A glass with a reinforced layer is provided, including a glass body and the reinforced layer formed in a surface of the glass body. The compressive stress of the reinforced layer trends to decrease non-linearly from the surface of the glass body to the interior of the glass body. The compressive stress curve of the reinforced layer has an inflection point. The gradient of a first curve section in front of the inflection point is greater than the gradient of a second curve section behind the inflection point. The overall refractive index of the reinforced layer trends to decrease non-linearly from the surface of the glass body to the interior of the glass body. The refractive index curve of the reinforced layer has at least two inflection points. Furthermore, a method for preparing the glass with a reinforced layer is provided.

A coated substrate for an electronic device can include a substrate, a physical vapor deposition layer over the substrate, and an anti-fingerprint layer over the physical vapor deposition layer. The physical vapor deposition layer can include an alloy of gold and platinum. The anti-fingerprint layer can include an ultraviolet radiation-cured polymer mixed with an anti-fingerprint material. The anti-fingerprint material can include a silane, a fluorinated polymer, a hydrophobic polymer, or a combination thereof.

Laminated glass-based articles and methods of manufacture are disclosed. A glass-based article includes a glass-based substrate having a first surface and a second surface opposing the first surface defining a substrate thickness (t) in a range of about 0.1 millimeters to 3 millimeters, the glass-based substrate having a compressive region having a first compressive stress CS maximum at the first surface of the glass-based article extending to a depth of compression (DOC) and second local CS maximum at a depth of at least 25 μm from the first surface, wherein the glass-based substrate comprises a glass-based core substrate having a first side and a second side, the glass-based core substrate sandwiched between a glass-based first cladding substrate and a glass-based second cladding substrate, the first cladding substrate and second cladding substrate directly bonded to the first side and the second cladding substrate directly bonded to the second side.

An electronic device includes an enclosure formed of a plurality of layers cooperating to define an interior volume. The enclosure includes a first layer formed of a first material and defining a user input surface of the enclosure and a first portion of a side surface of the enclosure. The enclosure also includes a second layer, formed of a second material different from the first material, positioned below the first layer and defining a second portion of the side surface of the enclosure. The enclosure also includes a third layer, formed of a third material different from the first and second materials, positioned below the second layer and defining a bottom surface of the enclosure and a third portion of the side surface of the enclosure.

Examples disclosed herein provide a computing device. As an example, the computing device includes a housing having an opening extending through the housing, to accommodate a lens of a camera. The computing device includes a shutter to selectively obscure the opening, where the shutter is slidable between a first position and a second position. While in the first position, the shutter is to obscure the opening while a microphone of the computing device is enabled and, while in the second position, the shutter is to obscure the opening and disable the microphone.

A coated metal alloy substrate for an electronic device, a process for producing a coated metal alloy substrate for an electronic device and a housing for an electronic device, comprising a coated metal alloy substrate wherein the coated metal alloy CA substrate comprises at least one chamfered edge (1) and comprises: a passivation layer (2) deposited on the at least one chamfered edge (1); an electrophoretic deposition layer (3) deposited on the passivation layer (2); and a hydrophobic layer (4) deposited on the electrophoretic deposition layer (3).

A terminal device and a sound-emitting apparatus arranged in the terminal device, where the terminal device includes a housing, a display is arranged on a surface of the housing, a notch is formed at an end of the display, and a camera system is arranged inside the housing. The camera system is arranged opposite to the notch in a direction perpendicular to the display, and a camera of the camera system is located inside the notch. A through-hole is arranged opposite to an opening of the notch in the housing in a direction parallel to the display.

An example electronic device includes a housing. In addition, the electronic device includes a display panel supported by the housing. The display panel includes a planar portion and a side portion extending from the planar portion to an end of the display panel. The planar portion and the side portion are to display images. The side portion is to transition between a first position in which the side portion is co-planar with the planar portion and a second position in which the side portion is curved relative to the planar portion.

In one example in accordance with the present disclosure, a computing device mount is described. The computing device mount includes a stand to support a computing device and a spacer removably attached to the stand. The spacer is placed in a recess of the computing device to mount the computing device to a mounting surface. The spacer also aligns holes on the computing device with holes on the mounting surface.

A head-mounted display device includes a mounting portion configured to be attached to a head of a user, an image display unit disposed in the mounting portion and configured to display an image to be visually recognized by the user, a state detection unit configured to detect a first state in which the mounting portion is attached to the head and a second state in which the mounting portion is detached from the head, and a display control unit configured to cause the image display unit to stop displaying an image when the state detection unit detects the second state.