A method for controlling a motor vehicle having an electronic control unit (ECU), includes enabling an initial set of vehicle performance limits of the motor vehicle via the ECU in response to a request signal from a computer device. The method includes detecting a current vehicle state of the motor vehicle, including one or more of a location of the motor vehicle, an occupancy state of the motor vehicle, and/or an experience level of a driver thereof, and dynamically adjusting at least one of the performance limits in response to the current vehicle state. A motor vehicle includes one or more road wheels and vehicle components connected to a vehicle body. The ECU includes non-transitory memory on which is recorded instructions for performing the method.

A harness buckle locking assembly for a buckle of for a car seat includes an On-Board Diagnostics (OBD) device, comprises a first transceiver and is configured to operationally engage an OBD II port of a vehicle, and a housing, which is positionable over a release button of a buckle of a car seat. A depressible button is attached to a pin and can be depressed to actuate the release button. A lock unit selectively locks the pin within the housing. An electronics unit is operationally engaged to the lock unit and communicates with the OBD device and with an electronic device of a user. The electronics unit can signal the user of occupancy of the car seat, when the vehicle has been turned off for a preset time, and also can selectively actuate the lock unit to unlock the pin.

An apparatus including a sensor and a control unit. The sensor may be configured to determine seat orientation information. The control unit may comprise an interface configured to receive the seat orientation information. The control unit may be configured to analyze the seat orientation information, determine when to deploy a corrective measure and modify the corrective measure in response to the seat orientation information. The control unit may deploy the corrective measure using a default arrangement in a first mode. The control unit may deploy the modified corrective measure in a second mode.

A passenger protection apparatus includes: a seat belt including a shoulder belt ; an anchor disposed on one side of a seat to hold one end of the seat belt; a buckle disposed on the other side; a tongue that can hold part of the seat belt; a first activation member that reels and unreels the shoulder belt; a first detector that detects or predicts a collision of the vehicle; a second detector that detects a change in a sitting state of the passenger; and a controller that controls activation of the first activation member. When the first detector detects or predicts a collision of the vehicle, the controller controls the first activation member to reel, and stop reeling or unreel the shoulder belt. The controller controls the first activation member to reel the shoulder belt again, based on the change in the sitting state detected by the second detector.

A method for controlling an actuatable safety device for protecting an occupant of a vehicle includes utilizing an advanced driver assistance system (ADAS) to determine that a vehicle collision is impending. In response to determining the existence of an impending vehicle collision, a mass spring damper model uses sensed vehicle longitudinal acceleration (IMU_X) to estimate the occupant movement that will result from the impending vehicle collision. The estimated occupant movement is used to determine how to control deployment of an actuatable safety device in response to the crash.

A method for adapting a triggering algorithm of a personal restraint device of a vehicle on the basis of a detected vehicle interior state of the vehicle. The method comprises detecting of key points of a vehicle occupant by an optical sensor device, ascertaining a vehicle occupant posture of the vehicle occupant based on the connection of the detected key points to a skeleton-like representation of body parts of the vehicle occupant, wherein the skeleton-like representation reflects the relative position and orientation of individual body parts of the vehicle occupant, predicting a future vehicle occupant posture of the vehicle occupant based on a predicted future position of at least one of the key points, and modifying the triggering algorithm of the personal restraint device based on the predicted future posture of the vehicle occupant. A control device for adapting a triggering algorithm of a personal restraint device is also disclosed.

A restraint system includes a housing, a spool rotatably coupled to the housing, and an actuator fixed relative to the housing. The spool has a base plate with holes. The holes are spaced from each other circumferentially about the spool. The actuator has a pin movable between an engaged position extending into one of the holes and a disengaged position spaced from the holes.

A front airbag for vehicles including an airbag cushion may include a rear panel located at the side of a steering wheel and a front panel located at the side of a passenger and having a shape corresponding to the shape of the rear panel, the rear panel and the front panel provided with protruding supports formed at both sides of the lower end portions thereof, a first tether connecting the central part of the front panel, corresponding to a loading position of the passenger's head, to an airbag housing, and second tethers connecting the lower end portion of the front panel, corresponding to a loading position of the passenger's chest, to the airbag housing and having a shorter length than that of the first tether.

A vehicle seat installed with a vehicle occupant restraining device, the vehicle seat includes: a seat cushion frame including a seat cushion side frame; a seatback frame supported swingably about a reclining rod and including a seatback side frame; an engaging portion disposed at a seat rear end side of the seat cushion side frame and at a seat lower side relative to the reclining rod, and protruding toward a seat transverse direction inner side; a first movable member disposed along the seatback side frame, a lower end portion of the first movable member being extended to position at a seat front side of the engaging portion; and a first driving member configured to extend the first movable member in a case in which a vehicle collision at a seat front side occurs or a vehicle collision at the seat front side is predicted.

A method of controlling an active seatbelt includes checking whether a seatbelt is fastened, collecting driving information from a sensor or driving assist/safety system installed in a vehicle, determining a safety state of the vehicle based on the driving information, checking whether an airbag is deployed, and outputting a motor control signal for restraint control of the seatbelt in response to the safety state when the airbag is not deployed.