An adjustment device for the automatic seat position change in a vehicle from an actual setting into a predefinable target setting including an electronic control unit for automatically setting at least one actuator for adjusting at least one seat-position-dependent adjustable vehicle component depending on detected vehicle occupant data. In this case, the control unit has an analysis unit for determining an efficiency-oriented adjustment space requirement for the adjustment of the actual setting into the target setting depending on the vehicle occupant data and the vehicle interior geometry.

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.

A method and apparatus for automatically arranging seats of an autonomous vehicle enable seats to be remotely changed between a standard arrangement mode and a final target arrangement mode. The apparatus includes a manipulation device configured to generate a signal corresponding to a target arrangement mode of seats through manipulation by a passenger, seat motors respectively provided in the seats so as to control positions and postures of the seats, seat controllers for controlling operation of the seat motors, and a vehicle controller configured to transmit a signal from the manipulation device to the seat controllers, transmit an abnormal signal indicating jamming of the seats to the manipulation device or control the seat controllers provided in the vehicle. As a result, it is possible to easily change the seats to a desired arrangement mode in an autonomous vehicle without interference with peripheral components during movement of the seats.

A seat assembly may include a seat, a seat actuator, a sensor assembly, and an electrical control unit (ECU). The seat actuator may be configured to adjust the seat. The sensor assembly may be connected to the seat and may be configured to detect a pressure applied to the seat. The ECU may be operatively connected to the seat actuator and the sensor assembly. The ECU may be configured to reduce soft tissue stress in soft tissue of a user via adjusting the seat with the seat actuator.

An automatic adjustment of a piece of equipment of a motor vehicle is performed in response to detecting the presence of at least one person on at least one seat of the motor vehicle or detecting the absence of a person on a front passenger seat of the motor vehicle. The automatic adjustment of the at least one piece of equipment as a function of the result of the detection.

A seat assembly is provided with a seat bottom and a seat back. A first actuator is oriented in a lower lumbar region. A second actuator is oriented in an upper lumbar region. A controller is programmed to operate the first actuator to adjust the lower lumbar region, and operate the second actuator to subsequently adjust the upper lumbar region to provide a seat assembly motion pattern. A third actuator is oriented in a thoracic region or a seat bottom region. The controller operates the third actuator to adjust the thoracic region or the seat bottom region after adjusting the lumbar regions to provide a seat assembly motion pattern. A plurality of sensors is provided on the seat back and the seat bottom to initiate the pattern in response to a lack of detected occupant motion to induce muscle activation upon an occupant.

Various examples of tilting a human support surface in a vehicle are disclosed. A frame is attached to the surface of the vehicle. The vehicle also includes rotation system mounted between the frame and a vehicle surface. The rotation system can be controlled to tilt a human support surface of the frame towards a direction of acceleration associated with a driving maneuver as the driving maneuver is executed.

Systems and methods are provided for predicting a desired position of or adjustment to one or more accommodation devices of a vehicle, e.g., a seat, a steering wheel, a rearview mirror, etc. A user's position or adjustment preferences may be learned over time by measuring or obtaining data regarding the position or adjustment of accommodation devices. These learned position or adjustment preferences may be stored along with a corresponding day, time of day, and/or vehicle location during or at which the position or adjustment preferences were measured or obtained. During a subsequent occurrence of the day, time of day, and/or if the vehicle is at or traverses a location during which a previous position or adjustment was made, the same or similar position or adjustment can be effectuated. Whether or not the position or adjustment is effectuated can depend on how accurate the predicted position or adjustment may be.

A capacitive detection system for detecting occupancy of a vehicle seat includes a signal generating unit and a signal evaluation unit. The vehicle seat has a seat heater member configured for receiving pulse-width modulated electrical heater power of a pulse-width modulation frequency and time-varying output signals of the signal generating unit. The signal evaluation unit is configured to monitor a voltage difference between the electrical connection ends of the seat heater member, and is further configured to generate an output signal that is indicative of the seat heater member to be defective, on the basis of a fulfillment of at least one predetermined condition concerning the monitored voltage difference and a phase of the pulse-width modulated electrical heater power.