An assembly includes a webbing. The assembly includes a first webbing guide receiving the webbing. The assembly includes a second webbing guide receiving the webbing and releasably secured to the first webbing guide. The assembly includes an actuator. The assembly includes a cable secured to the actuator and to the second webbing guide.

A method of controlling an airbag inflator, may include determining, when an occupant is accommodated on a seat, whether the weight of the occupant is in which of first to fourth weight ranges sequentially allocated by a controller, performing a first logic for operating an inflator at the lowest one of three intensities by the controller when it is determined that the weight of the occupant is in the lightest first weight range, and performing a second logic for operating the inflator at the intermediate intensity or a third logic for operating the inflator at the highest intensity by the controller, according to conditions such as a position of a seat, a state of operation of a recliner, a collision condition, a collision pulse, and wearing of a belt, when it is determined that the weight of the occupant is in the third or fourth weight range.

An advanced four-point seat belt may include: a three-point seat belt to diagonally hold a passenger with a webbing; and a motorized seat belt to allow a tongue of the webbing to maintain a state of being fixed to a side surface of a seat cushion to an initial position. In particular, when a vehicle collision situation is recognized, the motorized seat belt forms an X shape webbing confinement state by withdrawing the webbing and another webbing to locate the tongue at a central position of a body of the passenger.

A control device includes a device status sensor which senses the status of a safety device installed to an autonomous vehicle, and a vehicle controller which controls the autonomous vehicle. The vehicle controller is capable of implementing each of a normal travel mode and a safe travel mode in which the level of safety is higher than in the normal travel mode. In response to the device status sensor sensing that the safety device has been unlocked, the vehicle controller performs the process of switching from the normal travel mode to the safe travel mode.

Methods, systems, and apparatus for automatically responding to at least partial submersion of a vehicle in water. The system includes a sensor configured to detect sensor data indicating whether the vehicle is at least partially submerged in water. The system includes an electronic control unit (ECU) connected to the sensor. The ECU is configured to determine that the vehicle is at least partially submerged in water based on the sensor data. The ECU is also configured to adjust at least one feature of the vehicle in response to the determination that the vehicle is at least partially submerged in water.

An apparatus including a sensor and a control unit. The sensor may be configured to determine seat orientation information. The control unit may comprise an interface configured to receive the seat orientation information. The control unit may be configured to analyze the seat orientation information, determine when to deploy a corrective measure and modify the corrective measure in response to the seat orientation information. The control unit may deploy the corrective measure using a default arrangement in a first mode. The control unit may deploy the modified corrective measure in a second mode.

A restraint system for a vehicle, with which in a pre-crash phase prior to a predicted front crash time a vehicle occupant resting on a vehicle seat can be raised from a comfort position to an upright operative position by a forward displacer, in which in a crash phase a seat belt fastened on the vehicle occupant exerts a restraining effect on the vehicle occupant, in which an electromotive reversible belt pretensioner is activated to limit the restraining force exerted on the vehicle occupant to a predefined force level, namely by means of forward displacement of the vehicle occupant along a belt force limiting travel. In accordance with the invention, when raising the vehicle occupant to the operative position in the pre-crash phase, the electromotively reversible belt pretensioner generates a pre-crash belt slack so as to provide the pre-crash belt pullout travel required for raising the vehicle occupant in a restraining-force-free manner.

A vehicle seat installed with a vehicle occupant restraining device, the vehicle seat includes: a seat cushion frame including a seat cushion side frame; a seatback frame supported swingably about a reclining rod and including a seatback side frame; an engaging portion disposed at a seat rear end side of the seat cushion side frame and at a seat lower side relative to the reclining rod, and protruding toward a seat transverse direction inner side; a first movable member disposed along the seatback side frame, a lower end portion of the first movable member being extended to position at a seat front side of the engaging portion; and a first driving member configured to extend the first movable member in a case in which a vehicle collision at a seat front side occurs or a vehicle collision at the seat front side is predicted.

An occupant monitoring device for a vehicle is configured to monitor an occupant sitting on a seat provided in the vehicle and includes a light projector, an imaging device, and a processor. The light projector is configured to project light toward the occupant sitting on the seat. The imaging device is configured to capture an image of the occupant sitting on the seat. The processor is configured to control the light projector and the imaging device to capture the image of the occupant sitting on the seat. In a case where a collision of the vehicle is neither predicted nor detected, the processor causes the imaging device to capture an image of behavior of the occupant corresponding to either one of travel control and behavior of the vehicle so as to change occupant protection control.

A force-limiting device, especially for a seat belt system (10) in a vehicle, has a force transducer (20) interacting with webbing (14) for which a normal webbing path is provided. The force transducer (20) includes a webbing track (30) that in a non-force-limiting position extends in parallel to the normal webbing path and in a force-limiting position extends inclined relative to the normal webbing path so that the force transducer (20) in the force-limiting position sets a predetermined extension force (F) required to move the webbing (14) vis--vis the force transducer (20) in a direction of belt extension (R).