According to one aspect, a method includes identifying a condition relating to an impact on a vehicle by an object, the vehicle including at least one anchor mechanism, the at least one anchor mechanism configured to anchor the vehicle to a surface. The method also includes determining whether the condition indicates that the anchor mechanism is to be deployed, and deploying the anchor mechanism when it is determined that the condition indicates that the anchor mechanism is to be deployed.

A delivery robot that delivers a delivery item in a building comprises: a first acquisition unit configured to acquire external environment information; a travel control unit configured to control traveling of the delivery robot to a delivery destination in the building on the basis of the environment information acquired by the first acquisition unit; and a notification unit configured to perform notification in a case where an opening operation of a door existing in a traveling direction of the delivery robot is detected during the traveling of the delivery robot on the basis of the environment information acquired by the first acquisition unit. The notification unit performs notification by at least one of light and sound toward the door.

A method for generating high-value test scenarios for autonomous vehicles. The method includes identifying multiple scenarios, each associated with a location on a road network. An injury value may be determined for each of the scenarios, and the scenarios and their associated injury values may be stored in a database. A desired location for testing an autonomous vehicle may be selected. At least one of the scenarios associated with the desired location and having an associated injury value that exceeds a predetermined threshold may be identified in the database. A virtual reality test environment may then be generated for the autonomous vehicle based on the at least one scenario. A corresponding system and computer program product are also disclosed and claimed herein.

A vehicle includes a vehicle roof and a vehicle floor spaced downwardly from the vehicle roof. The vehicle includes a post slidably supported by one of the vehicle floor and the vehicle roof and a tether slidably engaged with the other of the vehicle floor and the vehicle roof. The tether extends from the other of the vehicle floor and the vehicle roof toward the post. The post is slidable relative to the vehicle floor and the vehicle roof from a stowed position to a deployed position. The vehicle includes a support member mounted to the post between the vehicle floor and the vehicle roof. The vehicle includes an airbag supported by the support member. The airbag is inflatable to an inflated position when the post is in the deployed position.

A seating assembly includes a seat and a seatback. The seatback is operably coupled with the seat. A back panel is disposed on a backside of the seat and includes a metal insert. An injection molded polymeric panel is formed around the metal insert. The metal insert is retained by the polymeric panel by a ribbon style mechanical lock. Peripheral attachment features are disposed about an outer perimeter of the back panel for securing the back panel with a frame of the seatback.

A seating assembly includes a seat and a seatback. The seatback is operably coupled with the seat. A back panel is disposed on a backside of the seat and includes a metal insert. An injection molded polymeric panel is formed around the metal insert. The metal insert is retained by the polymeric panel by a ribbon style mechanical lock. Peripheral attachment features are disposed about an outer perimeter of the back panel for securing the back panel with a frame of the seatback.

A method for identifying a polarity of a freewheeling diode interconnected in parallel to an inductive actuator for a safety unit for a vehicle. The method includes applying a test current to a terminal of the freewheeling diode and carrying out a comparison between a voltage present at the terminal and a threshold voltage while the test current is being applied, a result of the comparison indicating the polarity of the freewheeling diode.

A turret airbag system is provided including a plurality of airbags disposed within the turret to protect an occupant of the turret from injury and/or ejection from the turret. Turret airbags may be configured in padding around a turret access opening, and/or as substantially cylindrical airbags that deploy between the occupant of the turret and a wall or exterior opening of the turret. In some examples, the turret airbag(s) may be integrated with a countermeasure system that deploys explosion countermeasures and activates the turret airbags based on sensor data and multiple thresholds that indicate a collision event, a rollover event and/or an explosion event.

According to one aspect, a method includes identifying a condition relating to an impact on a vehicle by an object, the vehicle including at least one anchor mechanism, the at least one anchor mechanism configured to anchor the vehicle to a surface. The method also includes determining whether the condition indicates that the anchor mechanism is to be deployed, and deploying the anchor mechanism when it is determined that the condition indicates that the anchor mechanism is to be deployed.