A system and method for deciphering signals and messages from a control unit, and mapping those signals to the associated sensors to create a map of the sensor status. The map of the sensor status is then used in conjunction with a dongle and software application to interface with the control unit, able to receive messages from the control unit to monitor the status of the sensors, and to send messages to the control unit to manipulate the sensors. The system and method can further be used to interface with the electronic control unit of a vehicle to detect unattended access of the vehicle and ensure no passengers are left abandoned in the vehicle, such as by sending alerts to a mobile device of the user, triggering alarms in the vehicle, or sending alerts to emergency services.

Apparatus, device, methods and system relating to a vehicular telemetry environment for monitoring vehicle components and providing indications towards the condition of the vehicle components and providing optimal indications towards replacement or maintenance of vehicle components before vehicle component failure.

An electrically adjustable seating device includes at least one sensor element, a processor, a memory unit and at least one electromechanical actuator. The at least one sensor element is designed to detect predetermined seating parameter data relating to a person sitting on the seating device and to transmit the data to the processor. The processor is designed to determine person parameter data, relating to the person, from the seating parameter data, to extract control data, which are associated with the person parameter data, from the memory unit and to control the at least one electromechanical actuator on the basis of the control data.

A vehicle seat occupancy detection system includes at least one capacitive sensor member having at least one sensing electrode, an impedance measurement circuit for determining a complex impedance or a complex admittance of the at least one sensing electrode, an evaluation unit for generating an output signal based on a determined complex admittance of the at least one sensing electrode and comparison of the determined complex admittance to at least one predetermined value, and at least one electrically conductive ground connecting member that is intentionally electrically connected to the reference electrode and that is arranged in close proximity to the at least one sensing electrode. The at least one ground connecting member and the at least one sensing electrode are galvanically separated such that, when the seat gets wet, the sensing electrode is directly electrically connected to the reference electrode by the at least one ground connecting member.

A device (1) for temperature control and for recognizing an occupation of certain areas by a person and/or an object are disclosed. The device includes at least one electrically conductive heating line (23) that is designed for releasing heat energy, and at least one electrode (3, 5) adjoining the at least one electrically conductive heating line (23), the longitudinal axis of the electrode extending, at least in sections, along the at least one heating line. The at least one electrode (3, 5) is mechanically coupled to the at least one heating line (23), and is designed as a component of a capacitive sensor system, by means of which a presence of persons and/or objects within a certain area is determinable.

A capacitive sensor member of a seat occupant classification device for use in seats, in particular in vehicle seats. The capacitive sensor member includes at least one electrically conductive sense electrode that has an optimized shape for use in vehicle seats equipped with child restraint system anchorages. A capacitive seat occupant classification system is provided that includes the capacitive sensor member.

Systems, methods, tangible, non-transitory computer-readable media, and devices for configuration of a vehicle compartment are provided. For example, a method can include receiving, by a computing system, occupancy data based in part on one or more states of one or more objects. Based in part on the occupancy data and compartment data, a compartment configuration can be determined for one or more compartments of an autonomous vehicle. The compartment data can be based in part on a state of the one or more compartments. The compartment configuration can specify one or more spatial relations of one or more compartment components associated with the one or more compartments. One or more configuration signals can be generated based in part on the compartment configuration to control the one or more compartments of the autonomous vehicle.

Described are seat units with a seat pan (2) coupled to a seat back (3), inflatable cushions (5) positioned proximate the seat pan and/or the seat back, inflatable airbags (6) positioned proximate the inflatable cushions (5), and a pressure sensor (9) positioned over at least one of the seat pan (2) and the seat back (3) so that the inflatable cushions (5) and the inflatable airbags (6) are substantially covered by the pressure sensor (9). The pressure sensor (9) is configured to generate a pressure map, and a control unit (11) is configured to analyze the pressure map for at least one pressure irregularity within a pressure distribution, and adjust a pressure inside at least one of the inflatable cushions (5) and/or the inflatable airbags (6) to minimize the pressure irregularity within the pressure distribution.

Various systems and methods for providing an occupant profiling system are described herein. A system for profiling a vehicle occupant includes a vehicle control system, comprising: a sensor fusion circuit coupled to a plurality of sensors installed a vehicle seat, the sensor fusion circuit to: determine that a human occupant is seated in the vehicle seat; sample a backrest sensor arrangement and a base cushion sensor arrangement of the vehicle seat to obtain backrest sensor data and base cushion sensor data, when the human occupant is determined to be seated in the vehicle seat; sample, when the human occupant is determined to be seated in the vehicle seat, a height sensor to obtain a height sensor value; and statistically determine from the backrest sensor data, the base cushion sensor data, and the high sensor data, whether the human occupant matches a reference profile.

An automatic display adjustment system for a vehicle may include a controller coupled to a display and at least one motor for adjusting the display. The controller may be configured to detect a seat-back angle of a seat occupied by an occupant and determine a display angle based on the detected seat-back angle. The controller may be further configured to generate a control signal to actuate at least one motor for adjusting the display according to the determined display angle.