A method for a seat belt system (10) in a vehicle (14), wherein the seat belt system (10) comprises an extendable seat belt (18), a webbing extension measuring device (30) and a control unit (36), includes the steps of: a) determining the webbing extension by means of the webbing extension measuring device (30), b) determining whether a locking tongue (22) is connected to a belt buckle (24), c) determining whether the webbing extension is above a threshold.

Moreover, the invention provides a seat belt system (10) for a vehicle (14) comprising an extendable seat belt (18) and a vehicle (14) comprising a seat belt system (10).

An autonomous driving controller includes: a processor to collect driving data when a vehicle is traveling and calculate a steering override reference value, which is a criterion of determining an override mode, based on the collected driving data; and a storage to store the collected driving data and a set of instructions executed by the processor to calculate the steering override reference value. In particular, the processor controls autonomous driving by varying the steering override reference value based on the collected driving data or information regarding a driver of the vehicle.

A method for sensing the webbing extension of a seat belt (12) from a webbing retractor (10) of a vehicle includes sensing the position of the magnet (18) by means of the magnetic field sensor (20) by the control unit (22). The control unit (22) detects when the magnet (18) has completed a full turn. The control unit (22) deposits the number of the full turns in a memory (26). The control unit (22) determines the webbing extension by way of number of the full turns and the position of the magnet (18). A webbing retractor (10) for a seat belt (12) has a magnet (18).

A system for detecting improper usage of a seatbelt of a vehicle includes a vehicle seat having a seat cushion and a seat back. A shoulder belt and a lap belt are intended to restrain an occupant sitting on the vehicle seat. The system includes a sensor module associated with the shoulder belt and the lap belt. The sensor module generates signals indicative of at least one parameter associated with the vehicle seat, the shoulder belt, and the lap belt when the occupant is sitting on the vehicle seat. The system also includes a controller that receives the signals indicative of the at least one parameter associated with the seat back, the shoulder belt, and the lap belt. The controller analyzes the received one or more signals, and determines whether the seatbelt is being used improperly by the occupant, based on the analysis.

A seat belt system (10) has a control unit (14) and a seat belt (16) which includes a webbing (18) and a belt retractor (20). The belt retractor (20) comprises a belt reel (28) for the webbing (18), a rotation angle sensor (30) with a sensor unit and a rotatable measuring element, and a gear unit coupling the belt reel (28) to the measuring element. The belt reel (28) has a fully extended position and a ghost position. Furthermore, the gear unit is designed so that the gear unit reduces the rotation of the belt reel (28), when the belt reel (28) is adjusted from the ghost position to the fully extended position, to a maximum of 1.0 revolutions of the measuring element. In addition, a method for determining the extension length of a webbing (18) of a seat belt system (10) wound on a rotatable belt reel (28) is provided.

A system includes a seat belt routing module and a user interface device (UID) control module. The seat belt routing module is configured to: determine a routing of a seat belt relative to an occupant in a vehicle seat based on input from a webbing payout sensor; and determine the seat belt routing based on an input from an in-cabin sensor. The in-cabin sensor includes at least one of a camera, an infrared sensor, an ultrasonic sensor, a radar sensor, and a lidar sensor. The UID control module is configured to control a user interface device to indicate that the seat belt is being worn improperly when: the seat belt routing determined using at least one of the webbing payout sensor and the in-cabin sensor is improper; and the seat belt routing determined using the webbing payout sensor corresponds to the seat belt routing determined using the in-cabin sensor.

In a method for identifying misuse of a seat belt in a vehicle, vehicle data are detected and, based on said data, a plausibility check is performed for determining whether the seat belt is fastened as intended. Signals of at least one belt buckle sensor and of at least one webbing extension sensor are detected and a plausibility check for misuse is performed by taking the time course of the signals and/or the point in time of input of the signals into account so as to make a comparison with stored reference data. A seat belt system in a vehicle for carrying out said method comprises at least one belt buckle sensor and at least one webbing extension sensor as well as at least one seat occupation sensor, one door sensor, one vehicle acceleration sensor and/or one vehicle speedometer as well as a control unit in which the signals of the sensors are stored and evaluated.

The subject disclosure relates to techniques for detecting proper use of a seatbelt in a vehicle. A process of the disclosed technology can include steps for receiving, from a sensor, image data of one or more portions of a seatbelt. The process can further include steps for determining a length of the seatbelt that is dispensed based on the image data and determining if the seatbelt is buckled in front of a passenger's body based on the length of the seatbelt that is dispensed. Systems and machine-readable media are also provided.

System and method for obtaining and recording information about cargo includes a frame defining a cargo-receivable compartment, a position determining system at least partly on the frame and that allows for determination of position of the frame, an identification system on the frame that obtains information about cargo when present in the compartment, a memory component that receives and records information about position and movement of the frame, and the obtained information about cargo when present in the compartment in association with a unique identification of the frame, and a communications system on the frame to enable communication of information to and from the memory component.

A belt assembly includes a belt retractor, a sensor having a detection field, and a belt retractably payable from the belt retractor through the detection field. The belt has a webbing and a plurality of markers fixed to the webbing. The webbing has a longitudinal length and the markers are equally spaced along the longitudinal length of the webbing. The sensor senses the length of the webbing paid out. A size of the occupant may be determined based on the length of the webbing paid out, and the size of the occupant may be used to classify the occupant in classes.