A sensor unit manufacturing method includes: a core metal insertion process of inserting a core metal member having a length dimension smaller than a length dimension of a core metal accommodation portion into a predetermined location (a section of a curving portion) extending along a longitudinal direction of the core metal accommodation portion; and a bending process of bending the section (the section of the curving portion) of a fixation base portion, into which the core metal member is inserted, following a curved shape of a sensor bracket.

Provided is a metal touch sensing apparatus in which recognition performance thereof is improved, a plurality of touch parts are successively manipulated to enter into a specific mode, thereby preventing a refrigerator from being malfunctioned, and touch sensitivity of the refrigerator to be touched for the manipulation is visually adjusted, and a home appliance including the touch apparatus and a method for controlling the same.

An appliance that includes: a front panel having a touch point; a touch board including: a first side attached to a location on a rear surface of the front panel, the location corresponding to the touch point; a second side opposite to the first side; a pressing portion; and one or more holes defined around the pressing portion and configured to enable an elastic movement of the pressing portion; a holder that is attached to the second side of the touch board, the holder having a receiving portion; a piezo disc configured to be inserted in the receiving portion of the holder and contact the pressing portion; a guide board having a seating hole configured to receive the holder and the piezo disc; and a first adhesive member attached to the first side of the touch board and configured to attach to the rear surface of the front panel.

A system includes a piezoelectric capacitor assembly and signal processing circuitry coupled to the piezoelectric capacitor assembly. The piezoelectric capacitor assembly includes a piezoelectric member and piezoelectric capacitors located at respective lateral positions along the piezoelectric member. Each piezoelectric capacitor includes: (1) a respective portion of the piezoelectric member, (2) a first electrode, and (3) a second electrode. The first and second electrodes are positioned on opposite side of the piezoelectric member. The piezoelectric capacitors include piezoelectric force-measuring elements (PFEs). The PFEs are configured to output voltage signals between the respective first electrode and the respective second electrode in accordance with a time-varying strain at the respective portion of the piezoelectric member between the respective first electrode and the respective second electrode resulting from a low-frequency mechanical deformation. The signal processing circuitry is configured to read at least some of the PFE voltage signals.

A control device which allows an operator/user to follow the user's anatomical movement by following natural hand rotation, includes two independent detection sensors or sensor portions embedded in two different parts of the device, one in a fixed part and one in a mobile or rotative part, with resistance to mutual disturbance between the two. The device includes a knob portion rotatable about an axis of rotation, at least one sensor configured to sense a rotational position of the knob in relation to the axis of rotation, circuitry adapted to at least provide electrical power to the rotative knob portion, circuitry adapted to transmit the sensed rotational position of the knob, and a base portion rotatably coupled to the knob portion.

A touch key structure includes a touch panel including a key area at a front side of the touch panel, a circuit board provided behind the touch panel and including a sensing electrode corresponding to the key area, and a conductive medium provided between the key area and the sensing electrode.

The disclosure relates to solid state relay circuit for switching an electrical load. The solid state relay circuit may include a relay transistor; and a driver circuit comprising a constant current source. The driver circuit is configured and arranged to switchably operate the relay transistor, and the relay transistor is configured and arranged to switchably operate the electrical load.

A pressing structure of a mouse includes a base, a circuit board mounted on the base, at least one electronic switch mounted on the circuit board, an upper cover mounted on the base, and a button shell. A rear end wall of the at least one opening protrudes downward and extends towards a front end wall of the at least one opening to form a buckling block. A bottom of the buckling block is recessed inward to form a first accommodating groove equipped with a first magnet. The button shell has at least one button. The at least one button protrudes downward to form at least one contact portion. A rear surface of the at least one contact portion is recessed inward to form a buckling space corresponding to the buckling block. The at least one contact portion is equipped with a second magnet.

A mouse includes a lower shell, an upper shell covered on the lower shell, a circuit board and a pressing button. The upper shell is spaced from the lower shell to form an accommodating space between the lower shell and the upper shell. The upper shell has at least one elastic arm. The circuit board fastened in the accommodating space is equipped with at least one electronic switch corresponding to the at least one elastic arm. The at least one electronic switch has a touching element. The pressing button is covered on the upper shell. The pressing button has at least one touching board which protrudes downward to form at least one pressing block. The at least one elastic arm is received in the at least one pressing block. The at least one pressing block abuts against the touching element.

Disclosed are an inductive force sensor and a method of operating the same. An inductive force sensor according to an embodiment of the present invention includes a reference resonance circuit, a first resonance circuit, and a determination circuit configured to obtain information about a first resonant frequency, attributable to first inductance due to an inductive coil based on the displacement between a target and the inductive coil formed by an external force input in a Z-axis direction, and a reference resonant frequency. The determination circuit determines the displacement of the target and the external force in the Z-axis direction based on the first resonant frequency and the reference resonant frequency.