A method for a vehicle includes using sensors in a vehicle seat to detect biometrics of a person sitting in the seat and a vehicle controller determining from the biometrics of the person whether the person requires medical attention. In response to the person requiring medical attention, a request for assistance for the person is broadcasted via a V2X transceiver of the vehicle to medical practitioners of a medical practitioner network who are near a location of vehicle during the broadcasting. The medical practitioner network includes the person as a subscriber and medical practitioners as providers. Alternately, in response to the person requiring medical attention, the vehicle controller uses an autonomous vehicle control system of the vehicle to drive the vehicle to a medical facility.

Various implementations include a vehicle component heating system that includes an electrode disposed within a sensing zone, and a processor. The electrode generates heat for a surface of a vehicle component within the sensing zone and senses proximity of an occupant to the sensing zone. The processor selects a heating percentage of a duty cycle for generating a heating signal, a sensing percentage of the duty cycle for generating and measuring a sensing signal and reporting the measured sensing signal, and an idle percentage of the duty cycle during which neither the heating nor the sensing signal is generated, wherein the sum of the heating, sensing, and idle percentages is 100%. The processor generates the heating signal and/or generates and measures the sensing signal and reports the measurement of the sensing signal based on the selected percentages.

An autonomous vehicle (AV) can receive a pick-up location to rendezvous with a rider and a set of configuration instructions to configure one or more adjustable components of the configurable interior system for the rider. The AV can analyze sensor data to autonomously control acceleration, steering, and braking systems along a route to the pick-up location. Prior to arriving at the pick-up location, the AV can execute the set of configuration instructions to configure the one or more adjustable components of the configurable interior system for the rider.

The disclosed method is stored as computer readable instructions and carried out by a processor that is part of a disclosed occupant monitoring system (OMS). The method starts with the receipt of an external signal by the processor. The external signal can be the starting of the vehicle engine, an indication of semi-autonomous or autonomous driving mode, or an indication that the occupant is seated, is in contact with a steering wheel, and/or is in contact with at least one dashboard control. The receipt of the external signal causes the processor to capture an image, analyze the image to determine if at least one monitoring condition is met, generate an adjustment signal if the monitoring condition is not met, and communicate the adjustment signal to at least one VCS, and repeating the monitoring loop. In some implementations, multiple images are captured and analyzed during the cycling of a monitoring loop.

A vehicle seat operation feedback and control system with a seat and an electronic display screen and a processor configured to receive a signal from the seat corresponding to an inoperable, almost inoperable, or undesired condition and provide feedback on the display screen of the inoperable, almost inoperable, or undesired condition.

A system includes a computer programmed to receive data describing one or more vehicle operations from one or more vehicle input device. The computer actuates an output device upon determining, based on the received data, that a seat-change condition is met.

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.

A vehicle detection system includes an RFID reader, a detection device, and an ECU. The RFID reader transmits a transmission signal including at least a signal that supplies power. The detection device includes a second antenna unit that mutually transmits and receives a signal to and from the RFID reader, an RFID detection circuit that is activated using the signal that supplies power included in the transmission signal received by the second antenna unit as driving power and that outputs a detection signal to the second antenna unit, and a switch circuit that switches an electrical connection portion between the second antenna unit and the RFID detection circuit to a contact state or to a non-contact state according to a state inside the vehicle. The ECU determines the state inside the vehicle on the basis of the detection signal received by the RFID reader.

A condition correction unit includes a plan storage unit configured to store correction plans showing contents of correction of the body condition of a seated person, a presentation unit configured to read a correction plan based on a current value measured by a measurement unit from the plan storage unit and present the correction plan to the seated person, and a processing execution unit configured to execute processing to correct posture by controlling an operating unit. The plan storage unit stores the correction plan presented by the presentation unit in association with information identifying the seated person when the correction plan is presented. The processing execution unit reads the correction plan associated with the information identifying the seated person from the plan storage unit, and executes the processing to correct the posture according to correction contents shown by the correction plan.

Disclosed is a control device for comfort equipment for a seat module in a passenger transport vehicle. The control device includes a control unit capable of transmitting adjustment commands to a piece of comfort equipment, and one imager capable of acquiring one image representing a part of the body of a passenger resting on a seat. The control unit communicates with the imager to receive the one acquired image. The control unit is capable of detecting an object in the image representing a part of the passenger's body and generating one adjustment command to be sent to the comfort equipment as a function of the detected part of the passenger's body.