Disclosed herein are system, apparatus, article of manufacture, method and/or computer program product embodiments, and/or combinations and sub-combinations thereof, for using electrical button matrix scanning techniques to detect remote control buttons pressed by users. An example embodiment operates by detecting, using an electrical matrix scanning technique, an actuated electrical switch corresponding to a remote control action for a media device. The actuated electrical switch includes a first actuated electrode coupled to a first actuated electrical line of an electrical matrix, a second actuated electrode coupled to a second actuated electrical line of the electrical matrix, and a third actuated electrode coupled to a third actuated electrical line of the electrical matrix. In response to detecting the actuated electrical switch, the example embodiment operates by triggering an execution of the remote control action corresponding to the actuated electrical switch.

The invention relates to a sensor device (100) for actuating a movable part (101), in particular a sliding door, of a vehicle (1), comprising: a capacitive sensor unit (10) with a plurality of sensor elements (11) for motion detection, in particular gesture detection, of a user to trigger opening and/or closing of the movable part (101), an NFC antenna (30) for communicating with a vehicle-side security system (2) and/or a user-side mobile handheld device (4) in order to trigger unlocking and/or locking of the movable part (101), and a circuit board (20) for accommodating the capacitive sensor unit (10) and the NFC antenna (30).

A touch display device, including a display panel and a touch panel, is provided. The touch panel has a first display area, a second display area, and a connection area located therebetween, and includes a substrate, first touch signal lines, second touch signal lines, first electrode lines, second electrode lines, and first connection lines. The first and second touch signal lines are located on the first display area. The first and second electrode lines are located on the second display area. The first connection lines are located on the connection area. The first touch signal lines, the first electrode lines, and the first connection lines extend along a first direction. The first connection lines are electrically connected to the first touch signal lines and at least part of the first electrode lines. The second touch signal lines and the second electrode lines extend along a second direction.

The invention relates to a safety system for a door in a motor vehicle, comprising an electronic unit that includes at least one first and a second sensor. Each sensor has its own monitoring zone on the motor vehicle door. The safety system further comprises a lock which is arranged on the motor vehicle door and can be switched between a locked position and an unlocked position, as well as a user-held identifier which can be brought into data communication with a transceiver unit in the motor vehicle for authentication purposes. The electronic unit is designed in such a way as to be able to generate a trigger signal by having the user execute at least one defined movement pattern within the monitoring zones, thus allowing the position of the lock to be switched.

A touch display device and a touch driving method are provided. The touch display device comprises a plurality of interlaced sensing electrodes and driving electrodes in N large groups. Corresponding driving signals synchronously scan the driving electrodes of each large group. Scanning time of the driving electrodes can be reduced to an original 1/N, which can improve a touch report rate.

An input device according to an embodiment includes a first sensor electrode disposed on a substrate, a second sensor electrode which faces the first sensor electrode and which is capacitively coupled to the first sensor electrode, and a detection circuit which detects approach of an operation body to the second sensor electrode based on an electrostatic capacitance of the first sensor electrode.

This disclosure relates to a sensor, a sensing device, and a sensing method. The sensor may include an upper electrode layer, a dielectric layer, and a lower electrode layer. A first dielectric layer surface of the dielectric layer may be attached to a first upper electrode surface of the upper electrode layer. A second dielectric layer surface of the dielectric layer may be attached to a first lower electrode surface of the lower electrode layer. The second dielectric layer surface may be opposite to the first dielectric layer surface. The upper electrode layer may include at least two sub-upper electrodes arranged in an array. An electrode gap may exist between the at least two sub-upper electrodes.

A touch display device and a touch driving method are provided. The touch display device comprises a plurality of interlaced sensing electrodes and driving electrodes in N large groups. Corresponding driving signals synchronously scan the driving electrodes of each large group. Scanning time of the driving electrodes can be reduced to an original 1/N, which can improve a touch report rate.

An electronic device includes a substrate, a plurality of data lines, a plurality of data switches, a plurality of sensing electrodes, and a plurality of touch switches. The data lines and the sensing electrodes are arranged on the substrate. The plurality of data switches respectively have a first connection end and a second connection end, and the plurality of touch switches respectively have a third connection end and a fourth connection end. The first connection end of the plurality of data switches respectively couple to one of the plurality of the data lines. The third connection end of the plurality of touch switches respectively couple to one of the plurality of the sensing electrodes, and the fourth connection end of the plurality of touch switches respectively couple to the second connection end of one of the plurality of data switches.

An input device includes one or more groups of two or more touch sensitive elements. Each group of two or more touch sensitive elements is arranged to generate a sequence of electronic waveforms corresponding to a multi-digit code that identifies the group in response to a swiping touch across the two or more touch sensitive elements.