A profile for an occupant is stored. The profile includes a plurality of clusters of sitting positions for the occupant in a seat and classifications of respective clusters as preferred or nonpreferred. Respective clusters are classified as preferred or nonpreferred based on sitting scores for the respective sitting positions in that cluster. A higher sitting score increases a likelihood of the classification being preferred. A series of pressure maps indicating a respective series of sitting positions of the occupant in the seat are received. The pressure maps include a current pressure map. One of the sitting positions is assigned to one of the clusters that is classified as preferred in response to the sitting score of that sitting position being greater than a threshold score. A physical configuration of the seat is adjusted in response to the current sitting position being in one of the clusters that is classified as nonpreferred.

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 method for determining the occupancy status of a seat of a motor vehicle, the method being implemented by a determination system comprising a seat, six interdigitated capacitive sensors, and a controller comprising a reference capacitance value and a threshold value for each interdigitated capacitive sensor, the method comprising a step of measuring three capacitance values for each interdigitated capacitive sensor, the following steps being implemented by the controller for the measured capacitance values: calculating a resulting capacitance value based on the measured capacitance values, calculating the difference between the resulting capacitance value and the reference capacitance value, comparing the calculated difference to the threshold value, determining the occupancy status of the seat, based on the result of the comparison.

Systems, devices, and techniques are provided for occupancy assessment of a vehicle. For one or more occupants of the vehicle, the occupancy assessment establishes position and/or identity for some or all of the occupant(s).

A vehicle seating system is described that can detect and optionally quantify a drowsiness state and/or and emotional state of a seat occupant in the vehicle. A seat is mounted in a vehicle and houses a wireless electromagnetic sensing system at least partially integrated into the seat. These sensed signals can be used to determine the occupant's state. When the state exceeds a threshold, then wireless stimulation emitters output a stimulation signal to the occupant to alter the emotion state or drowsiness state to move the occupant to below the threshold and to a calm state or an alert state. The system can also use additional physiological sensor to measure at least one of a heart rate, a respiration rate, or both of the occupant to be used with the electromagnetic sensing at the seat.

A capacitance measurement circuit for determining a sense current of a capacitive sensor with a sense electrode and a guard electrode. The measurement circuit includes a periodic signal voltage source, a sense current measurement circuit configured for determining the sense current with reference to a reference voltage, and at least one remotely controllable switch member. In a first switching state, the at least one switch member electrically connects the sense current measurement circuit to the periodic signal voltage source for providing a first reference voltage, and in a second switching state, the at least one switch member electrically connects the sense current measurement circuit to a second reference voltage that is different from the first reference voltage.

A system for detecting the presence of an occupant of a seat. The system includes a sensing mat that includes an upper conducting layer and a lower conducting layer. At least one of the conducting layers comprises a printed electronic circuit separated into conductive zones by at least one resistive zone. The mat also includes a plurality of sensing zones and each of the sensing zones include a conductive zone from the upper conducting layer and a conductive zone from the lower conducting layer. Each of the conducting layers are connected to a controller configured to detect a change in capacitance of each of the sensing zones resulting from a change in distance between the upper conducting layer and the lower conducting layer. The controller is connected to a vehicle network and is configured to provide data to the network that indicates the absence or presence of the occupant.

According to various implementations, a sensor mat includes a mat substrate, a sensor electrode, and a shield electrode. At least a portion of the sensor and shield electrodes are spaced apart from and parallel to each other on a first surface of the mat substrate. The shield electrode is electrically coupled to a voltage source to create a capacitance between the shield electrode and the sensor electrode, and the sensor electrode is used to detect a change in the capacitance. The shield electrode may also be alternately used for heating the surface of the vehicle part adjacent the mat. For example, the sensor may be disposed adjacent a portion of a steering wheel or a seat assembly and is used for sensing presence of an occupant's hands or body adjacent the steering wheel or seat assembly.

Aspects of the disclosure relate to apparatus and methods for unattended occupant protection system (UOPS) safety systems for passenger vehicles. The UOPS safety system may include a UOPS module. The module may be integrated with a vehicle data bus of the passenger vehicle. The module may be in communication with a plurality of UOPS sensors. The module may launch an equalization mode in response to determining, via the UOPS sensors, the presence of an unattended occupant in the passenger vehicle with a high or rising ambient temperature. The equalization mode may stabilize the ambient temperature of the passenger vehicle.

A computing device in a vehicle can be programmed to receive an occupant position measurement from at least one of an acoustic and a light sensor, determine an estimated occupant size based on occupant weight, estimate a vehicle seat position based on the occupant position measurement, and, control a vehicle occupant safety device based on the estimated occupant size and estimated vehicle seat position.