A vehicle seating assembly comprises a seat including a back having an array of at least two electrodes arranged in the back such that a master electrode has an electric field being greater than an electric field of each of the other electrodes within the array to detect a total change in capacitance from the array. A controller is responsive to a change in capacitance calculated from the master electrode being greater than a first threshold and each of the other electrodes in the array being greater than a second threshold and outputs occupant movement data indicative of a first status of the seat to a vehicle control sub-system.

A vehicle seating assembly comprises a seat including a back having an array of at least two electrodes arranged in the back such that a master electrode has an electric field being greater than an electric field of each of the other electrodes within the array to detect a total change in capacitance from the array. A controller is responsive to a change in capacitance calculated from the master electrode being greater than a first threshold and each of the other electrodes in the array being greater than a second threshold and outputs occupant movement data indicative of a first status of the seat to a vehicle control sub-system.

Systems and methods for using image analysis techniques to facilitate adjustments to vehicle components are disclosed. According to aspects, a computing device may access and analyze image data depicting an individual(s) within a vehicle, and in particular determine a positioning of the individual(s) within the vehicle. Based on the positioning, the computing device may determine how to adjust a vehicle component(s) to its optimal configuration, and may facilitate adjustment of the vehicle component(s) accordingly.

Systems and methods for using image analysis techniques to facilitate adjustments to vehicle components are disclosed. According to aspects, a computing device may access and analyze image data depicting an individual(s) within a vehicle, and in particular determine a positioning of the individual(s) within the vehicle. Based on the positioning, the computing device may determine how to adjust a vehicle component(s) to its optimal configuration, and may facilitate adjustment of the vehicle component(s) accordingly.

A vehicle seat occupancy classification system having at least one weight-responsive sensor, including a supporting plate, a collecting plate, a hinge member mechanically connecting the supporting plate and the collecting plate, at least one elastic spring member, and a position sensor that is configured to determine a gap dimension between the supporting plate and the collecting plate. The occupancy seat classification system includes an evaluation unit that is configured to receive the output signal from the position sensor and to provide a seat occupant classification based on a level of the received output signal and at least a first pre-determined threshold value of the output signal.

A method for sensing occupancy status within an automotive vehicle uses a radar sensor system having an antenna system, at least one sensor and processing circuitry. The method comprises: illuminating, using the antenna system, at least one occupiable position within the vehicle with an outgoing radar signal; receiving, using at least one sensor, at least one sensor signal reflected as a result of the outgoing radar signal; obtaining accelerometer data value from at least one accelerometer, the accelerometer data containing information regarding vibration or motion of the automotive vehicle and supplying the accelerometer data to the processing circuitry; and operating the processing circuitry for generating, based on the at least one sensor signal and on the accelerometer data, one or more occupancy status signals, the occupancy status signal indicating a property related to the at least one occupiable position.

A safety system for a vehicle seat in a commercial vehicle operating a vehicle seat motion actuation when the commercial vehicle is colliding with an obstacle, comprising: at least one actuator unit that comprises at least one seat actuator to move the vehicle seat from a driving position to a safety position at least one control unit connected to said actuator unit to control the at least one N seat actuator at least one proximity sensor connected to said control unit and configured to detect an obstacle before the commercial vehicle collides it characterized in that the control unit is provided with a calculator device retrieving specific data (Dw, Dw′, Ds, Do) to determine the requested seats motion speed profile and the requested seats motion triggering moment to control, upon receiving an imminent and unavoidable collision alert signal from the proximity sensor, the at least one seat actuator to move the vehicle seat to the safety position.

An occupant protection apparatus includes: an airbag configured to be stored in a head rest or a seat back of a vehicle seat, and the airbag being formed as a single bag that is configured to cover a head of an occupant and including a front inflating part and a right and left pair of lateral inflating parts; a three-point seat belt device including webbing equipped with a lap belt and a shoulder belt, and a belt take-up mechanism, and the belt take-up mechanism applying tension to the webbing; and a control unit that, in the event that an impact to the vehicle has been predicted or detected, activates the belt take-up mechanism before inflating and deploying the airbag.

A suspension mat (14) for a vehicle seat comprises one or more suspension springs (16) for supporting a cushion (28), a support plate (18) attached to the one or more suspension springs, a mobile plate (34) coupled with the support plate, a flat spring (26) arranged between the support plate and the mobile plate and a switch element. The mobile plate is arranged movable between a first and a second position relative to the support plate. The flat spring biases the mobile plate toward the first position. The switch element is located between the support plate and the flat spring, in such a way that when the mobile plate moves against a bias of the flat spring toward the second position, the flat spring presses and actuates the switch element. The flat spring may e.g. comprise a washer spring, a plate spring, a dome-shaped flat spring and/or a cantilever flat spring.

A wireless tension adjusting system of a hand parking brake includes: a nut runner fastened to an that adjusts nut adjusting tension which is present in a parking brake cable, the nut runner being configured to apply rotational force to the adjusting nut; an external force measuring jig configured to measure external force of a parking brake lever caused by the rotational force applied to the adjusting nut from the nut runner; and a controlling unit configured to transmit an operation stop signal to the nut runner based on the external force which is measured by the external force measuring jig.