An improved power supply for the AN/PRC-117G military radio has been developed. The presently disclosed power supply includes an AC-DC power conversion module; a DC-DC power module and an onboard battery backup. The disclosed power supply is an adaptable power supply which configures to provide AC-DC power; DC only power and battery backup power. The AC and DC power modules are independent and separable, and may be configured by the radio user to remove the AC module and operate in a DC only mode. The adaptability of the power supply includes universal power supply for the Harris Corporation Falcon III series of radios which includes the AN/PRC-117G; RF-7800H-MP; RF-7800M-MP; RF-7800-RC; AN/PRC-160 and the RF-7800-RT intelligence, surveillance and reconnaissance terminal.

An electronic device is provided. The electronic device includes a housing, a display rollable into the housing, and a display driver circuitry operably coupled to the display. The display driver circuitry is configured to display, while the electronic device is in a first state in which a first display area of the display is exposed and a second display area of the display adjacent to the first display area is rolled into the housing, a first image in the exposed first display area, obtain, a second image based on applying a first weight to a pixel value of a first pixel of a first horizontal line and applying a second weight less than the first weight to a pixel value of a second pixel of the first horizontal line, and display, while displaying the first image, the second image in the second display area rolled into the housing.

An electronic device is provided and includes a housing including a first antenna, and a binding member configured to be bound to one side of the housing. The binding member includes a strap body, a coupling part formed at one end portion of the strap body and bound to one side of the housing, an expansion part expanded inward from the housing from one end portion of the strap body, and making contact with at least a portion of a rear surface of the housing when bound, a second antenna provided in the strap body, and a coupler electrically connected with the second antenna, provided in at least a portion of the extension part, the coupler being configured to transmit a signal received through the second antenna to the first antenna.

Embodiments describe an eartip including an eartip body having an attachment end and an interfacing end opposite from the attachment end. The eartip body can include an inner eartip body having a sidewall extending between the interfacing end and the attachment end, the sidewall defining a channel and having a first thickness near the attachment end and a second thickness different from the first thickness at the interfacing end. The eartip can also include an attachment structure coupled to the inner eartip body at the attachment end, the attachment structure having an inner surface and an outer surface. The attachment structure can include an upper region interfacing with the sidewall and defining discrete through-holes, a lower region below the upper region where the inner surface defines a plurality of recesses positioned around the lower region, and a mesh extending across the channel and into the upper region.

The present invention relates to the technical field of energy storage power supply and discloses a fanless portable energy storage power supply, comprising an upper shell, wherein a battery is arranged inside the upper shell; the lower part of the upper shell is fixedly connected with a lower shell; the lower inner wall of the upper shell is fixedly connected with a first fixing plate; the inner wall of the fixing frame is fixedly connected with a filter screen; the bottom of the fixing frame is fixedly connected with a bottom plate; and the bottom plate is connected with the bottom surface of the lower shell through bolts, so as to ventilate and dissipate heat, facilitate the separation and combination of batteries and circuit boards and save resources.

A housing assembly is provided according to the present disclosure. The housing assembly includes a dielectric substrate and a radio-wave transparent structure. The dielectric substrate has a first transmittance for a radio frequency signal in a preset frequency band. The radio-wave transparent structure is disposed on the dielectric substrate and at least partially covers the dielectric substrate. A region of the housing assembly corresponding to the radio-wave transparent structure has a second transmittance for the radio frequency signal in the preset frequency band, and the second transmittance is larger than the first transmittance. The housing assembly can be applied to an electronic device having an antenna module.

An electronic device may include: a housing including a first housing and a second housing, a hinge connecting the first housing and the second housing to be rotatable, a display module including a display panel including a first area disposed in the first housing, a second area disposed in the second housing, and a folding area disposed in the hinge part, a first plate supporting the first area of the display panel, and a second plate supporting the second area of the display panel, a third plate disposed under the first plate, and a fourth plate disposed under the second plate. At least a part of at least one of the third plate and the fourth plate may be disposed between the first plate and the second plate to support at least some of the folding area of the display panel.

Glass-based articles are disclosed having a thickness in a range of from about 0.2 mm to about 4.0 mm, a first compressive stress layer extending from a first surface of the glass-based article to a first depth of compression that is in a range of from about 5% to about 20% of the thickness, a second compressive stress layer extending from a second surface of the glass-based article to a second depth of compression that is in a range of from about 5% to about 20% of the thickness, wherein the second surface is opposite the first surface, and a central region extending from the first depth of compression to the second depth of compression and having a maximum tensile stress in a range of from about 0.5 MPa to about 20 MPa. Electronic devices comprising the glass-based articles and methods of making glass-based articles are also disclosed.

A wearable device is provided, including a shell, a body installed in the shell to implement a function of the wearable device, and a detachable part. The detachable part is detachably installed on the shell. An air hole is provided on the shell, a first end of the air hole is located on a surface of the shell that faces the body, and a second end of the air hole is located on a surface of the shell that faces away from the body. The detachable part and the shell jointly form a dirt collection groove and at least one air channel, the air hole communicates with the at least one air channel through the dirt collection groove, and an end of the air channel that faces away from the dirt collection groove communicates with an external environment of the shell.

An electronic device includes at least two modules, each module includes at least one component; two adjacent modules of the at least two modules are detachably connected, and the two adjacent modules are electrically connected; the housings of the at least two modules are connected to form the housing of the electronic device; in the at least two modules, the first module includes a mainboard and the second module includes a battery. When any module in the electronic device needs to be updated, the module only needs to be detached from the electronic device, and then the replacement of the module is connected to other modules, thereby forming a new electronic device. There is no need to replace the entire electronic device, and the hardware cost is reduced.