An apparatus includes a capture device and a processor. The capture device may be configured to generate a plurality of video frames corresponding to an area outside of a vehicle. The processor may be configured to perform operations to detect objects in the video frames, determine whether a potential collision is unavoidable based on the objects detected in the video frames and generate a signal if the potential collision is unavoidable. The signal may be configured to move a position of a seat in the vehicle. The position of the seat may be moved before an impact corresponding to the potential collision occurs.

A roof curtain airbag for a vehicle includes an airbag cushion that is expanded to a space between passengers seated on respective seats when a plurality of seats are arranged to face each other, so that a collision between the passengers is prevented and the passengers are protected from impact by the airbag cushion.

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.

A front airbag device for a vehicle is proposed. In the front airbag device, an airbag cushion is mounted in front of a passenger and is expanded to be positioned at a front surface of the passenger, a triangular main tether and a triangular support tether are positioned inside the airbag cushion, and one side of the main tether and one side of the support tether are spaced apart from each other and are coupled to the airbag cushion in a sewn manner, so that the main tether and the support tether support a front surface portion of the airbag cushion to protect a front surface of the passenger.

A state detection sensor includes a housing and a position sensing component mounted in the housing. The position sensing component is being configured to provide position data in response to detecting the presence or position of vehicle structure relative to the sensor. The state detection sensor also includes an analog input component mounted in the housing. The analog input component is configured to provide external analog sensor data in response to an analog signal received from an external analog sensor to which the analog input component can be operatively connected. The state detection sensor further includes a component configured to communicate the position data and the external analog sensor data via a serial bus.

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.

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.

The present disclosure relates to a control method for controlling the movement of a seat, called the selected seat, for a motor vehicle equipped with a plurality of seats, comprising: a step of modeling a seat volume associated with each seat of the plurality of seats of the vehicle; an overlap determination step for determining the overlap, called the interference, during which it is determined whether there is at least partial overlap between the seat volume associated with the selected seat, called the selected volume, and the seat volume associated with each of the other seats of the plurality of seats of the vehicle, if the movement is performed; and a decision step, during which the movement is at least partially prohibited or allowed on the basis of the determination step.

A method includes sensing when a seat is at a first location in a vehicle, and controlling an occupant restraint system of the vehicle in a first manner based on the seat being at the first location in the vehicle. The method further includes sensing when the seat is at a second location in the vehicle, and controlling the occupant restraint system of the vehicle in a second manner based on the seat being at the second location in the vehicle. A system receives data indicating a location of seats in a vehicle and operates an occupant restraint system for the seats using a first set of parameters when the data indicates that a first seat is at a first location, and operates the occupant restraint system for the first seat using a second set of parameters when the data indicates that the first seat is at a second location.

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).