A cantilever section as a substrate for a sensor includes: a base section; a movable section connected to the base section; an arm portion as a support portion extending along the movable section from the base section when viewed in a planar view as viewed from a thickness direction of the movable section; and a gap portion formed to have a predetermined gap between the movable section and the arm portion when viewed in the planar view, in which a ridge portion formed as an etching residue having a top portion on the side facing the gap portion is provided on each of facing surfaces of the movable section and the arm portion in the gap portion, and the predetermined gap is a gap between a top portion of a first ridge portion which is the ridge portion formed at one of the movable section and the arm portion, and a top portion of a second ridge portion which is the ridge portion formed at the other of the movable section and the arm portion.

The disclosure discloses an acceleration sensor, where the acceleration sensor comprises: a housing, and a mass block in the housing and connected with the housing via at least two hanging beams, where an auxiliary buffer component is further provided between the mass block and a bottom surface of the housing, and an elastic coefficient of the auxiliary buffer component decreases as force applied thereon increases.

Systems and methods for evaluating the performance of an athlete using a strain gauge is described. In some embodiments, the measurement system comprises a strain gauge and a central processing device. The strain gauge can include a power source, an inertial measurement unit (IMU) comprising a load cell, a microcontroller, and a wireless communication module. The strain gauge can be configured to output strain data at a rate of at least 1 kHz and the central processing device can be configured to receive the strain data transmitted from the wireless communication module.

A transduction detection device includes a substrate, at least one movable ground relative to the substrate and a suspended stress gauge provided with a piezoresistive element which includes a first anchoring and a second anchoring, different from the first anchoring, relative to the movable ground, wherein it includes at least one thermal dissipator element thermally conductively connected: to a connection portion of the piezoresistive element located outside of the anchorings, and to a thermal discharge part.

A signal processing apparatus according to an embodiment of the present technology includes an acceleration arithmetic unit. The acceleration arithmetic unit extracts, on a basis of a first detection signal and a second detection signal, the first detection signal including information related to an acceleration along at least a uniaxial direction and having an alternating-current waveform corresponding to the acceleration, the second detection signal including the information related to the acceleration and having an output waveform in which an alternating-current component corresponding to the acceleration is superimposed on a direct-current component, a dynamic acceleration component and a static acceleration component from the acceleration.

A sensor unit includes a first sidewall, a second sidewall, a third sidewall connected to one end of the first sidewall and one end of the second sidewall, and a fourth sidewall opposed to the third sidewall of a container including a lid, a first connector, and a second connector. The first connector is attached to the first sidewall further on the side of the fourth sidewall than the side of the third sidewall. The second connector is attached to the second sidewall further on the side of the third sidewall than the side of the fourth sidewall.

In a physical quantity sensor, a first substrate has a recess depressed from a second surface to provide a thin film section adjacent to a first surface, and a second substrate has a first surface bonded to the first surface of the first substrate, and has a hollow depressed from the first surface and facing the recess. The recess and the hollow have such sizes that a projected line defined by projecting an end of a bottom surface in the recess to the first surface of the first substrate surrounds an open end of the hollow. When the thin film section is displaced toward the hollow, a maximum tensile stress is generated at a position on a rear surface of the thin film section intersecting an extended line along a normal direction to the first surface of the first substrate and passing through the open end of the hollow.

The present invention provides a sensor with a simple structure which can precisely sense movement, etc., the sensor comprising: a head; and a support which is disposed to support one side of the head, wherein the support comprises: a first support portion for supporting the head; a second support portion which supports the head and is spaced apart from the first support portion; a first extension portion which is extended from the first support portion; a second extension portion which is extended from the second support portion; and a sensing portion which senses the deformation of the first extension portion and the second extension portion.

A sensor includes a weight body, a frame which is located so as to surround the weight body when viewed from above, a beam part which is provided with flexibility and in which a first end is connected to the weight body and a second end is connected to the frame, and a detection part which is provided on the beam part and detects deformation of the beam part as an electric signal. The beam part includes a main part in which a cross-sectional shape in a direction perpendicular to a longitudinal direction connecting the first end and the second end is a rectangular shape, and an extending part which protrudes from at least one of an upper surface or a lower surface of the main part and extends in the longitudinal direction or extends in a width direction perpendicular to the longitudinal direction when viewed from above.

An impact sensor for a vehicle. The impact sensor includes at least one strain-sensitive sensor element which comprises a sensor material, and at least two terminals, between which the sensor material is electrically connected. The sensor material is a metal-containing carbon material.