An apparatus and a method of controlling an airbag of a vehicle are capable of securing robustness of an airbag deployment logic and more effectively protecting passengers. The apparatus and method achieve this by determining whether to deploy an airbag based on a post-human injury probability calculated through a human injury probability model and Bayesian network learning (feedback learning). The apparatus includes: a human injury probability calculator configured to calculate a human injury conditional probability and a human injury prediction probability based on vehicle motion information measured by a sensing device; a learner configured to calculate a post-human injury probability by performing a probability-based real-time feedback machine learning based on the human injury conditional probability and the human injury prediction probability; and an airbag deployment determiner configured to determine whether to deploy an airbag based on the post-human injury probability.

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 method, a device and a computer program for activating a secondary function of an occupant protection system, a vertical acceleration and a lateral acceleration being detected and evaluated and an instantaneous position of the vehicle being determined based on the vertical acceleration and the first lateral acceleration. In the process, a lifting-off of the vehicle and/or an impact of the vehicle on its wheels is detected. A secondary function is activated if an impact of the vehicle on its roof and/or if an impact of the vehicle on one side or an impact of the vehicle on its wheels is detected.

An inertial sensor, includes: a substrate; a fixing portion that is provided on the substrate; a first movable body that faces the substrate and that is displaceable with a first support beam as a first rotation axis; the first support beam that is arranged in a first direction and that couples the first movable body and the fixing portion; a second movable body that is displaceable due to deformation of a second support beam; the second support beam that is arranged in a second direction intersecting the first direction and that couples the first movable body and the second movable body; and a protrusion that is provided on the substrate or the second movable body, overlaps the second movable body in plan view from a third direction and that protrudes toward the second movable body or the substrate.

A vehicle safety system includes an actuatable restraint for helping to protect a vehicle occupant and a controller for controlling actuation of the actuatable restraint in response to a vehicle rollover event. The controller is configured to execute a discrimination algorithm comprising at least one classification metric that utilizes at least one of vehicle pitch rate (P_RATE) and vehicle roll acceleration (D_RATE) to discriminate at least one of a ramp rollover event and a soil rollover event from an embankment rollover event. The discrimination algorithm determines a classification of the vehicle rollover event as one of a ramp rollover event, a soil rollover event, and an embankment rollover event. The controller is also configured to select a deployment threshold for deploying the actuatable restraint. The deployment threshold corresponds to the classification of the vehicle rollover event.

A collision detection sensor includes a sensor module which includes a first surface and a second surface facing each other. The first surface includes an acceleration detection element detecting a vehicle acceleration in one direction parallel thereto, and the second surface is formed with a first land and a second land. Among four corners of the second surface, one corner in a first pair of opposing corners is provided with the first land, and the other corner in the first pair of opposing corners is provided with the second land.

An inertial sensor includes a substrate, a sensor element provided on the substrate, a lid that covers the sensor element and is bonded to the substrate, and a plurality of terminals positioned outside the lid and electrically coupled to the sensor element, in which the plurality of terminals include an input terminal to which an electrical signal is input and a detection terminal for detecting a signal from the sensor element, and L1>L2, where L1 is a distance between the input terminal and the lid, and L2 is a distance between the detection terminal and the lid.

An occupant protection device capable of protecting occupants at a higher level is provided. An occupant protection device comprises a first sensor for detecting a value concerning a rotation angle of a vehicle, a second sensor for detecting an acceleration in the vehicle longitudinal direction, and a collision determination section adapted to determinate whether or not a collision has occurred to the vehicle based on the detection result of the first sensor and to determinate whether or not the collision has occurred to the vehicle also based on the detection result of the second sensor.

A method, a device and a computer program for activating a secondary function of an occupant protection system, a vertical acceleration and a lateral acceleration being detected and evaluated and an instantaneous position of the vehicle being determined based on the vertical acceleration and the first lateral acceleration. In the process, a lifting-off of the vehicle and/or an impact of the vehicle on its wheels is detected. A secondary function is activated if an impact of the vehicle on its roof and/or if an impact of the vehicle on one side or an impact of the vehicle on its wheels is detected.

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.