Abstract: In a capacitive touch sensor device, to avoid floating touches causing signal inversion in mutual capacitance measurements, a segmented conductive layer of conductive material is embedded in the touch panel. The segmented conductive layer comprises a plurality of segments of the conductive material which are separated by gaps. The segmented conductive layer effectively pre-loads the mutual capacitance of the touch sensor to the same or similar level of that of a floating touch of the maximum size for which it is desired to avoid signal inversion.

Abstract: In a capacitive touch sensor device, to avoid floating touches causing signal inversion in mutual capacitance measurements, an electrode pattern is used of the type in which the mutual capacitance arises primarily from co-extending electrode portions of the drive and sense electrodes separated by a gap G. The pattern is dimensioned such that the sum of the gap G between co-extending drive and sense electrode portions and the widths Wy of the sense electrodes is made sufficiently small to avoid signal inversion. Namely, the width, Wy, plus the gap, G, is made less than or equal to one of: 4, 3 or 2 times the distance from the touch sensor electrodes to the touch surface, this distance being the touch panel thickness, h.

Abstract: A capacitive touch sensor device comprising set of crossing X and Y electrodes whose crossing points form a two-dimensional array of nodes which define a touch sensitive area. As well as the main electrode spines which cross, referred to as zeroth order electrode branches, the electrodes have higher order branches, some of which interdigitate. By varying the dimensions of the electrode branches, such as width and length, the overall area of the X and Y electrodes can be varied relatively independently of each other. It is therefore possible to produce an electrode pattern in which the self capacitances of the X and Y electrodes have a certain ratio, e.g. unity, and thereby compensate for the aspect ratio of the touch sensitive area, and/or to have a certain absolute value, e.g. in order not to overload a touch-sensor controller to which the sensor is to be connected.

Abstract: A capacitive touch sensor device comprising set of crossing X and Y electrodes whose crossing points form a two-dimensional array of nodes which define a touch sensitive area made up of rectilinear sub-areas bounded by adjacent pairs of X and Y electrodes. The main electrode branches are referred to as zeroth order branches, since, in each sub-area, there are also higher order branches arranged such that some higher order X branches interdigitate with some higher order Y branches separated by a gap suitable for making a mutual capacitance measurement. The electrode branches are implemented as a fine mesh. The fine mesh comprises criss-crossing lines of conductive material which have gaps in between that are free of conductive material. Some of the criss-crossing lines include breaks formed by absence of individual length portions of the criss-crossing lines that form the mesh.

Abstract: In a capacitive touch sensor device, to avoid floating touches causing signal inversion in mutual capacitance measurements, an electrode pattern is used of the type in which the mutual capacitance arises primarily from co-extending electrode portions of the drive and sense electrodes separated by a gap G. The pattern is dimensioned such that the sum of the gap G between co-extending drive and sense electrode portions and the widths Wy of the sense electrodes is made sufficiently small to avoid signal inversion. Namely, the width, Wy, plus the gap, G, is made less than or equal to one of: 4, 3 or 2 times the distance from the touch sensor electrodes to the touch surface, this distance being the touch panel thickness, h.

Abstract: A capacitive touch sensor device comprising set of crossing X and Y electrodes whose crossing points form a two-dimensional array of nodes which define a touch sensitive area made up of rectilinear sub-areas bounded by adjacent pairs of X and Y electrodes. The main electrode branches are referred to as zeroth order branches, since, in each sub-area, there are also higher order branches arranged such that some higher order X branches interdigitate with some higher order Y branches separated by a gap suitable for making a mutual capacitance measurement. The X and Y electrodes are designed so that they fill the touch sensitive area relatively sparsely, which reduces the electrodes' self capacitance, so that charge time can be kept low. The low fill factor also lends itself to a high degree of interdigitation of the higher order electrode branches.

Abstract: In a capacitive touch sensor device, to avoid floating touches causing signal inversion in mutual capacitance measurements, a segmented conductive layer of conductive material is embedded in the touch panel. The segmented conductive layer comprises a plurality of segments of the conductive material which are separated by gaps. The segmented conductive layer effectively pre-loads the mutual capacitance of the touch sensor to the same or similar level of that of a floating touch of the maximum size for which it is desired to avoid signal inversion.

Abstract: A capacitive touch sensor device comprising set of crossing X and Y electrodes whose crossing points form a two-dimensional array of nodes which define a touch sensitive area. As well as the main electrode spines which cross, referred to as zeroth order electrode branches, the electrodes have higher order branches, some of which interdigitate. By varying the dimensions of the electrode branches, such as width and length, the overall area of the X and Y electrodes can be varied relatively independently of each other. It is therefore possible to produce an electrode pattern in which the self capacitances of the X and Y electrodes have a certain ratio, e.g. unity, and thereby compensate for the aspect ratio of the touch sensitive area, and/or to have a certain absolute value, e.g. in order not to overload a touch-sensor controller to which the sensor is to be connected.