Stretchable electronic structure comprising one intrinsically fragile thin film integrated on or within a soft heterogeneous substrate. The invention also relates to a process for manufacturing such a structure.

Pressure sensors having ring-tensioned membranes are disclosed. A tensioning ring is bonded to a membrane in a manner that results in the tensioning ring applying a tensile force to the membrane, flattening the membrane and reducing or eliminating defects that may have occurred during production. The membrane is bonded to the sensor housing at a point outside the tensioning ring, preventing the process of bonding the membrane to the housing from introducing defects into the tensioned portion of the membrane. A dielectric may be introduced into the gap between the membrane and the counter electrode in a capacitive pressure sensor, resulting in an improved dynamic range.

A pressure measuring method, applied to a pressure measuring apparatus, comprising: measuring a first pressure sensing value of the pressure measuring apparatus, which corresponds to a first pressure in a test mode; measuring a second pressure sensing value of the pressure measuring apparatus, which corresponds to a second pressure in the test mode; generating a first corresponding function according to the first pressure, the second pressure, the first pressure sensing value and the second pressure sensing value; sensing a third pressure sensing value via the pressure measuring apparatus in a normal mode; and generating a third pressure according to the third pressure sensing value via the first corresponding function; wherein the pressure measuring apparatus operates at a first scan frequency. By this way, the pressure sensing value can be calibrated, to solve the issue that the pressure sensing values are affected by scan frequencies.

A strain body of a force sensor according to the present invention includes a tilting structure disposed between a force receiving body and a support body, a force-receiving-body-side deformable body connecting the force receiving body and the tilting structure, and a support-body-side deformable body connecting the tilting structure and the support body. The tilting structure includes a first tilting body that extends in a second direction orthogonal to a first direction and that is elastically deformable by the action of force in the first direction.

A pressure sensor is a pressure sensor that includes: a capacitive sensor electrode layer that includes a plurality of sensing units; a first reference electrode layer that faces a first surface of the sensor electrode layer; a second reference electrode layer that faces a second surface of the sensor electrode layer; an elastic layer disposed between the first reference electrode layer and the sensor electrode layer; and a gap layer disposed between the second reference electrode layer and the sensor electrode layer. In the pressure sensor, the sensor electrode layer, the first reference electrode layer, and the second reference electrode layer have a slit.

The integrated electronic device detects the pressure related to a force applied in a predetermined direction within a solid structure. The device includes an integrated element that is substantially orthogonal to the direction of application of the force. First and second conductive elements are configured to face an operating surface. A measure module includes first and second measurement terminals which are electrically connected to the first and second conductive elements, respectively. A detecting element is arranged in the predetermined direction such that the operating surface is sandwiched between the first and second conductive elements and this detecting element. An insulating layer galvanically insulates the first and second conductive elements. A layer of dielectric material is sandwiched between the detecting element and the insulating layer, and is elastically deformable following the application of the force to change an electromagnetic coupling between the detecting element and the first and second conductive elements.

A plate-like supporting body (200) is arranged below a plate-like force receiving body (100) and a deformation body (300) is connected between them. The deformation body (300) is provided with an elastically deformed portion (310) arranged along a connection channel (R1) which connects a first force receiving point (P1) with a second force receiving point (P2), a first base portion (320) and a second base portion (330) which support the elastically deformed portion (310) from below. The upper end of the first base portion (320) supports the vicinity of a first relay point (m1) on the connection channel (R1) so as to sway freely, and the upper end of the second base portion (330) supports the vicinity of a second relay point (m2) on the connection channel (R1) so as to sway freely. An arm-like member (312) which couples a pair of relay points (m1, m2) is used to lower the detection sensitivity of moment around an origin (O) which is exerted on the force receiving body (100), thereby easily adjusting the balance of detection sensitivity between moment and force.

Devices and methods are provided that facilitate improved input device performance. The devices and methods utilize a first electrode and a second electrode disposed on a first substrate and a deformable electrode structure. The deformable electrode structure overlaps the first electrode and the second electrode to define a variable capacitance between the first electrode and the second electrode that changes with the deformation of the deformable electrode structure. The deformable electrode structure comprises a spacing component configured to provide spacing between the deformable electrode structure and the first electrode and the second electrode. Finally, a transmission component is configured such that biasing the transmission component causes the deformable electrode structure to deform and change the variable capacitance. A measurement of the variable capacitance can be used to determine force information regarding the force biasing the transmission component.

The present invention concerns an elongated capacitive sensor for fluid monitoring. The sensor comprising: a fibre support made of a dielectric material or dielectric composite material; and a first electrode and a second electrode arranged longitudinally along the fibre support, the first and second electrodes forming together with the fibre support a capacitive sensing element whose capacitance is dependent upon one or more electrical properties of one or more materials inside the support and/or outside the support, and/or is dependent upon a change of materials configuration and associated overall change of one or more electrical properties inside the support and/or outside the support.

A flexible sensor that includes a printed circuit board (PCB), a capacitive structure on the PCB, and mechanical coupling sites. The PCB includes a slot extending from an outer edge of the PCB to an inner portion of the PCB, and the slot defines a first edge and a second edge facing the first edge. The first and second edges are separated by a gap when the PCB is in an unflexed state. The slot is configured to permit the PCB to flex so as to vary a relative position of the first edge with respect to the second edge. The capacitive structure on the PCB includes a first edge electrode on a portion of the first edge of the PCB, and a second edge electrode on a portion of a second edge of PCB. The second edge electrode is aligned with the first edge electrode across the slot.