An autonomous vehicle is provided. The autonomous vehicle includes a vehicle control device positioned proximate a forward end of the autonomous vehicle. The autonomous vehicle further includes a passenger seat. The passenger seat defines a seating orientation and is configurable in at least a first position and a second position. When the passenger seat is in the first position, the seating orientation is directed towards the rear end of the autonomous vehicle. In addition, the vehicle control device is substantially obscured from access from a passenger compartment of the autonomous vehicle. When the passenger seat is in the second position, the seating orientation is directed towards the forward end of the autonomous vehicle. In addition, the vehicle control device is accessible from the passenger compartment of the autonomous vehicle.

An aircraft seat with tilt-shift functionality includes a backrest frame pivotably mounted to the seat frame, the backrest frame having rollers set into its upright end that translate through slots in the seat frame and lateral slots in its forward end capable of accepting sliders attached to the seatpan. When a passenger leans backward in the seat, tilting the backrest frame backward and downward, a shift linkage below the backrest frame translates the backward tilt to a forward shift of the seatpan forward to enhance the comfort of the passenger. The aircraft seat may further be capable of longitudinal and lateral translation as well as a full 360-degree swivel.

An electrical system may include a mounting surface, a component configured for connection with the mounting surface and configured to move relative to the mounting surface, and/or an orientation sensor configured to determining an orientation of the component relative to the mounting surface. The orientation sensor may include a first sensor (e.g., a magnetometer, an accelerometer, a gyroscope, etc.) connected, at least indirectly, to the mounting surface, and a second sensor (e.g., a magnetometer, an accelerometer, a gyroscope, etc.) connected to move with the component. The orientation sensor may include an electronic controller. The electronic controller may be configured to compare first information from the first sensor to second information from the second sensor to determine the orientation of the component relative to the mounting surface.

An airbag assembly includes a housing and a side airbag inflatable to an inflated position. The side airbag in the inflated position has an upper lobe and a lower lobe supporting the upper lobe on the housing. The side airbag includes an internal panel between the upper lobe and the lower lobe. A tether has a first end anchored to the housing and a second end anchored to the upper lobe.

A vehicle includes a floor, a roof, and a pair of body sides spaced from each other. A pillar is spaced from both of the body sides. The pillar has a first end at the roof and a second end at the floor. An airbag is supported on the pillar.

Aspects of the present disclosure include a vehicle having a passenger assistance system for facilitating ingress and egress of passengers. The vehicle may include a plurality of wheels. The vehicle may include a body including at least one doorway supported on the plurality of wheels via a suspension. The vehicle may include a door movable between an open position and a closed position covering the at least one doorway. The vehicle may include a first platform movable between a horizontal position beneath a bottom of the doorway and a stowed position parallel to the door. The vehicle may include an occupant compartment within the body. The occupant compartment may include a seat rotatable to face the doorway in an ingress or egress mode. The occupant compartment may include a robotic arm configured to extend along an ingress or egress path through the doorway.

A removable component system may include a removable component selectively connectable to a mounting surface including a component electrical unit; an antenna; a system controller configured to communicate with the component electrical unit and the antenna; and/or a track assembly configured to be fixed to said mounting surface. The removable component may be selectively connectable to said mounting surface via the track assembly. The removable component may be configured for selective connection with, removal from, and movement along the track assembly. The system controller may be configured to obtain a position of the removable component relative to said mounting surface via the antenna and the component electrical unit (e.g., via a component controller, a sensor, and/or a communication device thereof).

An occupant support system includes a first vehicle seat and a second vehicle seat. The second vehicle seat is spaced apart from the first vehicle seat.

Aspects of the present disclosure may include a vehicle having one or more tires, a body, and an occupant compartment including: a rotatable platform, a central pod seat and one or more companion pod seats disposed on the rotatable platform, and one or more rear seats, wherein the rotatable platform is configured to rotate the central pod seat and the one or more companion pod seats toward a front of the vehicle in a first mode and toward a rear of the vehicle in a second mode, and wherein the central pod seat is further configured to translate linearly away from a center of the rotatable platform into a first position and toward the center of the rotatable platform into a second position.

A restraint system for helping to protect an occupant of a vehicle having a floor and a cabin with a floor for the occupant includes an airbag. The airbag has a stored condition on the vehicle floor and is inflatable to a deployed condition aligned with the occupant in a forward-rearward direction of the vehicle. The airbag is configured to utilize the vehicle floor as a reaction surface for restraining the movement of the airbag in response to occupant penetration into the airbag.