A key structure includes a keycap, a pedestal and an elastic element. The keycap includes a main body and a coupling shaft. The pedestal includes a key slot. The key slot has an upper part and a lower part. The coupling shaft is penetrated through the upper part of the key slot and movable within the key slot upwardly or downwardly. The elastic element is installed in the lower part of the key slot. After an external force applied to the keycap is released, the elastic element is elastically restored, so that the keycap is returned to an original position. At the same time, the buffering elements in the key slot interfere with the coupling shaft. Consequently, an ascending speed of the keycap is reduced, and a click sound generated from the collision between keycap and the pedestal is reduced.

Aspects of the present disclosure are directed to systems, apparatuses, and methods for the projection of images onto keycaps of a computer keyboard.

A switch device described by this invention a reset assistant part arranged at the second end of male leg, and a ram, the reset assistant part provided with a holding station, both sidewalls of which are each provide with a saddle, both sides of the ram provided with a cam matching with the saddle, the ram hanging from the saddle through two cams. With the structure said above, not only a photoelectrical type switch of the scissor-leg structure is realized, but also the key is enabled to have an obvious stage sense and sound.

A keyboard device includes a substrate, a connection hook, a keycap, and a connecting member. The substrate has a top surface including an assembly area. The connection hook is disposed on the assembly area and includes a fixed seat fixed on the substrate, a standing portion, and a reinforcement block. The standing portion is extending from the fixed seat and extending in a direction away from the fixed seat. A hook portion is laterally extending from a top end of the standing portion, the hook portion has a bottom edge. The reinforcement block is connected to the standing portion and the bottom edge. The keycap is disposed on the assembly area. The connecting member is connected between the keycap and the assembly area. The connecting member includes a shaft slidably pivoted at the bottom edge. An inner side of the shaft includes an avoidance groove corresponding to the reinforcement block.

A touch pad structure includes a touch pad, a dome switch, and a buffer film. The touch pad includes a fulcrum end and a moving end opposite to the fulcrum end, and the touch pad has an outer surface and an inner surface opposite to the outer surface. The dome switch is disposed at the moving end and connected to the inner surface of the touch pad. The dome switch includes a switch body and a convex portion protruding from the switch body. The buffer film is attached to the inner surface of the touch pad and the dome switch. The buffer film covers the dome switch and has a perforation, and the convex portion of the dome switch is located inside the perforation.

Keyboards, input devices, and related systems include key mechanisms with keycaps and actuators that provide adjustable feedback in response to user input. The actuators are controllable to provide variable tactile force or audible feedback that is dependent upon the user input. Encoders are able to transduce a location or relative position of a keycap as it is being pressed over time, and a signal is provided to actuators to cause them to provide feedback corresponding to the position of the keycap as it moves. The feedback can change the feel or sound of the keycap based on the keycap positions, time of operation, velocity, user identity, and other factors. Thus, the feel or sound of a keyboard or related input device can be adjusted electronically for efficient testing and increased user customization and feedback modes.

The invention relates to an input device in the form of a single-hand keyboard, comprising a substantially flat housing (1) approximately in the shape of a quadrant of a circle, in which housing a first keyboard circuit board having associated first keys (2) is accommodated, the first keys (2) lying on a first housing side (3) and being arranged along concentric circular arc segments in the manner of a fan. A second keyboard circuit board having associated second keys (4) is accommodated in the housing (1), the second keys lying on the second housing side (5) facing away from the first housing side (3), and the layout of the second keys (4) being mirror-inverted with respect to the layout of the first keys (2). Furthermore, a detection element for determining the current orientation of the input device is provided in the housing (1). The detection element activates only the keyboard circuit board facing upward and deactivates the other keyboard circuit board, depending on the orientation.

An analog input device including at least one mounting panel and a matrix of analog push button assemblies mounted thereon. Each analog push button assembly including an analog pressure sensor including a pressure reception arrangement having an optical sensing sub-arrangement configured to measure an amount of light varied according to a pressure sensed at the pressure reception arrangement and an output terminal for outputting an analog signal corresponding to the amount of light measured, and a plunger element configured to exert the pressure on the pressure reception arrangement. The analog input device may include a multiplexer including an input side coupled to the push button assemblies and an output side; an analog-to-digital converter coupled to the output side of the multiplexer; a processor coupled to the analog-to-digital converter and configured to output a data packet; and a communication interface configured to transmit the data packet to a host computing device.

A keyboard includes a base plate, a plurality of key structures, and a light emitting assembly. The base plate includes a body and a plurality of optically transmissive members. The body has a plurality of hollow portions. The optically transmissive members are contained in the hollow portions, respectively. Each of the optically transmissive members has a light guiding portion and a plurality of connecting structures. The key structures correspond to the optically transmissive members, respectively. One of the key structures is connected to the connecting structures of one of the optically transmissive members. The light emitting assembly includes a driver circuit board and a plurality of light emitting units. The light emitting units are located on the driver circuit board. The driver circuit board is located on one of the surfaces of the base plate. The light emitting units are contained in the light guiding portion, respectively.

A touch module includes a touchpad assembly and a connection assembly. The connection assembly includes a main body, plural first coupling plates and plural protrusion posts. When the connection assembly is accommodated within a computer casing, the plural first coupling plates are penetrated through plural first openings of the computer casing and the plural protrusion posts are inserted into the corresponding fixing structures. The plural protrusion posts and the corresponding fixing structures are collaboratively formed as a hinge structure. While the touchpad assembly is pressed down, the connection assembly is swung relative to the computer casing by using the plural protrusion posts as the pivotal shafts, so that the touchpad assembly is correspondingly swung. Due to the hinge structure, the touchpad assembly is swung along a fixed direction. Consequently, the touch module is operated stably.