An input device is characterized in that in a first stroke region in which an operation panel is pushed during a touch operation, a first reaction force that occurs by pushing the operation panel is generated by the first elastic portion. In a second stroke region including a stroke longer than in the first stroke region and a stroke for performing a push operation, a second reaction force that occurs by pushing the operation panel is a resultant force generated by a first elastic portion and the push switch. In the vicinity of a boundary between the first stroke region and the second stroke region, the amount of change in the first reaction force with respect to a stroke length is less than the amount of change in the second reaction force with respect to a stroke length.

Aspects of the present disclosure relate to playback devices having a non-flat surface and comprising a flexible electronic assembly conforming to that surface. The flexible electronic assembly may include (i) a flexible substrate having a first portion and a second portion, (ii) an array of capacitive touch sensor electrodes arranged on the first portion, and (iii) a plurality of conductors that are electrically coupled to the array of capacitive touch sensor electrodes and that extend onto the second portion. The first portion may include a plurality of cutouts. Each cutout of a first subset of the plurality of cutouts may be positioned between a respective set of two or more electrodes in the array of capacitive touch sensor electrodes. Each cutout of a second subset of the plurality of cutouts may be configured to reduce a wrinkling of the first portion when conforming the first portion to the non-flat surface.

An operation input device includes a resistance element to generate a capacitance between an operating medium and the resistance element in response to an approach of the operating medium to the resistance element, and a power source to supply electric charge to one end and the other end of the resistance element. A first electric unit measures a first electric charge transfer amount supplied to the one end of the resistance element in response to generation of the capacitance. A second unit measures a second electric charge transfer amount supplied to the other end of the resistance element in response to generation of the capacitance. A controller is connected to the first and second units, and detects a position of the operating medium in a direction perpendicular to a surface of the resistance element based on a sum of the first and second electric charge transfer amounts.

A device, comprising: a pair of force sensors located for detecting a user squeeze input; and a controller operable in a squeeze detection operation to detect the user squeeze input based on a cross-correlation between respective sensor signals originating from the pair of force sensors.

A method of operating a capacitive sensing device that includes exactly two electrically conductive antenna electrodes, which are placeable in two layers at a vehicle steering wheel rim, and a current measurement circuit for determining complex electric currents in the antenna electrodes. The method includes at least the following steps for constituting a measurement cycle: operating each one of the exactly two antenna electrodes in loading mode and determine the complex impedance of the respective antenna electrode; and generating a classification signal that is indicative of a present scenario, based on a fulfillment of at least one predetermined condition concerning at least one characteristic quantity of the first complex impedance as well as of the second complex impedance.

The present invention relates to a combined capacitive sensor and heating apparatus (10, 60, 70) having a capacitive sensor device for detecting the presence of a capacitively effective actuation means in a detection region of the sensor device, and having a heating device, wherein the sensor and heating apparatus (10, 60, 70) has an electrical combined sensor and heating element (4), wherein a synchronization device (40) is configured to capture an actual voltage applied to the first electrical path (P1) between the first pole (V+) of a voltage source and the first connection (5) of the combined sensor and heating element (4) and/or an actual current flow and/or to capture an actual voltage applied between the second connection (6) of the combined sensor and heating element (4) and the second pole (GND) and/or an actual current flow and to detect an instantaneous actual state of the heating device on the basis thereof, and to control the sensor device and/or output at least one control signal for at least partially controlling the sensor device on the basis of the detected actual state of the heating device.

A control element (1) has a control panel (2) on a front side and a rear surface (3) on a rear side of the control element situated opposite the front side. The control element has a vibration actuator (4) operatively connected to a locally limited portion (5) of the control panel (2). Thus, a touch detected by a sensor on the locally limited portion (5) of the control panel (2) triggers a vibration of the vibration actuator (4). The vibration actuator (4) is connected indirectly, via a lever element (7), to the rear surface (3) on the rear side of the control panel (2). The lever element (7) transmits a vibration of the vibration actuator (4) to the rear surface (3) of the control element in the area of the locally limited portion (5) of the front side of the control panel (2).

Technologies and techniques for operating an appliance. A command button of an operating part is actuated, the actuation of the command button being detected by a microcontroller using measuring instruments. The read-in measured values are evaluated such that it is determined whether the measuring signal has a regular form for actuating the command button, or an irregular form. A function associated with the actuated command button is implemented if it is established that the measuring signal has a regular form. When a regular form is identified, optionally an acoustic, haptic or optical acknowledgement signal is emitted, and when an irregular form is identified, an acoustic, haptic or optical fault signal is emitted.

A motorized shade for covering an architectural opening that can be actuated by touching its shade material. The motorized shade comprises a shade material extending between an upper end and a lower end and a motor drive unit operably connected to the upper end of the shade material and comprising a motor and a motor control module adapted to control the motor to raise or lower the shade material. The shade material comprises at least partially comprises electrically conductive material. The motor control module comprises a capacitive touch sensor that is electrically connected to the upper end of the shade material via at least one electrical contact. The motor control module is adapted to detect a touch of the shade material via the capacitive touch sensor and in response control the motor to raise or lower the shade material.

An user interface device includes a lens with a top surface and a bottom surface, where the bottom surface includes at least one graphic that is visible through the top surface of the lens. The user interface device further includes a transparent circuit film with a top surface and a bottom surface, at least one light emitting diode (LED), at least one silver conductor, and a layer of transparent pressure-sensitive adhesive that secures the bottom surface of the lens to the top surface of the transparent circuit film.