A customizable gesture controller is disclosed for retro-fitting and forward-fitting into existing spaces or structures. One embodiment of the controller comprises a controller board configured to host software; a response layer comprising a plurality of sections arranged sequentially, each of the plurality of sections comprising: one or more center LEDs; one or more runway LEDs; and one or more touch sensors; and an overlay comprising: a glass overlay layer; and a graphic overlay layer comprising a plurality of button icons corresponding to the plurality of sections. The response layer further comprises one or more marks positioned at boundaries between each of the plurality of sections, the one or more marks being configured to identify locations at which to adjust lengths of the response layer using an application of force.

An electrical control system includes a switch module configured to control power delivery to at least one external load, and a removable user interface module configured to connect to the switch module, receive power from the switch module and display an interface in accordance with a status of the external load, the user interface including a printed circuit board (PCB) having a touch controller that detects signals from a plurality of touch sensors integrated on a first side of the PCB, and a light-emitting diode (LED) controller that controls a plurality of LED's, a light guide, attached to the first side of the PCB, that partially obstructs light emitted from the plurality of LED's, a tactile switch electrically connected to the first side of the PCB between the transparent cover and the PCB, and a cover attached to the tactile switch over the first side of the PCB.

A cooking appliance includes a plurality of electrically controlled heating elements operable to elevate a temperature of food items. A user interface includes a touch-sensitive circuit that is operatively-connected to an external surface of the cooking appliance for altering operational settings of the electrically controlled heating elements. An electrovibration feedback circuit is coupled to the external surface that generates a vibratory feedback that is sensible by the user's finger at the external surface in response to adjustments of the operational settings. The electrovibration feedback circuit creates an electrostatic force on the user's finger that simulates friction between the user's finger and the external surface.

A customizable gesture controller is disclosed for retro-fitting and forward-fitting into existing spaces or structures. One embodiment of the controller comprises a controller board configured to host software; a response layer comprising a plurality of sections arranged sequentially, each of the plurality of sections comprising: one or more center LEDs; one or more runway LEDs; and one or more touch sensors; and an overlay comprising: a glass overlay layer; and a graphic overlay layer comprising a plurality of button icons corresponding to the plurality of sections. The response layer further comprises one or more marks positioned at boundaries between each of the plurality of sections, the one or more marks being configured to identify locations at which to adjust lengths of the response layer using an application of force.

A first operation region 11 for providing a first tactile sensation and second operation regions 12_.sub.U and 12_.sub.D for providing a second tactile sensation are arranged adjacent to each other. when a detection unit 20 detects a slide operation from the first operation region 11 to the second operation region 12.sub.U or 12.sub.D, an operation control unit 30 outputs a second operation signal different from a first operation signal output depending on a movement distance of the slide operation on the first operation region 11. Therefore, the second operation signal is output when the degree of operation is not sufficient even by performing a slide operation within the first operation region 11, and the movement of the finger stops at a place where a change from the first tactile sensation to the second tactile sensation occurs. As a result, it is possible to allow a user to perform an operation of a degree of operation desired by the user without performing the slide operation several times.

Embodiments of the present invention provide a control apparatus (400, 500, 600) for controlling operation of a component; a control unit; component; a vehicle and a method for operation of the control apparatus (400, 500, 600). The control apparatus (400, 500, 600) comprises a user-interaction surface visible to a user of the apparatus, a first pressure sensing means (202, 402, 502, 602) horizontally adjacent to a gesture sensing means (204, 404). The first pressure sensing means (202, 402, 502, 602) is adapted to detect a first press input and the gesture sensing means (204, 404) is adapted to detect a gesture input, such that movement of a finger to provide the first press input and the gesture input are combinable to form a single command for controlling operation of the component.

A customizable gesture controller is disclosed for retro-fitting and forward-fitting into existing spaces or structures. One embodiment of the controller comprises a controller board configured to host software; a response layer comprising a plurality of sections arranged sequentially, each of the plurality of sections comprising: one or more center LEDs; one or more runway LEDs; and one or more touch sensors; and an overlay comprising: a glass overlay layer; and a graphic overlay layer comprising a plurality of button icons corresponding to the plurality of sections. The response layer further comprises one or more marks positioned at boundaries between each of the plurality of sections, the one or more marks being configured to identify locations at which to adjust lengths of the response layer using an application of force.

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 of positions, includes one of the number n of input/output lines crossing another of the number n of input/output lines.

To provide a capacitive touch switch capable of improving ununiformity of design and improving appearance relating to design or decorativeness. A capacitive touch switch 1 includes a glass substrate 2, a sensor portion formed at a side of an opposite surface opposite to a touch surface of the glass substrate. The sensor portion includes a center portion A of a wire attached portion 4 to a flexible printed circuit, and a connection portion C connected to the wire network B. In the connection portion C, an opening rate in a capacitive touch switch panel is increased by setting an electrode pattern width to be thinner from the wire attached portion A toward the wire network B.

A multi-layer touchscreen assembly for an appliance includes a panel including an outer touchscreen surface, an opaque layer positioned below the touchscreen surface and having at least one transparent area therein defining lighting of at least one visual touch control region, a printed circuit board positioned below the opaque layer, the printed circuit board including a plurality of light-emitting diodes proximate one or more corresponding capacitive touch sensors of a first visual touch control region of the one or more visual touch control regions, and the one or more capacitive touch sensors configured to provide a visual indication of a control aspect of the appliance according to a user's touch input. The assembly also includes at least one diffusion portion operatively positioned between the opaque layer at a transparent area thereof and the printed circuit board at the first visual touch control region.