A system and method for detecting seatbelt routing in a motor vehicle safety restraint system for a motor vehicle seat. The system includes a seatbelt buckle sensor, a seatbelt payout sensor, an occupancy sensor, an automatic locking retractor sensor and a control module. The method includes sensing a presence of a seatbelt latchplate in a seatbelt buckle. Further, the method includes sensing a seatbelt payout length. Additionally, the method includes comparing the seatbelt payout length to a first seatbelt payout length threshold. Moreover, the method includes determining seatbelt routing based on whether seatbelt latchplate is present in the seatbelt buckle and the seatbelt payout length is greater than the first seatbelt payout length threshold.

An inflatable blanket for a vehicle includes a first blanket layer, a second blanket layer coupled to the first blanket layer, and an airbag disposed between the first blanket layer and the second blanket layer. The airbag has a deflated configuration and an inflated configuration to protect a vehicle occupant when the vehicle is subjected to an external force.

A vehicle includes: a sensor for measuring a relative position and a relative speed between an obstacle and the vehicle; an injector for injecting a deforming material which is solidified during injection to absorb an impact and enhance coupling strength at a portion to which the deforming material is attached; and a controller configured to determine a collision probability with the obstacle based on the measured relative position and the measured relative speed, to determine a predicted collision position when the collision probability reaches a reference collision probability, to determine an injection direction of the injector based on the predicted collision position, and to control the injector to inject the deforming material in the determined injection direction.

An object is identified by an on-board camera and a relative speed of the vehicle and the object is acquired. If the object is a two-wheel vehicle and the relative speed is lower than the vehicle speed, the relative speed is set as a collision speed. If the object is an object other than a two-wheel vehicle, the vehicle speed is set as the collision speed. Using the set collision speed, an effective mass is computed and collision determination is executed.

A method and apparatus for protecting a passenger during a crash comprises a moveable seat with an energy absorber (EA) that allows the seat to stroke a finite distance to decelerate the passenger in a controlled manner. The seat is designed so that one of a plurality of fixed profile EA's can be selectively engaged to provide a tailored EA composite profile adapted to the occupant's weight and anticipated crash environment. The tailored EA composite profile applies a frequency matched, low onset force to the seat, which substantially eliminates problems associated with dynamic overshoot of the passenger's spine.

One general aspect includes a deployable containment system for a vehicle roof panel, the system including: a pair of guide channels proximate to an opening through the vehicle roof panel, each guide channel of the pair having a first end and a second end; a housing mounted to the first end of the pair of guide channels. The deployable containment system also includes a shield configured to deploy from the housing and travel along the pair of guide channels so as to cover at least a portion of the opening. The deployable containment system also includes an actuator disposed proximate to the pair of guide channels, the actuator configured to deploy the shield from the housing after a deployment event.

An apparatus including a sensor and a control unit. The sensor may be configured to perform a snapshot configured to detect interior information about a vehicle. The control unit may comprise an interface configured to receive an event warning and the snapshot. The control unit may be configured to determine whether an event is imminent based on the event warning, activate the snapshot when the event is imminent, analyze the interior information based on the snapshot corresponding to the imminent event, determine an arrangement of corrective measures to deploy based on the interior information and the event warning and activate the corrective measures based on the arrangement.

One general aspect includes a deployable containment system for a vehicle roof panel, the system including: a pair of guide channels proximate to an opening through the vehicle roof panel, each guide channel of the pair having a first end and a second end; a housing mounted to the first end of the pair of guide channels. The deployable containment system also includes a shield configured to deploy from the housing and travel along the pair of guide channels so as to cover at least a portion of the opening. The deployable containment system also includes an actuator disposed proximate to the pair of guide channels, the actuator configured to deploy the shield from the housing after a deployment event.

A method for adapting a triggering algorithm of a personal restraint device of a vehicle on the basis of a detected vehicle interior state of the vehicle. The method comprises detecting of key points of a vehicle occupant by an optical sensor device, ascertaining a vehicle occupant posture of the vehicle occupant based on the connection of the detected key points to a skeleton-like representation of body parts of the vehicle occupant, wherein the skeleton-like representation reflects the relative position and orientation of individual body parts of the vehicle occupant, predicting a future vehicle occupant posture of the vehicle occupant based on a predicted future position of at least one of the key points, and modifying the triggering algorithm of the personal restraint device based on the predicted future posture of the vehicle occupant. A control device for adapting a triggering algorithm of a personal restraint device is also disclosed.

A method and apparatus for protecting a passenger during a crash comprises a moveable seat with an energy absorber (EA) that allows the seat to stroke a finite distance to decelerate the passenger in a controlled manner. The seat is designed so that one of a plurality of fixed profile EA's can be selectively engaged to provide a tailored EA composite profile adapted to the occupant's weight and anticipated crash environment. The tailored EA composite profile applies a frequency matched, low onset force to the seat, which substantially eliminates problems associated with dynamic overshoot of the passenger's spine.