A vehicle seat includes a seat cushion, a seatback, and a headrest. At least one of the seat cushion, the seatback, and the headrest includes a fixed part and a movable part. The fixed part and the movable part that is mounted so as to be movable relative to the fixed part are provided adjacent to each other. A border between the movable part and the fixed part is exposed to an outside of the seat. A movable-side edge of the movable part and a fixed-side edge of the fixed part are disposed adjacent to each other along a direction of movement of the movable part so as to form at least a part of the border exposed to the outside of the seat. The movable part moves relative to the fixed part while keeping a constant clearance between the movable-side edge and the fixed-side edge.

A seat panel for assembly into a rear surface of a seat assembly includes a light assembly which generates task lighting directed to a task area and of sufficient brightness to be useful in performing a task within the task area. The light assembly is selectively actuable to emit light through an aperture defined by the seat panel in a defined light pattern to illuminate a recessed space in the seat panel. The seat assembly when configured as a forward seat assembly of a vehicle provides task lighting for a passenger seated rearward of the forward seat assembly, to illuminate a task area which can include one or more of the exterior surface of the seat panel, a leg space between the forward seat assembly and the passenger's seat assembly, and/or a seat space generally including a portion of the upper leg and/or lap area of the passenger.

A method for controlling an autonomous vehicle is disclosed. The vehicle control method, which adjusts a seat installed in a vehicle, a first display positioned in front of the seat and facing the seat, and a second display positioned in front of the first display and facing the seat, includes: detecting the face of a passenger sitting in the seat by a camera installed in the vehicle; estimating the face height from the floor surface of the vehicle; if the estimated face height is lower than a predetermined level, setting a display region on the first display, and, if the estimated face height is higher than the predetermined level, setting the display region on at least part of the second display; and displaying images in the set display region. One or more among an autonomous vehicle, user terminal, and server according to the present invention may be associated with an artificial intelligence module, a robot, an augmented reality (AR) device, a virtual reality (VR) device, etc.

A method for controlling an autonomous vehicle is disclosed. The vehicle control method, which adjusts a seat installed in a vehicle, a first display positioned in front of the seat and facing the seat, and a second display positioned in front of the first display and facing the seat, includes: detecting the face of a passenger sitting in the seat by a camera installed in the vehicle; estimating the face height from the floor surface of the vehicle; if the estimated face height is lower than a predetermined level, setting a display region on the first display, and, if the estimated face height is higher than the predetermined level, setting the display region on at least part of the second display; and displaying images in the set display region. One or more among an autonomous vehicle, user terminal, and server according to the present invention may be associated with an artificial intelligence module, a robot, an augmented reality (AR) device, a virtual reality (VR) device, etc.

A motor vehicle seat includes a backrest portion a first body, a second body and a mechanism configured to coupled the backrest portion to the first body in a movable manner between a first position, in which the backrest portion is arranged between the first and the second body, the latter defining a base extending crosswise to the backrest portion in order to support a passenger seating with the back resting against the backrest portion on a first surface of the backrest portion, and a second position, in which the backrest portion has a second surface opposite the first surface and facing the second body; wherein the first surface, in the second position of the backrest portion, defines a wind deflector.

A motor vehicle seat includes a backrest portion a first body, a second body and a mechanism configured to coupled the backrest portion to the first body in a movable manner between a first position, in which the backrest portion is arranged between the first and the second body, the latter defining a base extending crosswise to the backrest portion in order to support a passenger seating with the back resting against the backrest portion on a first surface of the backrest portion, and a second position, in which the backrest portion has a second surface opposite the first surface and facing the second body; wherein the first surface, in the second position of the backrest portion, defines a wind deflector.

A seat for a vehicle with a new structure integrates a walk-in mechanism, a mechanism for a relaxation posture change function, and a mechanism for a seatback full-flat folding function into one mechanism. The seat selectively performs one function of a walk-in function, a relaxation posture change function, and a seatback full-flat folding function through the one integrated mechanism.

The disclosure provides for a system that includes a seat mounted in a vehicle. The seat includes a base, a back support, a hinge, and a seat belt integrated into the seat. The back support is capable of rotating relative to the base and thereby reclining. The hinge is between the base and the back support and is configured to lock the back support in positions in relation to the base. The seat belt has a shoulder portion and a lap portion and is attached to the seat at a shoulder anchor in the back support and a base anchor in the base. When a generated torque, created from a forward force applied by the shoulder portion of the seat belt, exceeds a threshold amount of torque, the hinge is configured to unlock and back support is configured to rotate forward from a reclined position towards an upright position.

The disclosure provides for a system that includes a seat mounted in a vehicle. The seat includes a base, a back support, a hinge, and a seat belt integrated into the seat. The back support is capable of rotating relative to the base and thereby reclining. The hinge is between the base and the back support and is configured to lock the back support in positions in relation to the base. The seat belt has a shoulder portion and a lap portion and is attached to the seat at a shoulder anchor in the back support and a base anchor in the base. When a generated torque, created from a forward force applied by the shoulder portion of the seat belt, exceeds a threshold amount of torque, the hinge is configured to unlock and back support is configured to rotate forward from a reclined position towards an upright position.

A pull-strap assembly for actuating a recline mechanism of a vehicle seat includes a clevis having first and second pieces configured to snap into one another, wherein the pieces cooperate to define a cylindrical body and a cable connector. The assembly further includes a fixed anchor and a tension member having a fixed end connected to the anchor, an intermediate portion looped around the cylindrical body, and a free end. The clevis is configured to move towards the anchor responsive to the free end being pulled by a user to release the recline mechanism.