An example method of indicating to a user that a biometric input was authenticated. The method is performed at a computing system comprising a processor, memory, a first housing that includes a primary display, and a second housing containing a physical keyboard, a touch-sensitive secondary display, and a biometric input device. The method includes displaying, at the primary display, a web page that identifies items for purchasing, and detecting a selection of an affordance displayed on the web page. In response, displaying, on touch-sensitive secondary display, an alert prompting a user to provide a biometric input to the biometric input device, and detecting a biometric input on the biometric input device that is in second housing. In response to detecting the biometric input, and in accordance with a determination that the biometric input has been authenticated, displaying on the display an indication that purchase of the items has been validated.

A portable electronic device having a rollable display structure is proposed. When the rollable display panel is unrolled from the display drum inside the housing and drawn out of the housing, a self-standing guide unit guides the rollable display panel to be curved in an arc shape so that the rollable display panel stands upright on its own, whereby the rollable display panel may be maintained in an unrolled state without an additional structure. In this way, the size and weight of a product may be reduced, so that portability of the portable electronic device may be improved.

A fingerprint reader/power button system includes a base member defining base leg apertures extending into the base member. A spring member engages the base member to provide a spring force that is directed away from the base member. Spring legs on the spring member define respective spring leg apertures that are located adjacent respective base leg apertures. A support member engages the spring member and includes support legs that are configured to extend through the spring leg apertures and into the base leg apertures. A power actuator element connected to the support member is configured to engage a power actuator engagement element when an actuation force on the support member overcomes the spring force. A fingerprint reader connected to the support member is configured to read a fingerprint from a finger that engages a fingerprint reader surface on the fingerprint reader.

The disclosure provides an electronic device. The electronic device includes a computer system, a light emitting module, and a control unit. The computer system is adapted to execute a boot procedure, the boot procedure lasting for a first time period. A light emitting module includes a plurality of indicator lights, each indicator light providing an indication function. The control unit is electrically connected to the light emitting module. The control unit controls the indicator lights to generate a first light emitting effect within a second time period when the computer system enters the boot procedure. The second time period is shorter than the first time period.

A method includes determining a physical location of each of a plurality of peripheral devices communicatively coupled to a host computing device, the each of the plurality of peripheral devices including a computer mouse; generating a lighting sequence configured to activate visual output elements on the each of the plurality of peripheral devices; and modifying the lighting sequence based on the physical location of the computer mouse relative to at least one of the other plurality of peripheral devices. In some aspects, the plurality of peripheral devices further includes a mouse pad, and modifying the lighting sequence for the computer mouse is based on the location of the computer mouse relative to its position on the mouse pad. In some cases, modifying the lighting sequence for the computer mouse is based on the location of the computer mouse relative to its position to the other plurality of peripheral devices.

A computer input device that includes a keyboard base comprising a touch-sensitive display device and selectively removable from a keyboard and a joystick couplable to the touch-sensitive display device.

A keyboard device having functionality of physiological parameter measurement is disclosed, which comprises a keyboard main body and at least two physiological signal sensing units. The physiological signal sensing unit comprises a lighting element and a light sensing element. Moreover, the physiological signal sensing unit further comprises a touch plane that is exposed out of the surface of the keyboard main body. When a user is typing the button keys of the keyboard main body, the user can touch the touch plane by one finger thereof, such that the physiological parameter calculating unit receives an optical signal through the physiological signal sensing unit, thereby calculating physiological parameters of the user after applying a physiological parameter calculating process to the optical signal. The calculated physiological parameter comprises heartbeat and heart rate.

A method can include: determining a physical location of each of a plurality of peripheral devices communicatively coupled to a host computing device; generating a lighting sequence configured to activate visual output elements on the each of the plurality of peripheral devices, wherein the lighting sequence is a time based sequence that traverses the plurality of peripheral devices; and modifying a timing parameter of the lighting sequence based on the respective physical location of each of the plurality of peripheral devices. In some cases, modifying the lighting sequence can include: determining a distance between at least two of the plurality of peripheral devices and modifying the timing parameter of the sequential pattern based on the distance between the at least two of the plurality of peripheral devices.

A sensor determining coordinates of a proximal object, including a one-dimensional array of alternating light emitters and detectors, including a plurality of light emitters projecting light along a detection plane, and a plurality of light detectors detecting reflections of the projected light, by a reflective object in the detection plane, and a plurality of lenses mounted and oriented relative to the emitters and the detectors such that the light detectors receive maximum intensity when light enters a corresponding lens at a first particular angle, whereby for each emitter-detector pair, light emitted by the emitter of that pair passes through one of the lenses and is reflected by the object back through one of the lenses to the detector of that pair when the object is located at one of a set of positions in the detection plane, that position being associated with that emitter-detector pair.

A foldable computing device provides user interface (“UI”) transitions and optimizations while operating in a productivity mode. When the foldable computing device is operating in productivity mode, it can present a UI below a hardware keyboard placed over a display region and occluding only a top portion of the display region or a software keyboard presented in the display region occluding only the top portion of the display region. If the hardware keyboard or the software keyboard occlude only the bottom of the display region, a UI can be shown above the hardware keyboard or the software keyboard. The foldable computing device can adjust the position of UI windows that are occluded when the hardware or software keyboard is placed on the display region. The foldable computing device can move the UI windows back to their original positions if the hardware or software keyboard no longer occlude the display region.