The present disclosure relates to a capacitive touch-type power seat switch using a receptacle, mounted on a seat of a vehicle and configured to control a position of the seat and a function thereof, the power seat switch comprising: a knob configured to be moved upwards, downwards, leftwards, and rightwards by operation of a user; an operation transmission unit configured to transmit an operation direction of the knob when the knob is moved upwards, downwards, leftwards, and rightwards, and to implement a function of the power seat switch in response to an operation signal according to the transmitted operation direction; a receptacle installed in a PCB provided in the operation transmission unit; a sensor electrode electrically connected to the receptacle and configured to detect variation in capacitance; and a sensor circuit part electrically connected to the sensor electrode.

A composite pane with a capacitive switching zone includes a substrate, a first intermediate layer areally bonded to the substrate, a second intermediate layer areally bonded to the first intermediate layer, and a cover pane areally bonded to the second intermediate layer. A carrier film with an electrically conductive layer is arranged between the first and second intermediate layers. A capacitive switching zone is electrically isolated from the electrically conductive layer by a coating-free separating line, the capacitive switching zone has a contact zone, a supply line zone, and a connection zone; the supply line zone electrically connects the contact zone to the connection zone, and the connection zone is electrically connectable to sensor electronics. The surface capacitance between the contact zone and the outside surface of the substrate is greater than the surface capacitance between the contact zone and the outside surface of the cover pane.

Disclosed is a device for opening/closing an opening element of a motor vehicle by detecting movement of a users limb, the device including an approach and/or contact detection sensor including a single electrode and an analyzer for analyzing the variations in capacitance of the electrode, and an opening element opening/closing control unit. The device also includes: a sealed housing including first and second metal surfaces; and a unit for detecting a predetermined form of the variations of the electrode, exhibiting a succession of a predetermined number of peaks of predetermined amplitude within a predetermined period; the first and second surface being separate, and the electrode being located outside the sealed housing, in such a way that the electrode is coupled electrically to the at least one first surface and to the at least one second surface so as to create at least two approach and/or contact detection areas.

A rotary actuator assembly includes a rotary actuator having a rotary body on a capacitively-sensing detection surface of the touch panel. A sensor ring coupled to the rotary body includes on a first ring surface includes alternately arranged contact surfaces and insulating surfaces and on a second ring surface includes a circumferential metal surface that is electrically connected to the contact surfaces. A sliding contact includes a contact pad and a contact spring connected together. The contact pad forms an electrical contact point fixed at a position of the detection surface. The contact spring contacts the contact surfaces and the insulating surfaces in alternation as the sensor ring rotates with rotation of the rotary body whereby a variable electrical signal is generated at the contact point. The electrical signal is detectable by the touch panel and the touch panel includes a mutual capacitance touch sensor assembly.

The present disclosure relates to a phased array antenna module. The phased array antenna module comprises: multiple antenna units, each of which comprises a first antenna electrode part, a second antenna electrode part spaced apart from the first antenna electrode part, a sensing electrode part electrically connected to the second antenna electrode part, and a ground electrode part spaced apart from the first antenna electrode part with the second antenna electrode part interposed therebetween; a capacitance sensing part to which the sensing electrode part is connected and which senses at least one among the capacitance change between the first antenna electrode part and the second antenna electrode part, the capacitance change between the first antenna electrode part and the ground electrode part, and the capacitance change between the second antenna electrode part and the ground electrode part, and outputs a capacitance sensing signal; and a module control part which is electrically connected to the capacitance sensing part and the second antenna electrode part of each of the antenna units, and controls the antenna units on the basis of the capacitance sensing signal generated by the capacitance sensing part.

A capacitive sensor for a planar recognition of an approach of an object. The capacitive sensor includes a first planar electrode and a second planar electrode, a dielectric being situated between the first electrode and second electrode for spacing. The first electrode and the second electrode being designed to be limp and/or torsion flexible.

A capacitance type input apparatus includes a plurality of touch switches; and a determining unit configured to determine which one touch switch among the plurality of touch switches a touch operation is performed on, based on outputs of the plurality of touch switches. The determining unit performs a first comparison of comparing a first threshold used for determining whether the touch operation has been performed, with each of the outputs of the plurality of touch switches, performs a second comparison of comparing an output that is higher than the first threshold among the outputs of the plurality of touch switches, with a plurality of comparison thresholds that are greater than first threshold and that are different from each other, and determines which one touch switch among the plurality of touch switches the touch operation is performed on, based on a comparison result of the first or second comparison.

In a pressure-sensitive touch sensor of a capacitance type, a first electrode and a second electrode are provided on a first surface of a base material sheet. The base material sheet is folded between the first electrode and the second electrode so that a surface of the first electrode and a surface of the second electrode face each other. The base material sheet is folded at a fold line portion in which a slit is formed. An elastic layer is provided between folded parts of the base material sheet. The pressure-sensitive touch sensor is configured to detect pressing on the operation surface based on a change in capacitance, which is caused when the elastic layer is compressed and deformed in a thickness direction by a pressing force to reduce a distance between the first electrode and the second electrode.

A control device configured for use in a load control system to control one or more electrical loads may comprise an actuation member having a front surface defining a touch sensitive surface configured to detect a point actuation along at least a portion of the front surface, a touch sensitive circuit, and a control circuit. The touch sensitive device may comprise one or more receiving capacitive touch pads located behind the actuation member and arranged in a linear array adjacent to the touch sensitive surface. The control circuit may be configured to operate using different filtering techniques based on the state/mode of the control device and/or based on whether the positions of point actuations by a user along the touch sensitive surface indicate a fine tune or gross adjustment by the user. For example, the control circuit may generate an output signal using light/no filtering or using heavy filtering.

An exemplary an access control device generally includes a keypad assembly, an antenna, and a controller. The keypad assembly includes a capacitive touch keypad matrix, and the antenna is substantially coplanar with the capacitive touch keypad matrix. The controller is connected with each of the keypad assembly and the antenna such that the controller is operable to receive access codes via each of the keypad assembly and the antenna.