A display panel and an electronic device are provided. The display panel comprises a base substrate including a display region and a border region surrounding the display region, wherein the border region includes an encapsulation region; a plurality of display units disposed in the display region; an encapsulation member disposed in the border region; a plurality of wires disposed in the border region; and a cover substrate arranged opposite to the base substrate. The display units and the wires are disposed between the base substrate and the cover substrate, the encapsulation member is disposed in the encapsulation region and configured to bond and fix the base substrate to the cover substrate, and at least one of the wires is disposed in the encapsulation region.

An information processing apparatus including a display portion; a backlight unit configured to irradiate light from a rear face side of the display portion; a rear frame having height equivalent to at least a thickness of the backlight unit, and configured to protect the backlight unit; and an outer circumference casing attached to the rear frame, or formed integrally with the rear frame, and provided along an outer circumference of the display portion.

A display apparatus including: a display panel including a substrate and an encapsulating member and realizing an image; a circuit member arranged to overlap at least a portion of the substrate of the display panel; and a shield member arranged between a surface portion of the substrate of the display panel and the circuit member, the surface portion overlapping the circuit member.

An electrochromic device includes a nanostructured transition metal oxide bronze layer that includes one or more transition metal oxide and one or more dopant. The electrochromic device also includes nanoparticles containing one or more transparent conducting oxide (TCO), a solid state electrolyte, a counter electrode, and at least one protective layer to prevent degradation of the one or more nanostructured transition metal oxide bronze. The nanostructured transition metal oxide bronze selectively modulates transmittance of near-infrared (NIR) and visible radiation as a function of an applied voltage to the device.

A display device includes an outer frame, a transparent cover, a back cover, a display module, and a separating structure. The outer frame has a display opening, the transparent cover covers the display opening, and the back cover is opposite to the display opening. The display module is disposed inside the outer frame and has a front surface facing the transparent cover and a rear surface facing the back cover. The separating structure is connected between the back cover and the rear surface of the display module. A first space formed between at least the transparent cover, the front surface of the display module, the outer frame, the back cover, and the separating structure is an enclosed space. A second space formed between at least the rear surface of the display module, the separating structure, and the back cover is connected to an outside and surrounded by the first space.

An electro-optic device includes an element substrate including a plurality of pixel electrodes on one surface of the element substrate, an opposite substrate opposing the one surface of the element substrate via an electro-optic layer, and a seal material configured to bond the element substrate to the opposite substrate. The seal material includes a plurality of gap materials that controls a substrate-to-substrate distance between the element substrate and the opposite substrate. A concave portion is formed in the opposite substrate within a region surrounded by the seal material, and is configured to allow the substrate-to-substrate distance in a display region to be broader than the substrate-to-substrate distance in a region overlapping with the seal material.

A display device has both an array layer and a terminal part formed on a bendable substrate. An optical sheet is disposed to cover the array layer, and an overcoat is formed to cover the terminal part. The side surface of the optical sheet is inclined at an inclination angle with respect to the main surface of the substrate. The overcoat is in contact with the side surface of the optical sheet.

The disclosure is directed to electronic device displays which are constructed to withstand damage from an impact resistance test wherein a steel ball of 2 g having a diameter of 8 mm is dropped from a designated height greater than 1 ft, more preferably greater than 2 ft, even more preferably greater than 3 ft, still even more preferably greater than 4 ft, yet even more preferably greater than 5 ft and even more preferably greater than 6 ft. The displays are configured using, for example, ultrathin glass adhered to a base glass, wherein the adhesive layer is optimized for thinness and stiffness.

A film wrapping display includes a panel that is transparent to light and is configured to display information on one surface of the panel, and a film adhered to cover the one surface of the panel on which the information is displayed. The film is adhered to the other surface of the panel opposite to the one surface in addition to the one surface of the panel. An edge of the film is positioned at the other surface while the film covers an outermost periphery of the panel and extends around to the other surface.

A cover (8) of an optical device (10) is divided into: a first cover (5) which is fixed to a side wall section (4) so that an optical window (52) covers a light receiving section (1a) that serves as an effective region of an LCOS element (1); and a second cover (6) which is fixed to the side wall section (4) and the first cover (5) so as to cover an electrode terminal (3) and a wire (7) that connects the electrode terminal (3) and the semiconductor element (1b) to each other.