seat; sample, when the human occupant is determined to be seated in the vehicle seat, a height sensor to obtain a height sensor value; and statistically determine from the backrest sensor data, the base cushion sensor data, and the high sensor data, whether the human occupant matches a reference profile.