A keyswitch assembly includes a switch module, a support mechanism, and a blocking mechanism. The switch module includes a substrate, a signal generator, and a signal sensor. The signal generator provides a sensing signal. The signal sensor receives the sensing signal to obtain a sensing intensity. The support mechanism is disposed on the substrate. A top portion of the support mechanism moves in response to a pressing force. The blocking mechanism includes a pivoting portion rotatably disposed on the substrate, a connecting piece extending from the pivoting portion and movably connected to the support mechanism to be driven by the top portion to swivel relative to the substrate, and a blocking piece extending from the pivoting portion and driven by the connecting piece to be inserted into or escape from the gap between the signal generator and the signal sensor to change the magnitude of the sensing intensity.

Described is a system for producing an acoustic field from a plurality of ultrasonic transducer arrays, each of which has known relative positions and orientations. The acoustic field comprises a carrier wave and a modulated wave. The carrier wave has a plurality of modulated focal areas. A plurality of control points having a known spatial relationship relative to at least one of the plurality of ultrasonic transducer arrays is used. The plurality of ultrasonic transducer arrays are calibrated by using the relative position of each of the plurality of ultrasonic transducer arrays.

A keyswitch structure includes a base plate, a keycap, a lift mechanism connecting the keycap and the base plate, a movable part movably disposed relative to the base plate, a linking support, and a magnetic part on the base plate. The linking support has a pivotal connection portion, a magnetic portion, and a driving portion. The magnetic part and the magnetic portion produce a magnetic attraction force therebetween. When the movable part is located at a first position, the pivotal connection portion is rotatably disposed on a protruding portion of the movable part, and the magnetic attraction force drives the keycap through the linking support to move away relative to the keycap. When the movable part moves from the first position to a second position, the protruding portion moves away, so that the pivotal connection portion falls down and the keycap moves toward the base plate.

A multi-directional input device includes an operation knob, a plurality of direction setting switches, and a sensation generation unit. The operation knob is configured to be operable in multiple operation directions. The plurality of direction setting switches are configured to be turned on by being pressed when the operation knob is operated. The sensation generation unit is configured to generate different operation sensation from operation sensation generated by the direction setting switches. Sensation is generated by the sensation generation unit after at least one of the plurality of direction setting switches has been turned on in a predetermined operation direction out of the multiple operation directions.

An electrical switch includes a base, an actuating rod comprising a lateral wall guided in a bore of the base, a return spring for the rod which moves with respect to the base. The return spring comprises a last elastic turn which, during the actuating travel of the rod, bears against an abutment surface of the base and which cooperates with a ramp formed in the side wall which deforms it radially. The bore has a series of axial ribs projecting into the bore, each of which is slidably received in a complementary axial groove formed in the side wall. A radial upper end facet of each axial rib forms a portion of the abutment surface.

A control device configured for use in a load control system to control one or more electrical loads external to the control device may include an antenna and an actuation member having a front surface defining a touch sensitive surface configured to detect a touch actuation along at least a portion of the front surface. The control device may include a main printed circuit board (PCB) comprising a control circuit, an antenna PCB connected to the main PCB, a tactile switch(es), a controllably conductive device, and a drive circuit operatively coupled to a control input of the controllably conductive device for rendering the controllably conductive device conductive or non-conductive to control the amount of power delivered to the electrical load. The antenna may extend substantially perpendicular from the main PCB through an opening in the yoke and into a cavity defined by the actuation member and the yoke.

A momentary electrical push switch that can be configured for 2 or more activation positions. The switch has a top surface, or “key” top, which is pressed down upon in different areas to actuate the switch's different activation positions. The key top can be of various shapes, such as quadrangles, circle, hexagon, etc., or irregular shapes, to suit a particular application. The key top can be divided into multiple segments, or activation zones, each corresponding to a different activation position of the switch. The key allows free-form movement when pressing down upon it, without requiring the user to use specific or narrowly-defined motions to actuate the various activation positions.

A touch sensing device including a housing, a movable part, a covering, and a lifting actuator. The movable part is relatively movable within an opening of the housing relative to an edge portion of the opening, between first and second heights. The covering includes a flexible layer covering at least the edge portion and the movable part. The flexible layer includes first and second portions directly or indirectly fixed to the edge portion and to the movable part, respectively. The flexible layer can partly flex and stretch or partly shrink in accordance with a relative movement of the second portion relative to the first portion, from a third height to a fourth height, or vice versa. The lifting actuator can move the movable part or the edge portion to relatively move the movable part, from the first height to the second height, or vice versa, relative to the edge portion.

A pressing device includes a base board, an upper board unit that is disposed over the base board, and an intermediate unit that is disposed between the base board and the upper board unit. The upper board unit includes a panel, a circuit board, and a tact switch. The intermediate unit includes a middle portion that corresponds in position to the tact switch, a surrounding frame member, and a plurality of interconnecting board members. When the upper board unit is pressed, at least one of the interconnecting board members is deformed, and the middle portion is driven to convert the tact switch from an initial state to a triggered state.

An input device includes an operation unit to receive an operation, at least one load detection unit to detect a load on the operation unit and detect the load according to capacitance between a pair of conductors, and a substrate on which an electrode as one of the pair of conductors of the load detection unit is arranged. The load detection unit includes the electrode, an operation deformation portion to deform in response to an operation on the operation unit, and a detection electrode as the other of the pair of conductors. The electrode, the operation deformation portion and the detection electrode are located between the substrate and the operation unit and arranged in this order from the substrate.