Systems, devices, and methods that ensures that an ultrasonic fingerprint detection process is not interfered with by using a screen protector. An example screen protector for a mobile device is disclosed that is capable of an in-screen fingerprint detection. The screen protector includes a first layer made of a clear rigid material and configured to be touched by a user. The screen protector also includes a second layer beneath the first layer and made of a film. Additionally, the screen protector includes a third layer beneath the second layer and configured to contact the mobile device. The third layer includes a fingerprint conduit configured to facilitate the in-screen fingerprint detection.

An electronic device, including a housing, a display screen, a mainboard support, and a camera. A first mounting portion is arranged on the housing. The display screen is mounted on the housing, a mounting cavity is formed between the display screen and the housing, and the display screen has a light-transmitting hole. The mainboard support is mounted on the housing, located inside the mounting cavity, and arranged spaced apart from the display screen. A second mounting portion is arranged on the mainboard support. The camera is located inside the mounting cavity, is arranged facing the light-transmitting hole, and matches the first mounting portion and the second mounting portion respectively, to be positioned between the housing and the mainboard support. A minimum distance n between the camera and the display screen satisfies: 0.15 mm≤n<0.4 mm.

An electronic device includes a display screen, a first aperture region and a second aperture region. The display screen is disposed on a surface of the electronic device. The first aperture region is disposed on the surface of the electronic device, and a visible light is able to enter into an internal portion of the electronic device through the first aperture region. The second aperture region is disposed on the surface of the electronic device, and the visible light is able to enter into the internal portion of the electronic device through the second aperture region. The display screen is disposed between the first aperture region and the second aperture region and configured to be a spacing maintained therebetween, and a shape of the first aperture region and a shape of the second aperture region are non-circular and mirror-symmetrical to each other.

An ultraviolet light-resistant article that includes: a substrate having a glass or glass-ceramic composition and first and second primary surfaces; an ultraviolet light-absorbing element having a an absorptivity greater than 50% at wavelengths from about 100 nm to about 380 nm and a thickness between about 10 nm and about 100 nm; and a dielectric stack formed with a plasma-enhanced process. Further, the light-absorbing element is between the substrate and the dielectric stack. Alternatively, the light-absorbing element can include one or more ultraviolet light-resistant layers disposed within the dielectric stack over the first primary surface.

An interface device includes an electronic device and an input device configured to communicate with the electronic device. The electronic device includes a display layer and a sensing layer disposed under the display layer. The sensing layer transmits a first driving signal to the input device and sensing an input generated by the input device. The input device includes a resonance circuit unit in which a first magnetic field is generated based on the first driving signal, a control unit configured to control the resonance circuit unit, and a power supply unit providing power to the control unit. A second magnetic field is generated by the supply in the resonance circuit unit. The sensing layer senses the input based on the second magnetic field.

A display panel and a mobile terminal are disclosed. A light-emitting device layer of the display panel includes a plurality of first light-emitting units, a plurality of first compensation layers disposed corresponding to the first light-emitting units. The first compensation layers are located on at least one side of the first light-emitting units. A hole transport rate of the first compensation layers is greater than a hole transport rate of a hole transport layer, and/or an electron transport rate of the first compensation layers is greater than an electron transport rate of an electron transport layer.

An electronic device and method for controlling the electronic device are provided. The electronic device includes a first surface in a first direction, a second surface in a second direction opposite to the first direction, and a third surface enclosing at least a portion of a space formed between the first surface and the second surface. The electronic device also includes an audio module changing an audio signal input to the electronic device into an electronic signal, and a processor being operationally connected to the display and the audio module. The processor is configured to detect the audio signal input via the audio module from a first user via the first surface, detect a touch signal dragged from the third surface in the direction of the second surface, and display in the second surface a translation corresponding to the audio signal.

A mobile terminal includes a middle frame, a fixing frame, and a cover plate. The middle frame includes a first placement slot and a second placement slot. The fixing frame is disposed in the second placement slot. The cover plate is disposed in the first placement slot. The second placement slot includes first side surfaces. The first side surfaces are provided with a plurality of first protrusions. The fixing frame includes first sidewalls. The first sidewalls are provided with a plurality of second protrusions. The first protrusions and the second protrusions are arranged to form a support structure configured to support the cover plate, and the cover plate is fixedly connected to the support structure.

An electronic device may have a glass housing structures. The glass housing structures may be used to cover a display and other internal electronic device components. The glass housing structure may have multiple glass pieces that are joined using a glass fusing process. A peripheral glass member may be fused along the edge of a planar glass member to enhance the thickness of the edge. A rounded edge feature may be formed by machining the thickened edge. Raised fused glass features may surround openings in the planar glass member. Multiple planar glass members may be fused together to form a five-sided box in which electronic components may be mounted. Raised support structure ribs may be formed by fusing glass structures to a planar glass member. Opaque masking material and colored glass may be used to create portions of the glass housing structures that hide internal device components from view.

An electronic device is provided. The electronic device includes a front plate, a rear plate facing away the front plate, a side member disposed to surround a space defined between the front plate and the rear plate, wherein the side member is coupled to the front plate and the rear plate to define a housing, wherein the side member is at least partially made of a metallic material, a polymer structure located in the space, and a display received in the space to be viewable through the front plat. The rear plate may be seated on the second surface.