In some examples, an electronic device includes an outer housing an outer housing including a recess to receive a peripheral module. In addition, the electronic device includes a mounting assembly to move the peripheral module into and out of the recess of the outer housing. The mounting assembly is moveably coupled to the outer housing. The mounting assembly includes a latch mechanism to removably attach the mounting assembly to the peripheral module. The mounting assembly includes a first electrical connector to removably connect to a second electrical connector of the peripheral module. The latch mechanism includes an arm and a lip to move into and out of engagement with a shoulder of the peripheral module. The lip is disposed along the arm.

A liquid cooling system includes a heat dissipating device with cooling pipes and a radiation structure arranged on the cooling pipes; a pump device, integrally arranged between the cooling pipes and generating power so that a coolant circulates within the cooling pipes; a heat absorbing device, attached to a heating device and having a heat conduction effect with the heating device; and a combination means for connecting a connecting unit to the pump device. On the basis of existing products, a liquid pump main body and a radiator are integrally arranged together, and the heat absorbing device is connected to the liquid pump main body via the combination means. In addition, the leakage at the tube connector and the occupied space is significantly reduced, the heat transfer effect is significantly improved, and the production and assembly costs are reduced, so that product assembly is convenient and efficiency is high.

An apparatus may comprise first and second auxiliary function units each one or more connector interfaces configured to be operably connected to one or more medical devices via mating engagement with one or more transmission lines. The apparatus can further include a user interface overlay panel overlying at least a portion of each of the first auxiliary function unit and the second auxiliary function unit. The user interface overlay panel comprises a user interface control portion operably coupled to each of the first auxiliary function unit and second auxiliary function unit to alter control settings of each auxiliary function unit in response to input at the user interface control portion. The user interface control portion further comprises a first and second user interface control areas arranged to align with the one or more connector interfaces of the respective first and second auxiliary function units.

Disclosed herein are radio frequency (RF) front-end structures, as well as related methods and devices. In some embodiments, an RF front-end package may include an RF package substrate including an embedded passive circuit element. At least a portion of the embedded passive circuit element may be included in a metal layer of the RF package substrate. The RF package substrate may also include a ground plane in the metal layer.

In one aspect, a device may include at least one processor, a touch-enabled display accessible to the at least one processor, and storage accessible to the at least one processor. The storage may include instructions executable by the at least one processor to identify a height of a user. Then, based on the height of the user, the instructions may be executable to one or more of determine a first location of the touch-enabled display at which to present a selector and then present the selector at the first location, and/or determine a second location of the touch-enabled display to use as an area at which touch input that is received will correspond to selection of the selector and then undertake an action associated with selection of the selector responsive to receipt of touch input to the area.

The present invention comprises a flexible display that surrounds the front surface of an electronic device and a control unit that controls operation of functions of the flexible display-based electronic device. The control unit may display a plurality of icons corresponding to an application or a specific function in at least one area among sub areas of the flexible display; the control unit may sense an input for selecting at least one icon among the plurality of icons; the control unit may sense an input for swiping the at least one selected icon to at least one area among main areas of the flexible display; and the control unit may process a control such that an application or a specific function, which corresponds to the at least one selected icon, is executed, and a screen corresponding to the execution is displayed in the main area corresponding to the sensed swipe input.

The present invention provides a quick-release structure for a display, comprising a stand, a first buckle ring and a second buckle ring. The stand includes a top base, and the top base is connected with a side of a top end of a support frame, where the top base has a front cover and a rear cover that cover oppositely each other. A clamping space is provided between the front cover and the rear cover, and the front cover has an outer periphery having a plurality of notches. The first buckle ring, accommodated and limited in the clamping space in a manner that the first buckle ring can be restored after being rotated, where the first buckle ring is provided with a pushing portion passed through the first limiting hole to push the first buckle ring to be rotated.

A display device includes a display panel having a display area and a non-display area at least partially surrounding the display area. A panel support sheet is disposed behind the display panel and has a first hole exposing the display area of the display panel. An optical sensor is disposed within the first hole. A first light-blocking portion is disposed in a void area that is between the panel support sheet and the optical sensor, within the first hole.

In one aspect, a device may include at least one processor, a touch-enabled display accessible to the at least one processor, and storage accessible to the at least one processor. The storage may include instructions executable by the at least one processor to identify a height of a user. Then, based on the height of the user, the instructions may be executable to one or more of determine a first location of the touch-enabled display at which to present a selector and then present the selector at the first location, and/or determine a second location of the touch-enabled display to use as an area at which touch input that is received will correspond to selection of the selector and then undertake an action associated with selection of the selector responsive to receipt of touch input to the area.

This application is directed to a speaker assembly in which a speaker is mounted in an enclosure structure. The enclosure structure exposes a speaker opening of the speaker and provides a sealed enclosure for a rear portion of the speaker, and further includes an electrically conductive portion. One or more electronic components are coupled to the electrically conductive portion of the enclosure structure (which is grounded in some implementations). The electrically conductive portion of the enclosure structure is configured to provide electromagnetic shielding for the electronic components and forms part of the sealed enclosure of the speaker. In some implementations, the electrically conductive portion of the enclosure structure is thermally coupled to the electronic components and acts as a heat sink that is configured to absorb heat generated by the electronic components and dissipate the generated heat away from the electronic components.