The present description relates to an occupant protecting system for a vehicle, a vehicle comprising such an occupant protecting system and an occupant protecting method for such a vehicle. The occupant protecting system comprises a seat assembly, a sensor unit, an actuator unit and a control unit. The sensor unit is configured to generate crash monitoring data of the vehicle. The control unit is configured to determine a crash type based on the crash monitoring data in case of a collision of the vehicle. The actuator unit comprises a pyrotechnic element. The actuator unit is arranged at the seat assembly and capable to adjust a position of the seat assembly. The control unit is configured to cause the actuator unit based on the crash type.

An assembly for a vehicle includes a first seat and a second seat. The assembly includes a crossbar positioned between the first seat and the second seat. The assembly includes an airbag supported by the crossbar. The assembly includes a controller programmed to position the crossbar in a raised position in response to a detected occupant egress.

An airbag device for a vehicle provided with a door and a side sill includes an airbag and an application state detector. The airbag is deployed from a container to be disposed on a lower side of the door on a vehicle body to a region on a vehicle-widthwise outside of the door. The application state detector detects a load application state of a load from the airbag to the vehicle body. The airbag includes a first air chamber, a second air chamber, and an internal pressure controller. The first air chamber transmits a load applied from the vehicle-widthwise outside to a side surface of the side sill. The second air chamber couples a lower part of the first air chamber and the container. The internal pressure controller controls an internal pressure of the second air chamber based on the load application state detected by the application state detector.

An airbag device to be applied to a vehicle provided with A to C pillars, a door, and a side sill includes an airbag, a collision mode predictor, and a pressure controller. The airbag is deployed from a container to be disposed on a lower side of the side sill to a region on a vehicle-widthwise outside of a side surface of a vehicle body including the door. The airbag includes a first air chamber disposed mainly in front of the B pillar after being deployed and a second air chamber disposed mainly behind the B pillar after being deployed. The collision mode predictor predicts a collision mode of an object with the vehicle. The pressure controller increases or reduces at least either of internal pressures of the first air chamber and the second air chamber independently of the other, based on the predicted collision mode.

A vehicle steering wheel includes a hoop, a plurality of presence sensors and an outer sheath. The presence sensors are each arranged so as to detect a proximity and/or contact between a user's limb and the hoop. The outer sheath covers the plurality of presence sensors and is stitched with at least one seam that extends around at least part of the hoop. The plurality of presence sensors is mounted on the same support.

Systems and methods are provided for improving safety of one or more vehicle occupants. An example method for improving safety of one or more vehicle occupants includes accessing interior vehicle configuration data that is generated by, or derived from data generated by an interior data collection component, the data representing an interior space of a vehicle; determining, by processing the interior vehicle configuration data, location and orientation of one or more vehicle occupants; selecting a plurality of vehicle safety components to be active based on the location and orientation of the one or more vehicle occupants, and setting the plurality of vehicle safety components to an active state in which the plurality of vehicle safety components are deployed, when an emergency condition is detected.

There is provided a system for generating instructions for adjustment of vehicle sub-system(s) according to an analysis of a computed six degrees of freedom (6 DOF) of vehicle occupant(s), comprising: hardware processor(s), and a non-transitory memory having stored thereon a code for execution by the at least one hardware processor, the code comprising instructions for: obtaining at least one image of a cabin of a vehicle captured by an image sensor, obtaining depth data from a depth sensor that senses the cabin of the vehicle, wherein the at least one image and the depth data depict at least one head of at least one occupant, computing 6 DOF for the at least one head according to the at least one image and depth data, and generating instructions for adjustment of at least one vehicle sub-system according to the computed 6 DOF of the at least one vehicle occupant.

An occupant protection device for a vehicle includes: a collision predictor configured to predict a collision of the vehicle; a main airbag configured to deploy toward an occupant from a front of the vehicle when the collision predictor predicts a collision of the vehicle; an occupant center-of-gravity detecting device configured to detect a position of a center of gravity of the occupant; an armrest moving device configured to move an armrest; and a deployment controller configured to cause, when the collision predictor predicts a collision of the vehicle, the armrest moving device to move the armrest upward to guide the center of gravity of the occupant into a proper range on the basis of the position of the center of gravity of the occupant detected by the occupant center-of-gravity detecting device, subsequently cause the armrest moving device to remove the armrest, and thereafter, cause the main airbag to deploy.

A system includes a seat belt routing module and a user interface device (UID) control module. The seat belt routing module is configured to: determine a routing of a seat belt relative to an occupant in a vehicle seat based on input from a webbing payout sensor; and determine the seat belt routing based on an input from an in-cabin sensor. The in-cabin sensor includes at least one of a camera, an infrared sensor, an ultrasonic sensor, a radar sensor, and a lidar sensor. The UID control module is configured to control a user interface device to indicate that the seat belt is being worn improperly when: the seat belt routing determined using at least one of the webbing payout sensor and the in-cabin sensor is improper; and the seat belt routing determined using the webbing payout sensor corresponds to the seat belt routing determined using the in-cabin sensor.

A seat includes a seat bottom and a seatback rotatable relative to the seat bottom. The seatback is elongated upwardly from the seat bottom along a longitudinal axis of the seatback. An airbag assembly is supported by the seatback in an uninflated position. The airbag includes a housing and an airbag supported by the housing. The housing is moveably engaged with the seatback and moveable relative to the seat along a longitudinal axis of the seatback.