An electronic apparatus includes a storage chassis, an electronic component, an antenna circuit, and a proximity sensor circuit. A pair of main faces facing each other in the thickness direction and end faces of the storage chassis define a storage space. The electronic component is disposed in the storage space. The antenna circuit is disposed in the storage space so that at least a part of the antenna circuit overlaps the electronic component when viewed in the thickness direction. The proximity sensor circuit is connected to the antenna circuit, and detects proximity of an object based on a physical quantity that changes according to proximity of the object. The antenna circuit includes a substrate, an antenna element, and an antenna ground. The proximity sensor circuit is located in an end space defined between the electronic component and the end face.

A keyboard module, adapted to an electronic device, is provided. The keyboard module includes a bottom plate, a flexible circuit layer, a first key structure and a second key structure. The bottom plate includes a first area and a second area. The flexible circuit layer covers the first area and the second area. A first key structure is arranged at the position of the flexible circuit layer corresponding to the first area. A second key structure is arranged at the position of the flexible circuit layer corresponding to the second area. The height of the first key structure is greater than the height of the second key structure. An electronic device with the keyboard module is also provided.

Systems, methods, and non-transitory computer readable media for virtually extending a physical keyboard are disclosed. In one implementation, a non-transitory computer readable medium contains instructions that cause a processor to: receive image data representing a keyboard placed on a surface from an image sensor associated with a wearable extended reality appliance; determine that the keyboard is paired with the wearable extended reality appliance; receive an input for causing a display of a virtual controller with the keyboard; display, via the wearable extended reality appliance, the virtual controller in a first location on the surface, with original spatial orientation relative to the keyboard; detect a movement of the keyboard to a different location on the surface; and in response to the detected movement, present the virtual controller in a second location on the surface, with a subsequent spatial orientation relative to the keyboard that corresponds to the original spatial orientation.

An electronic device includes a host, a main display, an auxiliary display, and a hinge mechanism. The auxiliary display is located between the host and the main display and includes a sliding part and a lifting part. The sliding part is slidably connected to the host. The hinge mechanism includes a first bracket, a second bracket pivotally connected to the first bracket, and a third bracket pivotally connected to the second bracket. The first bracket is secured to the host, and the second bracket is secured to the main display. The third bracket is secured to the lifting part of the auxiliary display.

A portable computing device is disclosed which may include a base element, a lid element, a first motion sensor, a second motion sensor, a processor, and an eye tracking system. The first motion sensor may be disposed in the base element. The second motion sensor may be disposed in the lid element. The processor may be configured to control the first motion sensor to detect first motion information, control the second motion sensor to detect second motion information; and determine final motion information based at least in part on the first motion information and the second motion information. The eye tracking system may be configured to determine a gaze position of a user based at least in part on the final motion information, wherein the processor is further configured to execute one or more control processes based at least in part on the determined gaze position meeting a predetermined condition.

A display member and a base member. A support member can be attached between the display member and the base member. The support member can extend from the display member. A magnetic latch can magnetically attract an edge of the display member to one of the support member and the base.

An optical touch sensor is disclosed which includes a plurality of light emitting bare dies attached directly to a first printed circuit board and placed at a first edge bordering an object surface, the plurality of light emitting bare dies being commonly encapsulated in a first encapsulation having a first reflective surface, and a plurality of light detecting bare dies attached directly to a second printed circuit board and placed at a second edge bordering the object surface across from the first edge, the plurality of light detecting bare dies being encapsulated commonly in a second encapsulation having a second reflective surface, wherein light emitted from the plurality of light emitting bare dies can be detected by the plurality of light detecting bare dies through reflections of the first and the second reflective surface, and wherein a light beam traveling from the first reflective surface to the second reflective surface is above and substantially parallel to the object surface.

One embodiment provide an electronic device, including: a housing having an upper face and a lower face; a keyboard disposed in the upper face of the housing; a display part including a display; a hinge mechanism connecting the housing to the display part in a rotatable fashion; and a link mechanism that operates in conjunction with rotation of the display part to buffer the rotation of the display part when the display part is rotated beyond a predetermined angle with respect to the housing. Other aspects are described and claimed.

A key structure includes a supporting plate, a keycap, a scissors-type connecting element, a movable element and a coupling structure. The keycap is disposed over the supporting plate. The coupling structure is connected with the scissors-type connecting element and the movable element. For operating the key structure, the cooperation of the movable element and the coupling structure allows the keycap to be at a higher first height. Consequently, the tactile feel of depressing the key structure is enhanced. Moreover, the cooperation of the movable element and the coupling structure can lower the height of the keycap. Consequently, the key structure has a slim appearance.

Embodiments of keyboards having variations of electrically connecting keys to an internal component of an electronic device are described. Some embodiments include positioning several rows of conductive layers below several rows of keys. The conductive layers may be configured to receive a signal indicating a key has been depressed. Also, the internal component may be configured to scan the conductive layers to determine whether a key or keys have been depressed. In some embodiments, the conductive layers lie outside a portion of the electronic device in which internal components are traditionally located. In some embodiments, a substrate may be integrally connected with the keyboard. The substrate may receive some internal components of the electronic device.