Systems and methods for driver identification using vehicle approach vectors are disclosed. An example disclosed vehicle includes a plurality of beacons configured to connect to a first mobile device and a second mobile device. The example vehicle also includes a plurality of ultrasonic sensors. The example vehicle includes a driver identifier configured to predict trajectories for the first and second mobile devices based on information received from the plurality of beacons and the plurality of ultrasonic sensors, and determine which one of the mobile devices is associated with a driver based on the predicted trajectories.

Provided is a security device, comprising: a sensor that senses a presence in a vehicle and generates a presence signal; an ignition state detection device that detects a state of the vehicle, and generates a status signal; and a rules processor that determines from the presence signal and the status signal whether an alarm or message is to be generated.

A reclining rear seat system is provided for a motor vehicle. That reclining rear seat system includes a front seat, a first actuator for displacing the front seat between a first position and a second position, a reclining rear seat and a second actuator for displacing the reclining rear seat between an upright position and fully reclined position. Further the system includes a controller configured to control the reclining rear seat system and a front seat occupant sensor.

A vehicle seating system includes a vehicle seat, piezoelectric sensors individually positioned at respective locations within the seat corresponding to anatomical locations of a person sitting in the seat, and a controller. The sensors to generate electrical signals in response to mechanical stress applied on the sensors from biologically motivated force inputs of the person. The controller to detect from the electrical signals generated by the sensors biometric information of the person corresponding to the biologically motivated force inputs of the person.

A vehicle seat includes a seat bottom adapted to slide along a floor, a seat back coupled to the seat bottom, and powered means for rearranging the vehicle seat by sliding the seat bottom along the floor and/or pivoting the seat back relative to the seat bottom.

Arrangement for controlling a component having multiple states includes a device that generates a signal at a frequency that enables it to be conducted through a human body, and a conductive surface coupled to the device, situated in a position accessible by a part of the human, and which enables proximity or contact of the part of the human to the conductive surface to develop a reactive coupling between the human and the conductive surface. The component has multiple, different states and is controlled by the human to change from a first state to a second state upon completion of an electrical circuit including the component, the conductive surface and the device upon developing reactive coupling between the human and the conductive surface when the device is generating the signal conducted through the human. The component may be a vehicular component such as a door or window.

Systems and methods for controlling movement of an active payload support system. In one example, a seat system for a vehicle includes a seat, a support structure coupled to the seat and including an actuator configured to move the seat at a command angle relative to a floor of the vehicle responsive to movement of the vehicle, at least one sensor positioned to detect movement of the vehicle, and a controller configured to receive a signal from the at least one sensor, generate a command signal to instruct the actuator to move the seat relative to a floor of the vehicle, determine whether the command signal will cause the seat to exceed a limit, scale the command signal to conform to movement of the vehicle within the limit, and provide a force command to the actuator to move the seat based on the scaled command signal.

A heater/sensor assembly comprises a sensor assembly and a heater assembly. The sensor assembly comprises a first sheet of an electrically non-conducting material, a first wire attached to a first side of the first sheet, and a second wire arranged parallel to the first wire and attached to a second side of the first sheet that is opposite the first side. The heater assembly comprises a second sheet of the electrically non-conducting material arranged parallel to the first sheet; a third wire attached to a first side of the second sheet facing the second side of the first sheet; and a fourth wire arranged parallel to the third wire and attached to a second side of the second sheet that is opposite the first side of the second sheet. The third and fourth wires are arranged at an angle relative to the first and second wires.

A capacitive detection device and capacitive detection system for use in a vehicle interior includes at least one electrically conductive wire, at least partially attached to a component of the vehicle interior, and at least one electrically conductive layer that is arranged in close proximity to the at least one electrically conductive wire, compared to a potential minimum distance to a vehicle occupant, wherein a galvanic connection between the at least one electrically conductive layer and the at least one electrically conductive wire is avoided.

A system and a control method can prevent interference between front and rear seats for a vehicle, and allow reclining control and slide control for the front and rear seats to be performed, to control a seat back rearward movement angle of a front seat based on a seat back angle of the front seat, a position of the rear seat, and an interval between the front and rear seats at the time of rearward reclining control for the front seat, control a rearward slide movement distance based on the seat back angle of the front seat at the time of rearward slide control for the front seat, and calculate in advance a likelihood that interference will occur between the front and rear seats so as to stop the control operation at the time of performing a rearward reclining control operation and a rearward slide control operation.