Various aspects include wearable audio devices. In some particular implementations, a wearable audio device includes: an acoustic transducer having a sound-radiating surface for providing an audio output; a controller coupled with the acoustic transducer; a printed circuit board (PCB) coupled with the controller; and a capacitive touch interface coupled with the PCB, the capacitive touch interface having: a contact surface for receiving a touch command; and a set of at least two electrodes underlying the contact surface for detecting the touch command at the contact surface, where neighboring electrodes in the set share a border having an arcuate profile across the contact surface or a piecewise profile approximating a non-linear path across the contact surface.

A detection device including: a measurement electrode, and a second electrode separated from one another by a distance (D) that is elastically modifiable locally, by a load exerted by an object on a detection surface, and a controller arranged in order to: connect the electrodes to an alternating guard potential (V.sub.g) in order to measure a capacitance representing an approach and a contact; and connect the second electrode to a second potential a second potential proportional to the guard potential (V.sub.g) and having a different amplitude, or to the ground potential (G), in order to measure a capacitance representing a pressure.

Also provided is a detection method utilizing such a detection device.

A touch-sensitive depressible button with multiple depression thresholds is provided. When the button is depressed to a first depression threshold, the touch sensor can be switched from a low-power, non-sensing state to a sensing state. When the button is depressed to a second depression threshold, the touch sensor can sense the touch context and input can be generated based on the depression and the touch context. In this way, the touch-sensitive depressible button with multiple depression thresholds can facilitate timely switching of the touch sensor to a sensing state.

A device includes a touch and pressure sensitive screen having touch pressure sensors and a controller. The controller acquires touch pressure data from the plurality of touch pressure sensors. For each touch pressure sensor, the controller determines whether the touch pressure data from that touch pressure sensor is indicative of abnormal operation of that touch pressure sensor. Where no abnormal operation is indicated, the controller sums the touch pressure data from each of the touch pressure sensors to produce a touch pressure output. Where abnormal operation is indicated, the controller sums the touch pressure data from each of the touch pressure sensors and multiply the sum by a correction factor to produce the touch pressure output.

A proximity sensor is arranged with a first electrode input with a first signal, a second electrode input with a second signal different from the first signal, a third electrode arranged closer to the first electrode than the second electrode, and the second signal has a reverse phase of the first signal.

A touch-sensitive depressible button with multiple depression thresholds is provided. When the button is depressed to a first depression threshold, the touch sensor can be switched from a low-power, non-sensing state to a sensing state. When the button is depressed to a second depression threshold, the touch sensor can sense the touch context and input can be generated based on the depression and the touch context. In this way, the touch-sensitive depressible button with multiple depression thresholds can facilitate timely switching of the touch sensor to a sensing state.

A capacitive touch sensor panel of present invention includes a metal panel with a plurality of electrically isolated and separated metal buttons. A capacitive touch sensor also includes a dielectric layer attached to the backend of said metal panel and to the backend of said metal buttons, and a circuit bearing structure attached to said metal panel and having a plurality of sensor pads located directly beneath said metal buttons, and wherein the circuit bearing structure has a capacitive coupling between each of the sensor pads and the grounded parts of said circuit bearing structure.

An operator control device for a vehicle, and a method for operating such an operator control device is disclosed. The operator control device is for controlling safety-relevant functions. To this end, the operator control device has at least one user interface having at least one user input panel for user input and a sensor system for identifying a user input in the area of the user input panel, wherein the sensor system has at least one capacitive sensor device having a first, electrically conductive sensor structure and a second, capacitive sensor device having a second, electrically conductive sensor structure, the sensor structures being arranged beneath the user interface in the area of the user input panel. The first sensor structure and the second sensor structure are each configured in comb-like and/or meanderous fashion and arranged in intermeshing fashion at least in a subarea of the user input panel.

A touch-sensitive depressible button with multiple depression thresholds is provided. When the button is depressed to a first depression threshold, the touch sensor can be switched from a low-power, non-sensing state to a sensing state. When the button is depressed to a second depression threshold, the touch sensor can sense the touch context and input can be generated based on the depression and the touch context. In this way, the touch-sensitive depressible button with multiple depression thresholds can facilitate timely switching of the touch sensor to a sensing state.

A capacitive sensor device for approach and/or contact detection can be coupled with an electric circuit (10) and has a sensor electronics (20) and a device for potential separation (30), which with the sensor electronics (20) is coupled and by which the capacitive sensor device can be coupled with the electric circuit (10). In a method for operating a capacitive sensor device which has a sensor electronics, the sensor electronics can be coupled with an electric circuit and the sensor electronics is coupled with the electric circuit in a separable way with respect to the potential.