A recreational off-highway vehicle includes side-by-side passenger and driver seats held within a chassis that is approximately 50 inches wide. The seats sit low in the chassis and are covered by a roll cage. Grab handles are positioned on the sides of the passenger seat. Select large round tubing protects the vehicle, while rectangular tubing frames the portions of the vehicle beneath body panels. The vehicle is powered by an engine rearward of the seats that is connected to a transaxle. The engine and transaxle are isolation mounted together with a portion of the air intake assembly. The vehicle is suited for rough terrain travel.

A vehicle airbag system is proposed. The vehicle airbag system includes: a front airbag mounted to a portion of a vehicle in front of a passenger and configured to be unfolded toward a front of the passenger; an upper airbag mounted to a portion of the vehicle above the passenger and configured to be unfolded toward the front of the passenger; a seat detector configured to detect a seating posture of the passenger; and a controller configured to control unfolding of the front airbag or the upper airbag on the basis of the passenger's seating posture detected by the seat detector.

To reduce an amount of rear protrusion of a vehicle seat equipped with an airbag module configured to deploy rearward, in a vehicle seat provided with a seat cushion and a seat back, the seat back includes: a seat back frame including a pair of left and right side frames extending in a vertical direction and an upper frame connecting upper ends of the side frames to each other; an airbag module supported by an upper half of the seat back frame via a bracket; and a skin member covering the seat back frame, the bracket, and the airbag module from a rear side thereof, wherein a part of the skin member corresponding to the airbag module is provided with a frangible portion configured to open upon inflation of an airbag.

A seat assembly having an occupant protection system. The occupant protection system may have a deployable shield. The deployable shield may extend around multiple sides of the seat assembly, may extend at least partially around a front of a seat occupant when deployed, may be deployable along a dynamic deployment path based on a detected position of a seat occupant, or combinations thereof.

A vehicle seat includes a seat back frame, an elastic installation supporting member installed in the seat back frame, and an airbag within a seat back, the vehicle seat causing the airbag to inflate and develop within the seat back. An inflator is attached to the seat back frame. The seat back frame has a substantially frame shape along a seat back shape. The airbag is provided in the seat back frame in the substantially frame shape. The inflator is attached to at least one of an upper portion and a lower portion of the seat back frame in the substantially frame shape. An inflation and a development of the airbag in the seat back due to an operation of the inflator allows the airbag to elastically support an upper body of a seated person and to elastically receive an impact force.

The present invention relates to an occupant monitoring method and apparatus therefor. A monitoring apparatus according to one aspect of the present invention may include a camera obtaining an image in a vehicle and a processor processing the image. Moreover, the processor may include a detecting module separating each region in which an object exists from the image, a classifying module classifying the object existing in the each separated region and a recognizing module recognizing a pose of an occupant if the object corresponds to the occupant.

A processing device includes a control unit configured to execute identifying a first training device that is of one or more training devices equipped in a movable object for providing a training opportunity to a passenger and that is used by the passenger, and at least one process of controlling a traveling state of the movable object depending on a content of a training using the first training device and restricting use states of the one or more training devices depending on the traveling state of the movable object.

One general aspect includes a system to establish a deployment force for an airbag of a vehicle, the system includes: a memory configured to include one or more executable instructions and a processor configured to execute the executable instructions, where the executable instructions enable the processor to carry out the following steps: monitoring a head position of a vehicle occupant; based on the monitored head position, calculating a distance of a body part of a vehicle operator relative to a portion of an interior cabin of the vehicle; and based on the distance of the body part, establishing the deployment force for the airbag.

A vehicle includes a floor and a roof. A panel is removably attached to and supported by the floor. The panel is designed to engage a personal mobility device. An airbag housing is supported by the roof and moveably relative to the roof along a cross-vehicle axis and along a vehicle-longitudinal axis. An airbag is supported by the airbag housing. The airbag is inflatable to an inflated position that extends from the airbag housing towards the panel.

A vehicle configuration wherein the center of mass of the vehicle is approximately superimposed upon the passenger and driver centers of mass when seated within the vehicle. An occupant's center of mass can be approximated using a standard center of mass position approximation, or a combination of any number of standard center of mass position approximations. The vehicle's center of mass can be approximately superimposed upon the occupant's center of mass in at least the longitudinal and vertical directions.