Embodiments of the invention include a vehicle telematics system including a telematics device and a remote server system, wherein the telematics device obtains sensor data from at least one sensor installed in a vehicle, calculates peak resultant data based on the sensor data, generates crash score data based on the peak resultant data and a set of crash curve data for the vehicle, and provides the obtained sensor data when the crash score data exceeds a crash threshold to the remote server system and the remote server system obtains vehicle sensor data and vehicle identification data from the vehicle telematics device, calculates resultant change data and absolute speed change data based on the obtained sensor data and/or the vehicle identification data, and generates crash occurred data when the resultant change data exceeds a first threshold value and when the absolute speed change data is below a second threshold value.

A method for ascertaining a state value representing a condition of a surface, in particular, of a road, traveled upon by a vehicle. The vehicle includes at least one inertial sensor. The method is characterized in that the state value is increased or decreased as a function of at least one first signal acquired by the inertial sensor.

An active seat belt control apparatus is controlled according to a state of a vehicle. A control method for the active seat belt control apparatus includes: collecting, by a communication unit, state information about the vehicle; determining, by a controller, whether to activate a pulling operation of a seat belt using the collected state information; and activating the pulling operation of the seat belt using a motor.

A method of providing road and vehicle diagnostics, includes providing a vehicle axle system having a first axle half shaft housing, a second axle half shaft housing and a differential housing. Attached to one or more of the housings is one or more tri-axis accelerometers. In communication with the accelerometers is one or more data processors configured to receive and analyze data from the accelerometers. An occurrence of one or more road events is determined by one or more spikes in the Z-direction of the data collected from the accelerometers. A depth of the road event is determined by a magnitude of the positive and negative changes in acceleration of the spike in the Z-direction and a length of road event is determined by an amount of time between two spikes of opposite magnitudes in said Z-direction. Once identified, the time and geographic location of the road event is identified.

A method for controlling triggering of at least one passenger protection device for a vehicle. The method includes a step of determining whether a signal level of at least one read-in impact signal, which represents a change in a vehicle condition indicating a potential collision of the vehicle with a potential accident object, exceeds an evaluation limiting value. The method also includes a step of using a high triggering threshold value for triggering of the at least one passenger protection device when the signal level of the at least one read-in impact signal exceeds the evaluation limiting value.

The present disclosure is related to a paving machine including a tractor, a screed assembly coupled to the tractor, and an auger coupled to the tractor and disposed between the tractor and the screed assembly. The paving machine includes an actuator coupled to the auger and the tractor. The actuator is configured to move the auger relative to a ground surface. The paving machine includes a sensor coupled to the tractor and configured to detect an obstruction on the ground surface. The paving machine includes a controller in communication with the actuator and the sensor. The controller is configured to receive a signal from the sensor assembly indicative of the obstruction. The controller is further configured to control the actuator to raise the auger.

Method for automatically carrying out safety measures when a vehicle drives on a shoulder, as well as electronic vehicle guidance system, and vehicle

The invention relates to a method for automatically carrying out safety measures when a vehicle (1) drives on a shoulder (10) differing from a roadway (3), comprising the following steps: detecting the shoulder (10) which differs from the roadway (3) and laterally adjoins the roadway (3) by means of a detection apparatus (7) of the vehicle (1), providing information regarding the position and/or type of the shoulder (10) to the vehicle (1), recognizing that the vehicle (1) is driving on the shoulder (10) by means of an electronic evaluation unit (8), evaluating a dangerous situation which accompanies the driving of the vehicle (1) on the shoulder (10) and/or can accompany the same in the future, by means of the electronic evaluation unit (8), carrying out a safety measure by tensioning at least one safety belt (13) of a restraint system (14) of the vehicle (1) depending on the evaluated dangerous situation.

The invention also relates to an electronic vehicle guidance system (4) and to a vehicle (1).

Embodiments of the invention include a vehicle telematics system including a telematics device and a remote server system, wherein the telematics device obtains sensor data from at least one sensor installed in a vehicle, calculates peak resultant data based on the sensor data, generates crash score data based on the peak resultant data and a set of crash curve data for the vehicle, and provides the obtained sensor data when the crash score data exceeds a crash threshold to the remote server system and the remote server system obtains vehicle sensor data and vehicle identification data from the vehicle telematics device, calculates resultant change data and absolute speed change data based on the obtained sensor data and/or the vehicle identification data, and generates crash occurred data when the resultant change data exceeds a first threshold value and when the absolute speed change data is below a second threshold value.

A method for controlling actuation of an actuatable restraint in response to a vehicle rollover event includes detecting whether the vehicle (12) is being driven off-road. The method also includes determining whether the vehicle (12) is undergoing a roll event (99) that would warrant actuation of the actuatable restraint (20) if the vehicle was being driven on-road. The method further includes actuating the actuatable restraint (20) in response to determining that a roll acceleration (D RATE) of the vehicle (20) indicates that the roll event is continuing. A vehicle safety system (10) includes an actuatable restraint and a controller (50) configured to control actuation of the actuatable restraint according to this method.

A safety arrangement for a vehicle. The safety arrangement has a control unit; one or more sensors, a road detection arrangement; and one or more vehicle safety systems. The control unit processes the signals from the sensors and determines whether the vehicle is travelling over rough terrain, entering a ditch-like feature, or is airborne. The control unit will activate one or more of the vehicle safety systems if it is determined that the vehicle is travelling over rough terrain, entering a ditch-like feature, or is airborne. Signals, or derived quantities, from the sensors are compared against a threshold to determine whether to activate a vehicle safety system. A first threshold level is used if the vehicle has not or is not likely to leave the road, and a second threshold level is used if the vehicle has or is likely to leave the road.