An electronic device may have a housing, electrical components, and other electronic device structures. A display may be mounted in the housing. The display may have a transparent display cover layer and a display layer such as an organic light-emitting diode display layer that is mounted to the underside of the transparent display cover layer. A flexible printed circuit with metal traces may be mounted under the organic light-emitting diode display layer. The metal traces may form coils for a near-field communications inductive loop antenna. A magnetic shielding layer may be interposed between the housing and the flexible printed circuit. The magnetic shielding layer may include a polymer magnetic shielding layer having magnetic material particles embedded in a polymer matrix. The magnetic shielding layer may also have a polymer-binder-free magnetic shielding layer.

Examples of display devices are described. In an example, a display device may comprise a display panel, a supporting frame to hold the display panel within a housing of the display device, and a push-button assembly. In an example, the push-button assembly comprises a tubular member having a first end and a second end. The first end is located on an external surface of the housing, while the second ends abuts a surface of the display panel. An actuator may be slidably disposed within the tubular member. Upon actuation, the actuator may slide outward of the second end to disengage the display panel from the supporting frame.

The present embodiment relates to a DC-DC converter comprising: a housing; a plurality of electronic components disposed inside the housing; and a flow path disposed on a lower plate of the housing. The flow path comprises an expanding portion. The horizontal width of the expanding portion is greater than the horizontal width of a flow path on the front end of the expanding portion, and the vertical width of the expanding portion is less than the vertical width of the flow path on the front end of the expanding portion. The differential between the part wherein the surface area of the vertical cross section of the flow path is the biggest and the part wherein the surface area of the vertical cross section of the flow path is the smallest is 10% or less.

The present embodiment relates to a DC-DC converter comprising: a housing; a plurality of electronic components disposed inside the housing; and a flow path disposed on a lower plate of the housing. The flow path comprises an expanding portion. The horizontal width of the expanding portion is greater than the horizontal width of a flow path on the front end of the expanding portion, and the vertical width of the expanding portion is less than the vertical width of the flow path on the front end of the expanding portion. The differential between the part wherein the surface area of the vertical cross section of the flow path is the biggest and the part wherein the surface area of the vertical cross section of the flow path is the smallest is 10% or less.

An optoelectronic module is provide and includes an electronic unit, an optical unit, and an interconnect structure. The electronic unit is capable of outputting and/or receiving electric signals, while the optical unit is capable of converting the electric signals into optical signals. The interconnect structure connects the electronic unit and the optical unit, and includes an electrically conducting substrate and a pair of transmission leads connecting electronic unit and the optical unit. The pair of transmission leads includes a signal lead and a ground lead having lower impedance than the signal lead.

A hinge module and a foldable electronic device comprising the same are disclosed. The hinge module comprises a support piece. The foldable electronic device comprises a central body, a first panel body, a second panel body, and a flexible screen. When the first panel body and the second panel body are in an unfolded state, the flexible screen is flattened and the support piece is located at the first position for the supporting surface abutting against the bendable area of the flexible screen; and when the first panel body and the second panel body are in a folded state, the bendable area is bent, the support piece is located at the second position, and the support piece, the first panel body, and the second panel body collaboratively form a receiving space for accommodating the bendable area of the flexible screen.

An electronic device according to various embodiments includes: a housing; at least one input area disposed on an outer surface of the housing and facing a first direction; a sensor assembly including at least one pressure sensor disposed on an inner surface of the housing facing a second direction opposite the first direction, and configured to sense pressure applied to the input area; at least one first opening provided at a first portion of the housing adjacent to the sensor assembly; and a second opening provided at a second portion of the housing spaced apart from the first opening in the second direction, wherein the first opening and the second opening are configured to be deformed based on the pressure that is applied to the input area.

A light-emitting device and a control method are provided. The light-emitting device is applied to a memory module. The light-emitting device includes at least one memory module board, at least one light-emitting board and an application program unit. The at least one memory module board is connected with a host. Each light-emitting board includes plural light-emitting units and a control unit. The control unit controls a lighting mode of the plural light-emitting units. The control unit is electrically connected with the host through the corresponding memory module board. The application program unit generates a control signal. The control signal is transmitted to the control unit of each light-emitting board through the host. The control unit controls the corresponding light-emitting units according to the control signal.

An apparatus includes a tray, a shaft connected to the tray, a bracket that secures the tray to a networking device such that the tray is distanced from a surface of the networking device, and a support post coupled to the tray via the shaft, the support post including: a rotating pin having a cylindrical passage through which the shaft passes, the rotating pin being coupled to the support post to allow the support post to rotate about the rotating pin and about the shaft, and a locking pin having a latch that is configured to engage with a corresponding opening on the tray to secure the support post to the tray.

An apparatus includes a tray, a shaft connected to the tray, a bracket that secures the tray to a networking device such that the tray is distanced from a surface of the networking device, and a support post coupled to the tray via the shaft, the support post including: a rotating pin having a cylindrical passage through which the shaft passes, the rotating pin being coupled to the support post to allow the support post to rotate about the rotating pin and about the shaft, and a locking pin having a latch that is configured to engage with a corresponding opening on the tray to secure the support post to the tray.