An occupant feature detection method and system, and a computer-readable medium, where the method includes: inflating a seat cushion airbag (10) with a gas of a first predetermined volume, and measuring a reference pressure formed by the gas of the first predetermined volume when no occupant is seated; measuring a first pressure formed by the gas of the first predetermined volume after an occupant is seated; and obtaining a first weight based on a difference between the reference pressure and the first pressure, and using the first weight as a reference weight of the occupant. The seat cushion airbag (10) disposed in the vehicle seat is used to calculate the weight of the occupant and determine a sitting position of the occupant based on the difference between the pressure in the seat cushion airbag (10) obtained when no occupant is seated and the pressure in the seat cushion airbag obtained when the occupant is seated. Therefore, a feature of the occupant may be identified without additionally providing a pressure sensor, so that a targeted protection strategy is set for each occupant.

A motor vehicle includes a structural element and a seat having at least two separate and independent seat portions, each of the seat portions being configured to support a part of a user's body and being independently coupled to the structural element in a movable manner relative to the structural element with three degrees of freedom including two translations in a plane along respective orthogonal axes and a rotation around a further axis orthogonal to said plane.

Disclosed are a shoulder airbag and a method of controlling deployment thereof that are capable of adjusting the amount of inflation of chambers covering an occupant's shoulders depending on the body type of the occupant and/or the collision direction of a vehicle, thereby safely protecting the occupant in various collision situations. The shoulder airbag includes an occupant detection sensor configured to detect the posture and body type of an occupant, an airbag cushion including chambers configured to be inflated and deployed so as to cover the front, side, and upper portions of each of the shoulders of the occupant, and a controller configured to variably control the amount of inflation of each of the chambers covering the front, side, and upper portions of each of the shoulders of the occupant based on occupant information analyzed based on the posture and body type of the occupant when a collision accident occurs.

Provided are a vehicle electric seat (10) adjustment method, apparatus, and system, and a vehicle. The method includes: obtaining, in response to a position adjustment instruction for an electric seat (10), an image of a seat at a direct rear side of the electric seat (10) that is currently captured by a camera system (12) disposed on the electric seat (10); analyzing, whether the seat at the direct rear side is occupied by a passenger; when the seat at the direct rear side is occupied by the passenger, calculating, based on the image, a current distance of the electric seat (10) relative to the passenger on the seat at the direct rear side, and obtaining a predetermined seat adjustment safety distance; calculating a position adjustment parameter of the electric seat (10); and adjusting a position of the electric seat (10) based on the position adjustment parameter, to a target position.

A sensing system determines movement and position of passengers and objects within a vehicle. In particular, the determination of the position and movement of body parts can be enhanced by providing features that provide a source of ground for the system. The sensing system is able to transmit a plurality of signals during a transmission period and use the sensed signals during a frame in order to create different heat maps that represent movement and position of person during an integration period. By taking advantage of grounding sources, the system is able to better determine the position and movement of a person or object.

A service providing apparatus includes a detector provided on a seat and configured to detect a motion of a user seated on the seat; a control device including a processor and a memory coupled to the processor, having a plurality of service functions and configured to determine a service content in the plurality of service functions based on the motion detected by the detector and a presentation unit configured to present the service content determined by the control device.

The present disclosure relates to a mat for detecting the occupancy of a motor vehicle seat, comprising a flexible support, an interdigitated capacitive sensor borne by the flexible support, a first conductive track borne by the flexible support, the first conductive track having a first end connected to the interdigitated capacitive sensor and a second end intended to be connected to a computing unit, a second conductive track borne by the support, the second conductive track having a first free end and a second end intended to be connected to the computing unit. The present disclosure also relates to a system for determining a capacitance, a method for determining a capacitance or a state of occupancy of a seat and a method for detecting a rotation of a part of the trunk of an occupant seated on a seat

An occupant detection apparatus includes a first camera and a second camera. The first camera is arranged in a passenger compartment of a vehicle to capture images within a first field of view in the passenger compartment. The second camera is arranged at a different position in the passenger compartment from the first camera to capture images within a second field of view in the passenger compartment. The second field of view is different from the first field of view. Moreover, the first camera is arranged within the second field of view which is the field of view of the second camera. On the other hand, the second camera is arranged within the first field of view which is the field of view of the first camera.

Various implementations include seats and related systems for detecting user proximity and controlling one or more functions based on that proximity detection. In particular cases, the seats include an upper seat section with at least one two-dimensional (2D) contrast indicator that is detectable by a sensor system to indicate a position of the upper seat section.

A system for detecting a vehicular crash may (i) receive data from said at least one sensor; (ii) determine that a potential vehicular crash is imminent based upon the received data; and/or (iii) transmit one or more high priority packets including a notification that the potential vehicular crash is imminent. As a result, the speed and accuracy of detecting an imminent vehicular crash is increased. The system may also utilized vehicle occupant positional data, and internal and external sensor data to detect potential imminent vehicle collisions, take corrective actions, automatically engage autonomous or semi-autonomous vehicle features, and/or generate virtual reconstructions of the vehicle collision.