A portable electronic device includes a housing, a user input unit configured to detect touch input and push input, and a carrier, on which the user input unit is seated and which is inserted into the housing, wherein the user input unit includes a first input unit, closely disposed on an inner surface of the housing so as to detect touch input, and a second input unit, disposed inside the first input unit in the state of overlapping the first input unit so as to detect push input, the second input unit including a metal spring that changes in shape in response to the push input. The portable electronic device is capable of detecting two types of input and thus of ensuring that is possible to input a sufficient number of user instructions.

A capacitive switch according to an embodiment of the present invention includes a switch structure having a first electrode pattern; a substrate having a second electrode pattern and an integrated circuit unit; and an elastic body interposed between the switch structure and the substrate, wherein the integrated circuit unit generates a first output signal by detecting a change in capacitance caused by a user touch input operation through the first electrode pattern, the elastic body, and the second electrode pattern, and generates a second output signal by detecting a change in capacitance caused by a user push input operation.

A touch input device includes a touch sensing element having at least two input parts partitioned by at least one partition line, a plurality of force sensors mounted on a bottom surface of the touch sensing element, and at least one support member mounted on the bottom surface of the touch sensing element to provide reaction force to an elastic sensing element in a vertical direction and serving as the partition line. In at least one of the two input parts, a moment based on a shearing force may be canceled by the support member.

A headset controller takes a first touch sensor, a second touch sensor, a first pressure sensor, and a second pressure sensor as a control medium for users. The headset controller can generate four different output instructions by the users touching or pressing the operating interface. The headset controller integrates various sensing methods to generate the needed output instructions.

A wearable hearing device operatively coupled to an information handling system comprising a housing for a speaker and a microphone, a magnetic slider switch moveable with respect to the housing between a closed position and an open position in response to a user's external force, a rolling magnet rotating within the magnetic slider switch during movement between the open and closed positions, a bar magnet fixed within the housing having a first pole attracting the rolling magnet in the closed position and a second pole attracting the rolling magnet in the open position to reduce the external force required to move the magnetic slider switch, a hall effect sensor to sense a change in distance to the rolling magnet during movement between the open and closed positions, and to associate the change in distance with a command instruction, and a microcontroller to execute or transmit the command instruction.

The invention relates to a module component (100) for a movable part (201) of a vehicle (200), comprising: a support housing (10) for fastening the module component (100) to the movable part (201) of the vehicle (200), a key device (20) for actuating the movable part (201) of the vehicle (200), wherein the key device (20) comprises a key cap (21) configured to receive an activation action, in particular a touch and/or force, of a user, wherein an activation element (24) is arranged on the key cap (21) to be able to detect a presence and/or an activation action of the user, and an electronic device (30) for providing lighting functions and/or sensor functions when the movable part (201) of the vehicle (200) is actuated, wherein the electronic device (30) is fastened to the support housing (10), wherein the electronic device (30) comprises a sensor device (31, 32) for a presence detection and/or an activation action detection at the activation element (24), and wherein the electronic device (30) comprises at least one lighting device (33) for illuminating through the key cap (21).

A headset controller takes a first touch sensor, a second touch sensor, a first pressure sensor, and a second pressure sensor as a control medium for users. The headset controller can generate four different output instructions by the users touching or pressing the operating interface. The headset controller integrates various sensing methods to generate the needed output instructions.

A push switch with dual sensing mode including a main socket, a sliding base, a keycap, a sensing circuit board and a touch sensor is provided. The main socket has an opening and a base. The sliding base is slidably fixed in the main socket. The keycap is correspondingly fixed at the upper end of the sliding base. The sensing circuit board is correspondingly installed in the main socket. The touch sensor is disposed in a keycap chamber of the keycap. When a user places his finger on the upper end of the keycap, the touch sensor generates an inductance and causes the sensing circuit board to output a touch signal.

A multi-value selection switch that includes an engagement surface with an integrated touch sensor. The integrated touch sensor includes a plurality of detectable positions that correspond to, for instance, a range of absolute or relative target input values between a predefined minimum and maximum. The engagement surface further defines a switch that actuates/activates based on detecting a user-supplied force and/or based on a user momentarily holding a finger/pointer position. A user can select a target input value by bringing a finger or other pointer within operable proximity of an associated detectable position and actuating the switch and/or momentarily pausing. In response, the selection switch outputs a control signal to an associated device to cause the same to adjust operation.

A multi-stage capacitive sensor is provided having a layered structure, including a user-contact surface, a first capacitive sensor for the user-contact surface, a second capacitive sensor which is spaced apart from the first capacitive sensor in a direction away from the user-contact surface, and a conductive member. The conductive member is positioned between the first and second capacitive sensors, and is engaged with the first circuit substrate and spaced apart from the second capacitive sensor. In a preferred embodiment, under the application of a force at the user-contact surface, the conductive member is deflected relative to the second capacitive sensor to alter a distance therebetween to create a detectable change in a capacitance at the second capacitive sensor.