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.

According to one aspect, a method includes determining that a rapid deceleration mechanism of a vehicle is to be deployed at a first location, and identifying at least one deployment parameter associated with a deployment of the rapid deceleration mechanism, the at least one deployment parameter being associated with the first location. The method also includes deploying the rapid deceleration mechanism at the first location based on the at least one deployment parameter.

Embodiments described herein generally relate to a system for preventing the automatic retraction of a seatbelt. The system generally includes one or more processors, one or more host vehicle status sensors, one or more seatbelt braking mechanisms, and one or more memory modules. The one or more host vehicle status sensors output a status signal that a host vehicle is stopped an off-road driving condition. The one or more memory modules store logic that causes the one or more processors to determine that the host vehicle is in the off-road driving condition based on the status signal output by the one or more host vehicle status sensors and activate the one or more seatbelt braking mechanisms in response to detecting the host vehicle is in the off-road driving condition to prevent automatic retraction of the seatbelt.

Embodiments described herein generally relate to a system for preventing the automatic retraction of a seatbelt. The system generally includes one or more processors, one or more host vehicle status sensors, one or more seatbelt braking mechanisms, and one or more memory modules. The one or more host vehicle status sensors output a status signal that a host vehicle is stopped an off-road driving condition. The one or more memory modules store logic that causes the one or more processors to determine that the host vehicle is in the off-road driving condition based on the status signal output by the one or more host vehicle status sensors and activate the one or more seatbelt braking mechanisms in response to detecting the host vehicle is in the off-road driving condition to prevent automatic retraction of the seatbelt.

The present invention is a vehicle control device including a restriction unit configured to restrict a change in an orientation of a vehicle seat, a vehicle information recognition unit configured to recognize information of a traveling environment of a vehicle, a risk evaluation unit configured to evaluate a risk of a collision which may occur in the vehicle on the basis of the traveling environment recognized by the vehicle information recognition unit, and a control unit configured to control the restriction unit and restrict the change in the orientation of the vehicle seat on the basis of a level of the risk of the collision evaluated by the risk evaluation unit.

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 control device for a vehicle seat belt, includes: a retraction unit that is configured to retract a seat belt through use of a driving force of a motor and to stop retracting the seat belt when the motor is stopped from being driven; an acceleration measurement unit that is configured to measure an acceleration of a vehicle; a state detection unit that is configured to detect whether or not the vehicle is in a stable state while running; and a control unit that is configured to stop driving the motor when the acceleration measured by the acceleration measurement unit during driving of the motor has remained lower than a first set acceleration for at least a first set time and the vehicle has remained in the stable state detected by the state detection unit for at least a second set time.

A collision detection unit corrects a threshold value to a larger value, which a collision check unit uses to compare an output value of a collision detection unit, in case of a rough road surface than in case of a flat road surface. Thus, it becomes possible to suppress erroneous detection on the rough road surface while detecting a collision sensitively on a flat road surface. The rough road is detected by a vibration detection unit provided in a tire side device.

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 vehicle turn-over determination apparatus includes a turn-over sensor, a memory, a determination processor, and a road-surface detector. The turn-over sensor detects a value of a turn-over angle or a turn-over velocity of a vehicle. The determination processor performs the determination of the turn-over of the vehicle on the basis of the value detected by the turn-over sensor and the determination-threshold information held in the memory. The road-surface detector detects a road surface that is present in a traveling direction of the vehicle. The determination processor varies the determination-threshold information acquired from the memory in accordance with an inclination of the road surface detected by the road-surface detector, and thereby generates adjusted-threshold information adjusted in accordance with the inclination of the road surface. The determination processor compares the adjusted-threshold information and the detected value with each other, and thereby perform the determination of the turn-over of the vehicle.