The invention concerns a robust user interface for electronic devices where a single measurement circuit is used to measured inductance values due to user press events through sealable surface, as well as capacitance values due to user proximity and/or touch events, and with both the measured inductance and capacitance values used to determine user input commands.

A push-button structure includes: a mounting body, an outer surface of the mounting body being at least partially recessed inward to form a blind hole; a first magnetic component, located in the blind hole; a second magnetic component, located on an inner surface of the mounting body and distributed symmetrically with the first magnetic component on an opposite side of the mounting body, for generating, based on a distance to the first magnetic component, a magnetic signal corresponding to the distance; and an elastic block, located in the blind hole and having a first form without an external action and a second form under an external action.

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 control panel having: a trim element having a first outer face and a first inner face; a support element having a second outer face oriented towards the first inner face of the trim element and a second inner face opposite to said second outer face; and a group of force sensors configured for detecting a control force applied to the first outer face within a control area. The support element has, within a detection area extending around the group of control areas, a mechanical weakening formed by a recess in the second inner face.

An apparatus to secure a sensor assembly for a device touch button (such as for a mobile communications device). A touch sensor slot forms a part of the device case interior at a back-side of the touch button surface, and is configured to position the touch sensor (such as a sense coil inductor) relative to the associated touch button. A touch sensor spring clip is inserted within the touch sensor slot to flexibly urge the touch sensor toward the front-side surface of the touch sensor slot (back-side of the touch button surface). The touch sensor can include front-side spacers to maintain a sensing gap between the touch sensor and the touch button surface, and can include a sensor stiffener at the back-side surface of the touch sensor assembly, the touch sensor spring clip contacting the sensor stiffener. The touch sensor assembly can comprise a flex circuit PCB assembly.

A touch input sensing device configured to be added to an electronic device, the electronic device including a touch input unit, the touch input unit including a first touch member integrated with a housing. The touch input sensing device includes a resonant circuit configured to generate a resonance signal having a resonant frequency that varies based on a touch of the touch input unit, a digital frequency counter configured to count a reference frequency signal based on the resonance signal, or count the resonance signal based on the reference frequency signal, to generate a count value, and a touch detector configured to detect whether the touch of the touch input unit has occurred based on the count value generated by the digital frequency counter, and output a touch detection signal indicating whether the touch has occurred.

A machinery brake of an elevator includes a frame part including an electromagnet, an armature part, an inductive proximity sensor indirectly mounted to one of the following: the frame part, the armature part, and a target mounted to another of the following: the frame part, armature part. The machinery brake further includes, for establishing the indirect mounting: a temperature change compensation device mounted between the inductive proximity sensor and one of the following: the frame part, the armature part. Some aspects relate to a method for compensating a change in switching point of an inductive proximity sensor.

A touch sensing device configured to be installed in an electronic device, the electronic device including a side unit and a touch switch unit, the side unit including a non-conductive cover and a conductive frame coupled to the cover, the touch switch unit including a first touch member that is a portion of the cover, the touch sensing device including a first sensing electrode configured to be disposed inside the electronic device near the first touch member; a first sensing coil configured to be disposed inside the electronic device; and a first connection wire including one end connected to the first sensing electrode and another end connected to the first sensing coil, thereby electrically connecting the first sensing electrode to the first sensing coil.

A classification system for classifying sensor samples in a sensor system, the sensor system comprising N force sensors each configured to output a sensor signal, where N≥1, each sensor sample comprising N sample values from the N sensor signals, respectively, the classification system comprising: a classifier configured, for each of a series of candidate sensor samples, to perform a classification operation based on the N sample values concerned and generate a classification result which labels the candidate sensor sample as indicative of a defined target event, thereby generating a series of classification results corresponding to the series of candidate sensor samples, respectively; a determiner configured to output at least one event determination based on the series of classification results; and a controller configured to control the classifier and/or the determiner based on one or more controller input signals.

A touch sensing device includes: at least one sensing coil disposed on a substrate; a sensing circuit unit configured to detect applied external pressure, based on a change in inductance of the at least one sensing coil; and a deformation inducing shaft configured to block one side of the at least one sensing coil in one direction and open another side of the at least one sensing coil in another direction.