An assembly for a vehicle includes a panel. The panel includes a first channel and a second channel spaced from and parallel to each other. The first and second channels are designed to engage wheels of a wheelchair. The assembly includes a latch supported by the panel. The latch is moveable between an unlatched position and a latched position. The latch is retracted from the first channel in the unlatched position and elongated across the first channel in the latched position. The panel includes releasable connections designed to releasably engage a vehicle floor.

A vehicle safety system performs close-in incipient collision detection that combines high sample rate near-field sensors with advanced real-time processing to accurately determine imminent threats and the likelihood of a collision before a collision occurs. This allows applicable countermeasures to be deployed based upon the probability of a collision, while also taking into account the type of threat and the impending impact's location on the vehicle. This radically new approach will soon transform the passive safety market to greatly reduce injuries from automotive crashes and save lives.

A vehicle safety system performs close-in incipient collision detection that combines high sample rate near-field sensors with advanced real-time processing to accurately determine imminent threats and the likelihood of a collision before a collision occurs. This allows applicable countermeasures to be deployed based upon the probability of a collision, while also taking into account the type of threat and the impending impact's location on the vehicle. This radically new approach will soon transform the passive safety market to greatly reduce injuries from automotive crashes and save lives.

Aspects of the disclosure relate to deployable structures, such as airbag systems, for vehicles. A system is disclosed for reducing likelihood of injury to a passenger in a collision. The system may include a seat configured to accommodate the passenger and an airbag system. At least a portion of the airbag system may be incorporated into a vehicle prior to deployment of the airbag system. The airbag system may include an airbag and a locking feature. The locking feature may be configured to lock the airbag with a locking portion of a vehicle when the airbag system has been deployed. The locking feature may be attached to the airbag. Aside from airbags, other confining structures, such as nets, shades, curtains, etc., may also be used as deployable structures.

An occupant protection device for a vehicle includes a collision predictor, a main airbag, a seat, a sub-airbag, and a deployment controller. The collision predictor is configured to predict a collision of the vehicle. The main airbag is configured to deploy toward an occupant from a front of the vehicle when a collision of the vehicle is predicted by the collision predictor. The seat allows the occupant to be seated, and is movable in a front-back direction of the vehicle. The sub-airbag is accommodated in an upper part of the seat, and configured to deploy downward from above the occupant. The deployment controller is configured to, when a collision of the vehicle is predicted by the collision predictor, cause the sub-airbag to deploy from the upper part of the seat and subsequently cause the main airbag to deploy.

A support apparatus includes a gas-fillable support that is connectable to a gas generator. The gas-fillable support is securable to a body of a motor vehicle and has a first operating state which exists before the gas generator is activated and which has a first volume. The gas-fillable support has a second operating state which exists after the gas generator is activated and which has a second volume which is greater than the first volume. The gas-fillable support in the second operating state is contactable against a first portion which is operationally connected to the body and is contactable against a second portion which is operationally connected to the body and which is remote from the first end portion. A first mechanical strength of the gas-fillable support in the first operating state is less than a second mechanical strength of the gas-fillable support in the second operating state.

A vehicle safety system performs close-in incipient collision detection that combines high sample rate near-field sensors with advanced real-time processing to accurately determine imminent threats and the likelihood of a collision before a collision occurs. This allows applicable countermeasures to be deployed based upon the probability of a collision, while also taking into account the type of threat and the impending impact's location on the vehicle. This radically new approach will soon transform the passive safety market to greatly reduce injuries from automotive crashes and save lives.

A vehicle safety system performs close-in incipient collision detection that combines high sample rate near-field sensors with advanced real-time processing to accurately determine imminent threats and the likelihood of a collision before a collision occurs. This allows applicable countermeasures to be deployed based upon the probability of a collision, while also taking into account the type of threat and the impending impact's location on the vehicle. This radically new approach will soon transform the passive safety market to greatly reduce injuries from automotive crashes and save lives.

A passenger protection apparatus for a vehicle includes: an inflator configured to generate gas upon receiving a predetermined actuating signal; and an airbag body folded and configured to deploy by supplying the gas from the inflator to the airbag body. The airbag body includes a predetermined area on which adhesive is applied. The predetermined area adheres to an adherend when the airbag body is deployed. An adhesive force of the adhesive is decreased by a predetermined action.

The present specification relates to a method for controlling vehicle interior devices. More specifically, the method comprises the steps of: acquiring image data of a vehicle passenger located within a predetermined distance from a vehicle through an object detection device provided in the exterior of the vehicle; extracting body structure information about the body structure of the vehicle passenger from the image data by using a skeletonization-related deep learning algorithm; and when opening of a specific door of the vehicle is detected, controlling passenger seat-related interior devices corresponding to the specific door on the basis of the extracted body structure information.