A vehicular collision avoidance system includes a remote communicator disposed exterior and remote from the vehicle and operable to communicate information regarding location and motion of the remote communicator relative to the vehicle. A receiver at the vehicle receives a communication from the remote communicator, and a control at the vehicle includes a processor that processes information communicated by the remote communicator and received at the receiver. The control, responsive to processing communicated information, determines the location and motion of the remote communicator relative to the vehicle. A side sensing device is disposed at a side of the vehicle and operable to capture data, which is processed to determine approach of the remote communicator to the vehicle. Data captured by the side sensing device and information communicated by the remote communicator are processed at the control to determine a potential collision between the remote communicator and the vehicle.

An airbag assembly includes a first airbag and a second airbag each inflatable to an inflated position, and a panel. In the inflated position, each of the first and second airbags have a bend, and first and second legs extending from the bend. The panel extends from the first airbag to the second airbag in the inflated position.

Internal event verification is enabled in sensor bus systems. One example sensor bus system includes a channel master component and one or more channel slave components. A first subset of the channel slave components can include sensors that sense one or more properties (e.g., acceleration) associated with an event (e.g., crash) and output sensor data based on the one or more sensed properties. A second subset of the channel slave components can include channel verification components that can receive, decode, and analyze at least a portion of the sensor data, and output event data indicating whether an event occurred based on the analyzed portion of the sensor data. The channel master component can receive and decode the sensor data and the event data, and output information to a controller, which can send a signal to initiate a response (e.g., airbag deployment) when an event is detected and verified.

The disclosure relates to a device for a vehicle. The device comprises a component for the vehicle and an explosive module. The explosive module is configured so as in response to a trigger signal to cause the component to fragment.

A seat includes a seatback including a top portion, a seat bottom coupled to the seatback, an airbag, a tether fixed to the seatback below the top portion and attached to the airbag, and an airbag extension. The airbag is inflatable from an undeployed position in the top portion to a deployed position attached to the top portion and extending in front of a front panel of the seatback. The airbag extension is inflatable from the airbag in the deployed position in front of the seat bottom.

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.

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.

A vehicular collision avoidance system includes a remote communicator disposed exterior and remote from the vehicle and operable to communicate information regarding location and motion of the remote communicator relative to the vehicle. A receiver at the vehicle receives a communication from the remote communicator, and a control at the vehicle includes a processor that processes information communicated by the remote communicator and received at the receiver. The control, responsive to processing communicated information, determines the location and motion of the remote communicator relative to the vehicle. A side sensing device is disposed at a side of the vehicle and operable to capture data, which is processed to determine approach of the remote communicator to the vehicle. Data captured by the side sensing device and information communicated by the remote communicator are processed at the control to determine a potential collision between the remote communicator and the vehicle.

A vehicle seat assembly includes a seatback including a left lateral panel and a right lateral panel opposite the left lateral panel, a left airbag inflatable from the left lateral panel to an inflated position, a right airbag inflatable from the right lateral panel to an inflated position, a tether extending from the left lateral panel to the right lateral panel, and a sheet connected to the left airbag and the right airbag. The tether is connected to the left and right airbags.

In one embodiment, a vehicular monitoring and controlled response system includes a substance having a plurality of particles dispersed therein, the particles being tunable in response to an external stimulus; a sensor for measuring a disruption to a vehicle; and a computing device in communication with the sensor and the vehicle. The computing device has non-transitory computer readable medium with computer executable instructions stored thereon executed by a digital processor to analyze data received by the sensor; determine a magnitude of the external stimulus based on the data received by the sensor; and activate the external stimulus.