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.

Systems and method are provided for controlling a vehicle. In one embodiment, a method for determining the state of a restraint system provided within a vehicle includes incorporating one or more marker components into a restraint system component located within the vehicle, then receiving sensor data associated with the position of one or more of the marker components. The method further includes determining, with a processor, a state of the restraint system based on the sensor data.

A seatbelt payout measuring device with a rewind spring having a first end connected to a center spool and a second end connected to a rewind spring housing. A dielectric material layered immediately adjacent to the rewind spring forming a first layer and an electrolytic coil with dielectric material layered on both sides forming a second layer, isolating the rewind spring from the electrolytic coil. A capacitive measuring device having a first lead connected to the first end of the rewind spring and a second lead connected to a first end of the electrolytic coil. The capacitive measuring device measuring capacitance with belt pullout.

A computer that may be programmed to: in response to receiving an indication that a vehicle is approaching a geofence boundary, retract slack in a webbing associated with a seat in the vehicle by actuating a seatbelt retractor; then receive measurement data from one or more sensors associated with the seat; using the data, determine whether an occupant occupies the seat; and when no occupant occupies the seat, then transmit an instruction to stop the vehicle.

A plus-two-point belt system is disclosed. The plus-two-point belt system includes a longitudinal webbing anchored at a first end to a seat and fixed at a second end to a retractor. The webbing is extendable from the retractor to allow an occupant to slip their arm under the webbing to provide a supplemental restraint. The webbing includes first and second portions where the second portion is retractably coiled on the retractor and the second portion has at least one conductive marker. A sensor is provided to sense the marker and a processor is provided to set an alarm when the marker is not detected.

A belt assembly includes a belt, a first sensor and a second sensor. The belt has a webbing and a plurality of markers distinct from the webbing and fixed thereto. The markers are equally spaced a first longitudinal distance thereon in a longitudinal direction. The first sensor and the second sensor each have an associated detection field directed toward the belt and responsive to the markers in the fields. The second sensor is a second longitudinal distance from the first sensor differing from the first distance.

A method for monitoring a passenger compartment of a vehicle. The passenger compartment has at least one RFID transponder. A readout signal for reading out the RFID transponder is emitted in the method. In response to the emitting, a response signal of the RFID transponder is measured in order to obtain a measured value. Using the measured value, a degree of obscuration that represents an obscuration of the RFID transponder is ascertained in order to monitor the passenger compartment.

A seatbelt system may include a seatbelt configured to constrain a waist and a torso of an occupant. The seatbelt may also include a coupling configured to selectively couple a portion of a vehicle and the seatbelt to one another. The system may also include a reel configured to receive at least a portion of the seatbelt, and a tension sensor associated with the coupling and/or the seatbelt and configured to generate a signal indicative of tension in the seatbelt. The system may also include a deployment sensor associated with the seatbelt and configured to generate a signal indicative of a length of the seatbelt deployed from the reel. The system may also include an occupant detector configured to determine, based at least in part on the signals indicative of tension and the length, whether an occupant is properly wearing the seatbelt, such that the seatbelt constrains the occupant.

Method for controlling a vehicle including a smartphone-engaging coupling element. Data about operational status of the vehicle is transferred from one or more vehicle-resident systems to a smartphone when the smartphone is engaged with the coupling element. Commands are received by the vehicle from the smartphone when the smartphone is engaged with the coupling element, which commands being based in part on data previously transferred from the vehicle-resident system(s) to the smartphone when the smartphone is engaged with the coupling element. A vehicular system, e.g., seat positioning system, mirror positioning system, passenger compartment temperature control system, route guidance or navigation system, changes its operation in accordance with the commands received by the vehicle from the smartphone when the smartphone is engaged with the coupling element.