An embodiment of a camera module includes a holder configured such that the upper and lower portions of the holder are open and such that a first hole and a second hole, opposite to the first hole, are formed in the side surface of the holder, a first lens unit coupled to the upper portion of the holder, a second lens unit coupled to the lower portion of the holder, and a liquid lens disposed in the first hole and the second hole of the holder between the first lens unit and the second lens unit, the liquid lens protruding outward from the side surface of the holder, wherein at least a portion of the liquid lens may be spaced apart from the inner surface of the holder.

A lens module includes a printed circuit board; a lens mounted on one side of the printed circuit board, and a shielding cover. The shielding cover comprises a cavity. A part of the printed circuit board and a part of the lens are received in the cavity of the shielding cover. The disclosure also relates to an electronic device using the lens module. The lens module can filter the magnetic interference of the external signal and facilitate heat generated by the lens module dissipate outside.

An embodiment of a camera module includes a holder configured such that the upper and lower portions of the holder are open and such that a first hole and a second hole, opposite to the first hole, are formed in the side surface of the holder, a first lens unit coupled to the upper portion of the holder, a second lens unit coupled to the lower portion of the holder, and a liquid lens disposed in the first hole and the second hole of the holder between the first lens unit and the second lens unit, the liquid lens protruding outward from the side surface of the holder, wherein at least a portion of the liquid lens may be spaced apart from the inner surface of the holder.

Disclosed herein are photo-stable optical stacks including a transparent conductive film formed by silver nanostructures or silver mesh. In particular, one or more light stabilizers (such as transition metal salts) are incorporated into one or more constituent layers of the optical stack.

Disclosed are a lens driving device, a camera device and an electronic apparatus. The lens driving device has a stator and a mover moving relative to the stator. The stator has a non-conductive base and a non-conductive housing assembled on the base. The stator is quadrilateral observed from the optical axial direction of the lens. The stator has one of a pair of magnets or a pair of coils disposed respectively on two opposite edges of the quadrilateral. The mover has the other of the pair of magnets or the pair of coils. The pair of coils are respectively opposed to the pair of magnets. The other two opposite edges or the quadrilateral are not provided with the magnets and the coils or a conductive component limning at least one kind of the base, the housing, the magnets or the coils.

A protective window includes a flexible base film and a hard coating layer disposed on the flexible base film. The hard coating layer includes a silicone leveling agent and an inorganic antistatic agent. The coating layer includes an upper area and a lower area disposed between the upper area and the flexible base film, and a density of the inorganic antistatic agent in the lower area is greater than a density of the inorganic antistatic agent in the upper area.

A display device is provided including a substrate including a first organic layer and a first barrier layer. A shield layer is disposed between the first organic layer and the first barrier layer, and the shield layer includes a metal.

A display device includes a cover window having a bezel area including an opening, a stiffener, and a display panel. The stiffener includes a support portion on the rear surface, an insertion portion protruding from the support portion and inserted in the opening, a first bending portion extending from the support portion and bent at a first angle, and a second bending portion extending from the first bending portion and bent at a second angle. A cover part may be disposed in the insertion portion and of which at least a portion is exposed through the opening at the front surface. The display panel disposed on the rear surface of the cover window and includes at least one pixel configured to provide an image. The second angle is greater than the first angle, and the second angle is 180 degrees.

Nanocomposite films comprising carbon nanotubes dispersed throughout a polymer matrix and further comprising at least two surfaces with differing amounts of carbon nanotubes and differing electrical resistivity values are provided. Nanocomposite films comprising a polymer layer, a conductive nanofiller layer, and a polysaccharide layer having antistatic properties are provided. In particular, nanocomposites comprising polyvinyl alcohol as the polymer, graphene as the conductive nanofiller and starch as the polysaccharide are provided. In addition, processes for forming the nanocomposites, methods for characterizing the nanocomposites as well as applications in or on electrical and/or electronic devices are provided.

Nanocomposite films comprising carbon nanotubes dispersed throughout a polymer matrix and further comprising at least two surfaces with differing amounts of carbon nanotubes and differing electrical resistivity values are provided. Nanocomposite films comprising a polymer layer, a conductive nanofiller layer, and a polysaccharide layer having antistatic properties are provided. In particular, nanocomposites comprising polyvinyl alcohol as the polymer, graphene as the conductive nanofiller and starch as the polysaccharide are provided. In addition, processes for forming the nanocomposites, methods for characterizing the nanocomposites as well as applications in or on electrical and/or electronic devices are provided.