An electrostatic-capacitive proximity detecting device includes an electrode unit including a plurality of electrodes linearly arranged along one direction; an electrostatic capacitance detector that drives the electrodes in a time division manner and detects detection values corresponding to electrostatic capacitances between a to-be-detected object and the respective electrodes; and a position detector that detects a position of the to-be-detected object in the one direction, based on arrangement positions of the respective electrodes in the one direction and a bias in magnitudes of the detection values detected for the respective electrodes by the electrostatic capacitance detector.

A capacitive touch sensor is disclosed for use with input signal. The capacitive touch sensor includes a number n of input/output lines. Each of the number n of input/output lines is electrically disconnected from every other of the number n of input/output lines. Each of the number n of input/output lines is arranged to cross every other of the number n of input/output lines. Each of a number β of positions includes one of the number n of input/output lines crossing another of the number n of input/output lines.

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 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 programmable or configurable non-contact solid state switch device and method are provided for emulating a high reliability switch. The switch device senses position information related to a switch and is calibrated using a learning operation to learn position information of mechanical features of the switch and to map the positions of these features. Electrical outputs or functions are assigned to the mapped positions and stored such that the switch device generates the outputs when their corresponding positions are sensed. A switch device is uniquely configured to the mechanical system in which it operates.

A control system for a vehicle interior comprising a control element for a user to interact with is provided. The control element may comprise a sensing electrode configured to provide one or more electrical signals and a non-conductive cover material provided on or over the sensing electrode. The sensing electrode may be formed of or comprise a conductive plastic. The non-conductive cover material may be formed of or comprise a non-conductive plastic. The non-conductive cover material may be or comprise an outer layer, over-layer or skin of the control element. The non-conductive cover material may provide one or more touch interactive surfaces of the control element.

An on-vehicle human sensing switch includes: a display having a display area for luminously displaying a switch image of a vehicle-mounted electronic device ; a light transmission type touch panel substrate body disposed on the display; and a light transmission type decorative body disposed on the touch panel substrate body . The touch panel substrate body includes, on a substrate, an electrostatic capacitance type sensor electrode configured to detect approach of a detection target, and an electrostatic capacitance type switch electrode which is disposed at a position opposing the display area and is configured to detect an action of the detection target. When approach of the detection target is detected by the sensor electrode, the switch image is displayed on the display.

A rotary controller for a vehicle apparatus such as an infotainment system has at least two operating elements which are arranged at a spacing from one another in a direction of extent of an axis of rotation of the rotary controller. The rotary controller has a receptacle on which the operating elements are mounted along with a plurality of contact-sensitive sensor elements. Each sensor element associated with a respective operating element to detect a rotational movement about the axis of rotation when a user manually contacts the respective operating element.

A cooking appliance includes a cooktop having at least one sensor operating field. The at least one sensor operating field has at least one scroll field for step by step modification of a multi-value operating parameter of the cooking appliance. The at least one scroll field has a number of discretely disposed sensor keys which are disposed below a cooktop plate.

A vehicle input knob assembly is provided that includes a stationary knob located in a vehicle and having an outer peripheral surface with a plurality of radial extending surfaces such as ribs and a plurality of proximity sensors located proximate to the knob to detect a user rotating a hand around the knob. The assembly also includes a controller generating a control signal based on the detected rotation of the hand. The knob may further include proximity sensors on a front surface for added user input.