A film resistor and a film sensor are disclosed. In an embodiment a film resistor includes a piezoresistive layer comprising a M.sub.1+nAX.sub.n phase, wherein M comprises at least one transition metal, A comprises a main-group element, and X comprises carbon and/or nitrogen, and wherein n=1, 2 or 3.

A film resistor and a film sensor are disclosed. In an embodiment a film resistor includes a piezoresistive layer comprising a M.sub.1+nAX.sub.n phase, wherein M comprises at least one transition metal, A comprises a main-group element, and X comprises carbon and/or nitrogen, and wherein n=1, 2 or 3.

A sensor device is disclosed comprising at least one deformable substrate, at least one transducer element formed in or on a surface area of a first side of the deformable substrate, at least one other transducer element formed in or on a surface area of a second side of the deformable substrate, and electrical conductors formed on and/or in the substrate for electrically connecting between and to the transducer elements.

A flexible resistor including a support made of electrically insulating material; at least one track made of an electrically conductive material incorporated in the support, and configured to be connected to an electric energy source; a foil made of electrically conductive material, having a surface fixed to a first face of the support, and a plurality of wings defined by foil portions cut and folded transversally to the surface.

A flexible resistor including a support made of electrically insulating material; at least one track made of an electrically conductive material incorporated in the support, and configured to be connected to an electric energy source; a foil made of electrically conductive material, having a surface fixed to a first face of the support, and a plurality of wings defined by foil portions cut and folded transversally to the surface.

A force sensitive resistor includes first and second electrical contacts, and a layer of deformable material impregnated with carbon nanotubes. The layer of deformable material is arranged between the first and second electrical contacts. A difference in the conductivity of the impregnated material caused by deformation of the material is detectable across the contacts. A method of manufacturing a force sensitive resistor includes the steps of providing first and second electrical contacts, and arranging a deformable material impregnated with carbon nanotubes between the first and second electrical contacts. Again, a difference in the conductivity of the impregnated material caused by deformation of the material is detectable across the contacts

This pressure-sensitive elastomer porous body is a cured product of an elastomer emulsion, which is obtained via an emulsion composition including, as a continuous phase, a liquid rubber material which is cured to form an elastomer, wherein a conductive agent is contained in an amount of 2.7-3.5 wt % with respect to the total amount of the emulsion composition, and the electric resistance value () rises as the compression ratio C (%) increases.

A pressure sensor includes: a base including an outer surface partially or entirely composed of a curved surface; a plurality of electrodes disposed on the outer surface of the base with spaces therebetween and including at least one signal electrode and at least one ground electrode; and at least one variable resistor made from conductive foam elastomer material and configured to be elastically compressed upon application of pressure and such that electric resistance between the signal electrode and the ground electrode decreases as the amount of the compression increases.

A pressure sensor includes: a base including an outer surface partially or entirely composed of a curved surface; a plurality of electrodes disposed on the outer surface of the base with spaces therebetween and including at least one signal electrode and at least one ground electrode; and at least one variable resistor made from conductive foam elastomer material and configured to be elastically compressed upon application of pressure and such that electric resistance between the signal electrode and the ground electrode decreases as the amount of the compression increases.

A force sensor comprising a force sensitive resistor having a common electrode and an electrode array separated by a force sensitive resistor material. The sensor includes a preload structure, where the preload structure imparts a force on the force sensitive resistor material. The sensor may also include a signal conditioning board to read a signal from the electrode array and convert it to a digital output.