An onboard operation apparatus includes an operation panel having an operation face touch-operated on by a fingertip of a user, an output part outputting an operation signal that corresponds to an operation element touch-operated, a vibration instrument causing the user to feel vibration, a position sensor detecting the touch position by a fingertip, and a vibration control part controlling the actuation of the vibration instrument. The onboard operation apparatus further includes a trace calculation part calculating the movement trace of a touch position, and a prediction part predicting whether the touch position reaches a second operation element within a predetermined time. The vibration control part has an entering vibration control part and a holding control part.

A motor vehicle control panel includes a front face including a control zone; a printed circuit board; at least one electrically conductive capacitive detection element extending along a vertical axis from the rear surface of the front face to an electrical contact zone of the printed circuit board; a light source mounted on the printed circuit board and able to produce a back lighting light beam toward the control zone through the capacitive detection element; the capacitive detection element also comprises at least one rigid tubular part forming a light guide for the light beam and at least one elastic part made in one piece with the rigid tubular part so as to compensate the clearances between the rear surface and the detection element and between the printed circuit board and the detection element.

An interactive user interface for a steering wheel is provided. A user interface is provided on one or more portions of the steering wheel. The user interface recognizes gesture movements made by a user thereon. The user interface allows navigation of a set of controls associated with a menu provided through the user interface based on the recognized gesture movements.

A touch input device includes a mounting unit in which a mounting groove is formed at an inner side of the mounting unit, and a touch unit accommodated in the mounting groove and installed to be detachable from the mounting unit, wherein the touch unit comprises a first touch portion and a second touch portion, which are provided on different surfaces of the touch unit and allow a user to input a touch gesture, and the touch unit is selectively coupled to the mounting unit to allow the first touch portion to face an upper side or to allow the second touch portion to face the upper side.

A number of objects simultaneously touching a touch-sensitive operator control unit of an operator control apparatus are detected and a trigger position at which one of the number of objects detected touches the touch-sensitive operator control unit is determined. When more than one object touches the touch-sensitive operator control unit, a touch pressure with which the touch-sensitive operator control unit is acted on overall by the number of objects detected is compared to a predefined pressure threshold value. A function of the motor vehicle, assigned to the trigger position, is triggered if the touch pressure is higher than the predefined pressure threshold value. The predefined pressure threshold value is defined in a manner dependent on the number of objects detected.

An input device is described which comprises a touch-sensitive surface and a force sensor, wherein the force sensor is adapted to detect a force applied to the touch-sensitive surface. The input device further comprises a vibration sensor and a control unit, wherein the control unit is coupled with the force sensor, the touch-sensitive surface and the vibration sensor. The control unit is adapted to validate a force detected by the force sensor as an input in dependence on a touch of the touch-sensitive surface and in dependence on a vibration detected by the vibration sensor. There is further described a motor vehicle which comprises such an input device. A method of detecting an input at an input device is further described.

An integrated switch device for a vehicle includes: an input device configured to receive a user's fingerprint; a touch device configured to generate a mirror angle adjustment signal; a touch display configured to display a door control interface, a mirror selection interface, a mirror control interface, and a seat setting interface; and a controller configured to determine an operation mode based on whether the vehicle in a driving mode, a power condition, and whether a door is open and to set an interface displayed on the touch display among the door control interface, the mirror selection interface, the mirror control interface, and the seat setting interface depending on the operation mode.

A touch panel control unit controls a touch panel including a solid region. A gesture determination unit obtains solid shape information from a solid shape information table, specifies a content of a gesture operation with respect to the touch panel based on the solid shape information, and generates gesture specification information. An AP interface unit transmits the gesture specification information to the AP execution unit and receives response information from the AP execution unit. A display control unit controls display of the touch panel based on the received response information.

Touch events can be detected using an ultrasound input device coupled to a surface, such as a surface of a piece of furniture or electronic device. The ultrasound input device can generate ultrasonic waves in the surface, the reflections of which can be measured by the ultrasound input device. When a touch is made to the surface (e.g., opposite the ultrasound input device), the physical contact can absorb some of the energy of the outgoing ultrasonic waves (e.g., the originally transmitted wave and any subsequent outgoing reflections). Energy measurements associated with the measured reflections can thus be used to identify touch events. Various techniques can be used to make the energy measurements and reduce identification of false touch events.

A device for entering information includes an operating element and a control device. The device further includes an angle encoder configured to detect a rotational movement about an axis of rotation of the operating element, a touch encoder configured to detect a pressure movement of the operating element, and a transmission element configured to transmit data from the angle encoder and/or from the touch encoder to the control device. In addition, the device includes an energy transmission device configured to supply energy to the operating element via a cable-free transmission of energy.