Abstract: A common capacitive touch sensor may have a two dimensional array of transparent conductive strips going from edge to edge on a substrate layer or sheet of a touch sensor. According to some aspects, there is provided a capacitive touch sensor device including a substrate layer and a plurality of resonant circuits. Each resonant circuit includes an electrode, and each resonant circuit has a respective resonance frequency that is unique within the plurality of resonant circuits. The electrodes of the resonant circuits are distributed on the substrate layer. A controller for a touch sensor is also provided that includes a signal generator to drive at least one plurality of resonant circuits, where each resonant circuit has a respective resonance frequency. The signal generator is tunable to generate input signals at each of the resonance frequencies. The controller also includes a detector.

Abstract: Resistive touch sensors, such as those used in touchscreen panels, typically comprise multiple sheets separated by a gap. Typically, one sheet is a hard substrate layer, and the other sheet is a flexible switch layer that, when touched, flexes to touch the substrate layer. Changes in pressure within the gap may damage a resistive touch sensor. According to an aspect, there is provided a touch sensor device comprising a first sheet having and a second sheet overlaying and being spaced from the first sheet, thereby forming a gap. The gap is filled with gas, typically air, and has a sealed periphery. The touch sensor also includes a hole in the first sheet extending from the gap to an outer surface of the first sheet. The touch sensor device also includes a regulator device attached to the hole to allow flow of the gas between the chamber and the gap.

Abstract: The present disclosure relates to optical touch sensing technology. Provided is an apparatus comprising an emitting optical waveguide comprising input and output areas, an emitting optical distributed band pass filter disposed at the output area, a receiving waveguide disposed at a spaced apart location from the emitting waveguide, and a receiving distributed band pass filter at an input area of the receiving waveguide. The apparatus may comprise a tunable light source for cycling through a plurality of frequency bands of light for scanning a length of the waveguides for an obstruction (e.g. a touch). The apparatus may be used in place of the plurality of light source/photo detector pairs found in conventional touch screen devices.

Abstract: The present disclosure relates to optical touch sensing technology. Provided is an apparatus comprising an emitting optical waveguide comprising input and output areas, an emitting optical distributed band pass filter disposed at the output area, a receiving waveguide disposed at a spaced apart location from the emitting waveguide, and a receiving distributed band pass filter at an input area of the receiving waveguide. The apparatus may comprise a tunable light source for cycling through a plurality of frequency bands of light for scanning a length of the waveguides for an obstruction (e.g. a touch). The apparatus may be used in place of the plurality of light source/photo detector pairs found in conventional touch screen devices.

Abstract: In a touch screen having a flexible outer membrane with a first conducting surface, a backing surface with a second conductive surface, and sensors to detect contact between the first conducting surface and the second conducting surface, the improvement comprising the flexible outer membrane, wherein the flexible outer layer consists of an ultra-thin glass layer, a polymer layer; and an optical adhesive between the ultra-thin glass layer and the polymer layer, the optical adhesive holding the ultra-thin glass layer to the polymer layer.

Abstract: In a touch screen having a flexible outer membrane with a first conducting surface, a backing surface with a second conductive surface, and sensors to detect contact between the first conducting surface and the second conducting surface, the improvement comprising the flexible outer membrane, wherein the flexible outer layer consists of an ultra-thin glass layer, a polymer layer; and an optical adhesive between the ultra-thin glass layer and the polymer layer, the optical adhesive holding the ultra-thin glass layer to the polymer layer.

Abstract: There is described a method of forming a touch screen laminate for use in a resistive touch screen display, the method comprising the steps of bonding a layer of ultra-thin glass to a polymer layer by means of an optical adhesive applied uniformly between the glass layer and the polymer layer and applying a non-electrically conductive insulating layer to a lower surface of the polymer layer in a peripherally extending band.

Abstract: There is described a method of forming a touch screen laminate for use in a resistive touch screen display, the method comprising the steps of bonding a layer of ultra-thin glass to a polymer layer by means of an optical adhesive applied uniformly between the glass layer and the polymer layer and applying a non-electrically conductive insulating layer to a lower surface of the polymer layer in a peripherally extending band.

Abstract: In a touch screen having a flexible outer membrane with a first conducting surface, a backing surface with a second conductive surface, and sensors to detect contact between the first conducting surface and the second conducting surface, the improvement comprising the flexible outer membrane, wherein the flexible outer layer consists of an ultra-thin glass layer, a polymer layer; and an optical adhesive between the ultra-thin glass layer and the polymer layer, the optical adhesive holding the ultra-thin glass layer to the polymer layer.

Abstract: In a touch screen having a flexible outer membrane with a first conducting surface, a backing surface with a second conductive surface, and sensors to detect contact between the first conducting surface and the second conducting surface, the improvement comprising the flexible outer membrane, wherein the flexible outer layer consists of an ultra-thin glass layer, a polymer layer; and an optical adhesive between the ultra-thin glass layer and the polymer layer, the optical adhesive holding the ultra-thin glass layer to the polymer layer.