There is provided a control circuit configured for a touch panel. The touch panel includes: a first resistive film and a second resistive film installed with a gap between the first resistive film and the second resistive film; and a first terminal and a second terminal that extend from two opposing sides of the first resistive film. The control circuit includes: a driving circuit configured to apply a driving voltage between the first terminal and the second terminal; and a current detection circuit configured to generate a digital current detection value that indicates a current amount obtained by subtracting a predetermined current from a panel current flowing between the first terminal and the second terminal.

An input device includes a plurality of sensor electrodes and a processing system that is operable in at least a first mode or a second mode. The processing system is configured to receive an input current from a pair of the sensor electrodes. When operating the first mode, the processing system is configured to measure a capacitance across the pair of sensor electrodes based on the received input current. When operating the second mode, the processing system is configured to measure a resistance between the pair of sensor electrodes based on the received input current.

A system is for detecting a location of a touch input on a surface of a propagating medium. The system includes a transmitter coupled to the propagating medium and configured to emit a signal. The signal has been allowed to propagate through the propagating medium and the location of the touch input on the surface of the propagating medium is detected at least in part by detecting an effect of the touch input on the signal that has been allowed to propagate through the propagating medium. The system includes a piezoresistive sensor coupled to the propagating medium. The piezoresistive sensor is configured to at least detect a force, pressure, or applied strain of the touch input on the propagating medium.

A physical disturbance sensor includes a plurality of piezoresistive elements configured in a resistive bridge configuration. A signal transmitter is electrically connected to the physical disturbance sensor and configured to send an encoded signal to the piezoresistive elements of the resistive bridge configuration. A signal receiver is electrically connected to the piezoresistive elements and configured to receive a signal from the physical disturbance sensor. The received signal from the physical disturbance sensor is correlated with the sent encoded signal in determining a measure of physical disturbance.

A touch sensitive control system is disclosed, capable of providing touch activated control for use on substrate surfaces such as walls, flooring, doors, furniture, cabinetry, vehicles and machinery. The system may find particular application in large area substrates such as building walls, floors or ceilings, but may alternatively or additionally find application in any other non-active, non-electronic substrate such as furniture, cupboard doors or drawers, or tables for example.

The touch sensitive system comprises at least one electrically active layer having at least one electrical property and configured to be applied to the substrate and an electronic controller. The electrically conductive active layer is configured to have an electrical connection with the electronic controller wherein a differentiated touch on the substrate disrupts the electrical property of the electrically active layer; and wherein the disruption is detected by the electronic controller to provide a control signal. The differentiated touch is selected from: one or more of multiple sequential touches, and/or one or more touches of extended duration.

A sensor includes a plurality of piezoresistive elements and a plurality of electrical connection terminals. The plurality of piezoresistive elements are fabricated on a first side of a substrate. A second side of the substrate is configured to be coupled to an object where a physical disturbance is to be detected. A plurality of electrical connection terminals are coupled to the first side of the substrate.

The invention relates to the use of the modulation of an audio and/or visual signal by a variation in the impedance of at least one contact with the skin of at least one user, for the maintenance and/or development of the user's physical and/or mental abilities.

The invention comprises the use of a device (100) for controlling the delivery of a medium, said device comprising: a first skin electrode (105) configured to generate electric waves, positioned against the skin of a first user; a second skin electrode (110) configured to capture electric waves, positioned against the skin of a second user, where the second user can be the first user; a detector (115) for detecting the value of an impedance parameter of the junction connecting the electrodes and passing through the contact with the skin of each user; and a control means (120) configured to transmit a medium-delivery command according to the value detected.

A fabric-based item may include fabric formed from intertwined strands of material. The strands of material may include extruded strands. Strand extrusion equipment may have electrically adjustable sources such as one or more sources of different polymers, dyes, particles, wire, and other elements to be incorporated into an extruded strand. The properties of the strands such as strand stiffness, strand diameter, conductivity, magnetic permeability, opacity, color, thermal conductivity, sand strength, may be varied along their lengths. Fabric formed from the strands may have different areas with different properties. Markers may be formed from particles at particular locations along the lengths of the strands, may be optical marker structures formed from circumferential rings of ink or other visible material on the strands, or may be other markers that can be sensed using electrical sensing, magnetic sensing, optical sensing, or other types of sensing when forming fabric from the strands.

A flexible sensor is provided. A further aspect employs a sensor apparatus including pressure or force sensing layers or sheets in addition to location sensing layers or sheets. In another aspect, an electrical sensing circuit and flexible films are used to sense pressure and/or location of a contacting object. In another aspect, a compressible polymer includes conductive particles therein such that the compressible polymer changes electrical resistance when compressed to indicate a force or location. Still another aspect has stacked sandwiches of pressure and/or location sensing films, layers or sheets.

A conductive film includes a film substrate and a conductive layer formed on at least one surface of the film substrate. The film substrate and the conductive film have elongation of 10% or more. Ten-point average roughness Rz of the surface of the film substrate on at least a conductive layer side is 0.05 to 0.5 m, and an average interval Sm of unevenness is 0.1 to 1 m.