A seat belt arrangement for a motor vehicle, with at least one seat belt for the protection of a vehicle occupant seated on a vehicle seat; at least one inflatable gas bag arranged on the seat belt for protecting the vehicle occupant. The gas bag includes a passage through which the seat belt extends and to which at least one inflatable chamber of the gas bag adjoins, wherein during or after inflation of the gas bag at least a sub-section of a wall of the passage presses indirectly and/or directly against the seat belt such that the gas bag couples to the seat belt and follows an extension movement of the seat belt and hence a movement of the vehicle occupant, and wherein the seat belt is at least partly surrounded by a casing element at least within the passage.

A method for controlling operations of safety devices of a vehicle includes determining whether there is a possibility of a collision with a preceding vehicle on the basis of vehicle driving information, determining occupancy information of a passenger or a type of a passenger or determining whether a passenger has fastened a seat belt using vehicle sensor information, and determining whether to apply, and applying accordingly, full braking, a full braking profile, or an airbag deployment scheme according to the occupancy information of a passenger, the type of the passenger, or whether the passenger has fastened a seat belt when a possibility of a collision is determined, and fully retracting the passenger's seat belt before full braking is applied after partial braking is applied.

From a set of point data, a set of scattered rays is constructed. From the set of scattered rays, a set of ray slopes is computed. The set of ray slopes is mapped to a corresponding set of trigonometric functions. Using an optimization method, a parameter of the set of trigonometric functions is selected. Using an inverse of the set trigonometric functions, a vehicle mass corresponding to the set of point data is computed. Based on the vehicle mass, a threshold braking distance of a collision avoidance system of the vehicle is adjusted, the threshold braking distance comprising a distance from an object predicted to collide with the vehicle. By braking the vehicle at least the threshold braking distance from the object, a predicted collision between the vehicle and the object is avoided.

A method for activating a passenger protection device of a vehicle. A relative velocity value, which represents a relative velocity between the vehicle and an object, and at least one correction value are read in. In a further step, a velocity reduction value, which represents a decrease of a velocity of the vehicle when the vehicle collides with the object, is ascertained using the relative velocity value and the correction value. Finally, an activation signal for activating the passenger protection device is generated using the velocity reduction value.

The present disclosure relates to a vehicle control apparatus for safety of a vehicle occupant, a vehicle system including the same, and a method thereof. An exemplary embodiment of the present disclosure provides a vehicle control apparatus, including: a processor configured to recognize information related to occupants in a vehicle using a radar and to generate information for air conditioning control and airbag control depending on the occupant information; and a communication device configured to transmit the information for the air conditioning control and the airbag control depending on the occupant information to an air conditioning control device and an airbag control device.

A control device for an occupant protection device includes a power supply unit and a controller. The power supply unit performs supply of power to a squib for activating the occupant protection device. The controller causes the power supply unit to perform the supply of power at a first timing when a first condition is satisfied and causes the power supply unit to perform the supply of power at a second timing when a second condition is satisfied. At least one of the controller and the power supply unit prohibits, for a predetermined time after performing the supply of power at an earlier one timing of the first and second timings, the supply of power at another timing when the first and second conditions are satisfied.

An assembly for a vehicle includes a first seat and a second seat. The assembly includes a crossbar positioned between the first seat and the second seat. The assembly includes an airbag supported by the crossbar. The assembly includes a controller programmed to position the crossbar in a raised position in response to a detected occupant egress.

Disclosed is a rescue device for adjusting the direction of an automobile falling into water through buoyancy. The rescue device comprises an automobile body, wherein storage cavities are formed in the automobile head and the automobile tail of the automobile body, a first high-pressure quick inflation pump is embedded in the inner wall of the storage cavity, a square buoyancy air bag is folded and stored in the storage cavity, an annular storage box body is embedded in a shell of the automobile body, meanwhile, the annular storage box body is located on the side close to the driving position of the automobile body, and an annular buoyancy air bag is folded and stored in the annular storage box body.

Aspects of the disclosure relate to airbag systems for vehicles having interlocking airbags. An example airbag system may include a first airbag having a first shape and a second airbag having a second shape. The first shape and the second shape are configured to interlock with one another in order to reduce the likelihood of an object passing between the first airbag and the second airbag when the first and second airbags are inflated. In addition, the first airbag and second airbag are arranged to deploy on an exterior of the vehicle. An airbag system can also include one or more processors configured to determine that an impact with an object is likely to occur within a predetermined period of time. These processors can also use the determination to send a first signal to deploy the first airbag and a second signal to deploy the second airbag.

A loudspeaker arrangement in a motor vehicle includes a collision sensor transmitting a collision signal in response to detecting that the motor vehicle has been in a collision. An audio system transmits an audio signal. A loudspeaker includes an air bag connected thereto. The loudspeaker is coupled to the audio system and produces audible sounds based on the audio signal. The air bag is coupled to the collision sensor and is activated in response to the collision sensor transmitting the collision signal.