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 electronic parachute deployment system includes an electronic actuator, a control module, a deployment actuator, and a release mechanism. A parachute is positioned on a payload device, such as a racecar, to slow or stop the payload upon receipt of an electronic deployment activation signal. The electronic deployment signal is verified, including determining proper voltage and source. The deployment system includes multiple redundancies including mechanical deployment redundancy, remote deployment redundancy, and power supply redundancy. The control module responsible for monitoring deployment includes indicators and sensors to indicate a status, operation, or mode relative to the operability of the payload device, relative to components of the release mechanism, and relative to the parachute deployment.

An emergency vehicle flotation system has bladder(s) attached in a compressed state on a vehicle. An inflation initiating component comprising a selected one or more of a submersion sensor attached to the vehicle to detect water pressure indicative of submersion of the vehicle and a user interface device. Selectable force gas generator(s) (SFGGs) have one gas-generating propellant cells that are individually fired. The SFGG(s) have conduit(s) that receive gas from fired gas-generating propellant cells and direct the gas to inflate the bladder(s). A controller is communicatively coupled to the inflation initiating component and the gas-generating propellant cells of the one or more SFGGs. The controller enables the emergency vehicle flotation system to receive an inflation signal from the inflation initiating component, and to fire a selected number of the more than one gas-generating propellant cells to at least partially inflate the bladder(s).

An assembly for a vehicle includes a vehicle roof and a panel rotatably connected to the vehicle roof. The panel is rotatable away from the vehicle roof from a stowed position to a deployed position. The assembly includes an airbag supported on the panel. The airbag is inflatable from the panel in a vehicle-forward direction when the panel is in the deployed position.

An occupant protection apparatus to be applied to a vehicle includes a contact detector, a control processor, and a lifting mechanism. The contact detector detects frontal contact of the vehicle. The control processor includes a contact determination unit determining whether the frontal contact of the vehicle is underride contact based on a result of detecting by the contact detector. The lifting mechanism includes a lifting member and a lifting driver. The lifting member is disposed below a rear end part of a hood in a downward direction of the vehicle. The hood is disposed on a frontal part of the vehicle. The lifting driver transmits a driving force to the lifting member. When the contact determination unit determines that the frontal contact is the underride contact, the rear end part of the hood is lifted by the lifting mechanism.

A vehicle seat device includes: a detection unit that detects a side collision in a vehicle; a seat that is provided in a vehicle cabin so that the seat can be located at a center portion of the vehicle cabin in a vehicle width direction and that can face at least one of a front side and a rear side in a vehicle front-rear direction; a restraint portion that is provided on a seat side portion and that is movable between a retracted position in which the restraint portion does not face a seated occupant seated in the vehicle width direction, and a facing position in which the restraint portion faces the occupant in the vehicle width direction; and a movement control unit that positions the restraint portion at the facing position when the seat is located at the center portion and the detection unit detects the side collision.

A system and method are provided for controlling an interior configuration of a vehicle following a collision. Sensor data that includes, or is derived from data that includes, data collected by one or more sensors is received, and a vehicle accident condition indicative of an accident having occurred is detected by processing the sensor data. After detecting the vehicle accident condition, an actuator component is caused to prevent a passenger from adjusting an interior vehicle component outside a predetermined range of physical configurations, while allowing the passenger to adjust the interior vehicle component within the predetermined range of physical configurations.

Among other things, a documentation of a crash involving a vehicle is generated automatically. Telematics data is received that has been produced by one or more sensors associated with a telematics device at the vehicle. Based on the telematics data, a vehicle crash period is determined that begins at a start time and ends at an end time of the vehicle crash. Based on the telematics data, one or more metrics are determined associated with the vehicle during the vehicle crash period. Based on one or more metrics, a human-readable documentation of the vehicle crash is generated automatically.

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.

According to one aspect, a method includes determining that a rapid deceleration mechanism of a vehicle is to be deployed at a first location, and identifying at least one deployment parameter associated with a deployment of the rapid deceleration mechanism, the at least one deployment parameter being associated with the first location. The method also includes deploying the rapid deceleration mechanism at the first location based on the at least one deployment parameter.