This document describes one or more aspects of an in-vehicle occupant monitoring and calming system. In one example, the system includes a processor that receives occupant data from occupancy-monitoring sensors (e.g., microphones, cameras, radar sensors, ultrasonic sensors) of a vehicle. Based on the occupant data, the processor can determine whether the occupant is distressed and provide an image or video of the occupant to the driver. The processor can also display driver-selectable options to calm the distressed occupant. The options can include playing an audio or video file for the occupant, adjusting the ambient lighting of the vehicle, or rocking or gently vibrating the occupant's seat. In this way, the described system can monitor vehicle occupants and automatically display a video of the distressed occupant to the driver. In addition, the driver can calm the distressed occupant without removing their attention from driving.

A reclining seat including, but not limited to, a seat bottom. The reclining seat further including, but not limited to, a seat back having an upper segment and a lower segment, the lower segment pivotally coupled with the seat bottom via a first pivotal coupling, and the upper segment pivotally coupled with the lower segment via a second pivotal coupling.

An assembly includes a seat bottom including a panel pivotable from a first position to a second position. The assembly includes a track supported by the seat bottom. The assembly includes a spring in the track and urging the panel toward the second position. The assembly includes a pyrotechnic actuator maintaining the spring in compression and actuatable to release the spring.

A system includes a body structure, an assembly that is connected to the body structure, an airbag assembly that includes a housing that is located behind a first portion of the body structure and a deployable structure. The deployable structure is located in the housing in a stowed position and extends outward relative to the housing in an inflated position. The deployable structure includes a main chamber that is located adjacent to the seat assembly in the inflated position, and a reaction chamber that is spaced from the seat assembly by the main chamber in the inflated position. The deployable structure is configured so that forces that are applied to the main chamber of the deployable structure in a longitudinal direction of the vehicle cause the reaction chamber to move in a lateral direction so that the reaction chamber engages the body structure.

A vehicle seat including a pivot bracket, a back frame, a linear adjustment mechanism, a striker, and a latch. The back frame is pivotally connected to the pivot bracket and configured to pivot about a pivot axis. The back frame includes a first end spaced apart from the and disposed below the pivot axis. The latch is configured to selectively attach the linear adjustment mechanism to the first end of the back frame so that as the first linear adjustment mechanism translates, the back frame pivots from a first use position and a second use position, and selectively detach the linear adjustment mechanism from the first end of the back frame so that the back frame is pivotable to a non-use position.

A seat system includes: a base; a seatback; at least one recliner connecting the base and the seatback to each other for pivoting of the seatback relative to the base; a slider coupled to the base and configured for sliding engagement with a track having a detent region and a tilt-and slide region; and an electronic controller, wherein without mechanical interlock between the recliner and the slider, the electronic controller causes the recliner to place the seatback in a non-passenger position when the slider is within the tilt-and-slide region, and causes the recliner to place the seatback in a passenger position when the slider is within the detent region.

A vehicle seating assembly is provided that includes a pivot bracket coupled to a vehicle floor and disposed at a front of a seat frame, a gear assembly and a locking disk assembly disposed around an axis of rotation defined by the pivot bracket, wherein the gear assembly and the locking disk assembly are configured to each alternatively move the seating assembly from a sitting position to a standing position, and a track assembly disposed on the vehicle floor and between opposing side brackets of a seat frame. The track assembly includes a cam assembly movable between a locked position and an unlocked position. The vehicle seating assembly further includes a crank assembly extending between the pivot bracket and the cam assembly and configured to move the cam assembly from the locked position to the unlocked position.

Systems and methods for controlling autonomous vehicles are provided. In one example embodiment, a computing system can obtain data indicative of a service assignment associated with an autonomous vehicle. The service assignment is indicative of a destination location. The computing system can determine a checklist associated with the destination location. The computing system can provide, for display via a display device, data indicative of a user interface. The user interface can present the checklist associated with the destination location. The computing system can obtain data indicative of user input associated with the checklist. The computing system can determine that the checklist has been completed based at least in part on the user input associated with the checklist. The computing system can, in response to determining that the checklist has been completed, cause the autonomous vehicle to initiate a motion control to travel to the destination location.

A communication unit obtains transport plan information for transport of a plurality of persons using an automobile, and a processor generates seat control information for moving, to an entrance or an exit, a seat specified from the transport plan information among a plurality of seats provided in the automobile by using the transport plan information, and outputs the seat control information to a seat movement control unit which controls movement of the plurality of seats.

A seat system includes: a base; a seatback; at least one recliner connecting the base and the seatback to each other for pivoting of the seatback relative to the base; a slider coupled to the base and configured for sliding engagement with a track having a detent region and a tilt-and slide region; and an electronic controller, wherein without mechanical interlock between the recliner and the slider, the electronic controller causes the recliner to place the seatback in a non-passenger position when the slider is within the tilt-and-slide region, and causes the recliner to place the seatback in a passenger position when the slider is within the detent region.