A system comprising: a heater located within a steering wheel and a heater located within a vehicle seat; wherein the steering wheel is a first plate and the vehicle seat is a second plate and a shift in a signal is monitored from the first plate, the second plate, or both so that a presence and absence of an occupant is detected, and wherein the heater in the steering wheel and the heater in the vehicle seat are a sensor.

A system comprising: a heater located within a steering wheel and a heater located within a vehicle seat; wherein the steering wheel is a first plate and the vehicle seat is a second plate and a shift in a signal is monitored from the first plate, the second plate, or both so that a presence and absence of an occupant is detected, and wherein the heater in the steering wheel and the heater in the vehicle seat are a sensor.

Method for controlling a vehicle including a smartphone-engaging coupling element. Data about operational status of the vehicle is transferred from one or more vehicle-resident systems to a smartphone when the smartphone is engaged with the coupling element. Commands are received by the vehicle from the smartphone when the smartphone is engaged with the coupling element, which commands being based in part on data previously transferred from the vehicle-resident system(s) to the smartphone when the smartphone is engaged with the coupling element. A vehicular system, e.g., seat positioning system, mirror positioning system, passenger compartment temperature control system, route guidance or navigation system, changes its operation in accordance with the commands received by the vehicle from the smartphone when the smartphone is engaged with the coupling element.

A capacitive detection device (20) for a vehicle comprises a sensing electrode (26) for generating an oscillatory electric field in a detection space and a shielding electrode (28) arranged on a side of the sensing electrode turned away from the detection space. The capacitive detection device comprises a circuit ground and a ground connector for connecting the circuit ground to chassis ground of the vehicle. At least one shunt capacitor is connected between circuit ground and the shielding electrode. The at least one shunt capacitor has a capacitance at least 25 times higher than the capacitance between the shielding electrode and the chassis ground of the vehicle.

A combined seat heater and capacitive occupancy sensor comprises a heater network including a heating element (11) and a capacitive sensing circuit connected to the heating element to sense a capacitive load. A first and a second interface are provided for connecting the heating element to a first and a second terminal of a power source, respectively. Each interface comprises electronically controlled switches (3, 5; 4, 6) arranged in series and defining an intermediate node (20; 21). An oscillator (8) is AC-coupled to the intermediate nodes to apply an oscillating voltage thereto. A current measuring means (9), AC-coupled between the oscillator and the heating element, keeps the AC-potential of the heating element at least substantially equal, in amplitude and phase, to the oscillating voltage on the intermediate nodes and to derive the capacitive load from a thus resulting current flowing into the heating element.

Disclosed herein is an occupancy detection device for detecting an occupancy of a seat of a motor vehicle. The occupancy detection device comprises an electric resonant circuit and a sensor element, wherein the electric resonant circuit experiences a change due to a change of the surroundings of the sensor element, so that with reference to the determined electrical parameter an occupancy of the seat can be detected; and a heater control connected with the occupancy detection device such that the sensor element can simultaneously operate as a heater.

An occupant position detection device is an occupant position detection device disposed inside a vehicle to detect a position of an occupant, and includes: a detector comprising two or more sensor electrodes disposed forward of a seat and at least one sensor electrode disposed at a position more rearward and higher than these sensor electrodes, the detector respectively outputting a detection signal based on a distance between each of the sensor electrodes and the occupant; and a computation unit inputted with the detection signal to compute an occupant position. The computation unit selects from the detection signals outputted from the detector three or more types of combinations configured from two of the detection signals, calculates a ratio or difference for each of these combinations of detection signals, and computes the occupant position based on the three or more calculated ratios or differences of the detection signals.

An attachment structure of a vehicular module to a ceiling of a vehicle cabin of a vehicle includes a design member. The design member is configured to attach, to the ceiling, the module including an in-cabin sensor configured to perform detection in the vehicle cabin, and includes a securing portion configured to be secured to a vehicle-body ceiling member of the vehicle or an interior ceiling member disposed on a vehicle cabin side of the vehicle-body ceiling member, a downward protrusion protruding downward from the securing portion, and a design constituent extending from the downward protrusion and covering the securing portion. In an accommodating space defined between the downward protrusion and the design constituent, the in-cabin sensor is supported by the design member in such a manner that, above the accommodating space, a gap is left between the in-cabin sensor and the vehicle-body ceiling member or the interior ceiling member.

An electrostatic grip detection device includes a base material, a heater wire, a sensor wire, and a detection unit. The heater wire is formed in the base material. The sensor wire is formed in the base material, and has a first end electrically connected to the heater wire and a second end opened. The detection unit is electrically connected to at least one of the heater wire and the sensor wire, and senses a change in electrostatic capacitance of at least one of the heater wire and the sensor wire.

A capacitive sensing device includes an antenna electrode for emitting an alternating electric field in response to an alternating voltage caused in the antenna electrode and a control and evaluation circuit configured to maintain the alternating voltage equal to an alternating reference voltage by injecting a current into the antenna electrode and to measure the current. The control and evaluation circuit includes a microcontroller with a digital output for providing a digital signal and a low-pass filter operatively connected to the digital output for generating the alternating reference voltage by low-pass-filtering the digital signal.