A polymer-dispersed liquid crystal light-regulation structure comprises a liquid crystal light-regulation layer, a first anti-infrared light-permeable conductive layer, a second anti-infrared light-permeable conductive layer, a first light-permeable substrate, and a second light-permeable substrate. The first and second anti-infrared light-permeable conductive layers are respectively disposed on two sides of the liquid crystal light-regulation layer. The first and second light-permeable substrates are respectively disposed on sides of the first and second anti-infrared light-permeable conductive layers, which are far away from the liquid crystal light-regulation layer. The first and second anti-infrared light-permeable conductive layers not only retard infrared light from entering the building and lower the indoor temperature but also function as electric-conduction structures electrically energized to vary the light transmittance of the liquid crystal light-regulation layer, whereby fewer layers are used in the present invention, and whereby is reduced the overall thickness of the present invention.

This invention relates to an ophthalmic lens comprising a transparent substrate with a front main face and with a rear main face, at least one of the main faces being coated with a multilayered antireflective coating comprising a stack of at least one high refractive index layer (HI) having a refractive index higher than or equal to 1.55 and at least one low refractive index layer (LI) having a refractive index lower than 1.55, characterized in that: said at least one high refractive index layer (HI) is in direct contact with said at least one low refractive index layer (LI) forming a bilayer, said bilayer has a physical thickness lower than or equal to 60 nm, said bilayer is, in the direction moving away from said transparent substrate, in second to last place in said multilayered antireflective coating, said multilayered antireflective coating has a mean reflection factor Ruv between 280 nm and 380 nm, lower than 5% for an angle of incidence in the range from 20 to 50.

A polymer-dispersed liquid crystal light-regulation structure comprises a liquid crystal light-regulation layer, a first anti-infrared light-permeable conductive layer, a second anti-infrared light-permeable conductive layer, a first light-permeable substrate, and a second light-permeable substrate. The first and second anti-infrared light-permeable conductive layers are respectively disposed on two sides of the liquid crystal light-regulation layer. The first and second light-permeable substrates are respectively disposed on sides of the first and second anti-infrared light-permeable conductive layers, which are far away from the liquid crystal light-regulation layer. The first and second anti-infrared light-permeable conductive layers not only retard infrared light from entering the building and lower the indoor temperature but also function as electric-conduction structures electrically energized to vary the light transmittance of the liquid crystal light-regulation layer, whereby fewer layers are used in the present invention, and whereby is reduced the overall thickness of the present invention.

Optical windows based on a multi-period master-slave nested ring array of concentric rings are suited for electromagnetic shielding. A metal grid of the ring array has basic rings, concentric sub-ring pairs, secondary sub-rings, filling rings, concentric modulation ring pairs, and modulation sub-rings. Basic rings and concentric modulation ring pairs form a two-dimensional orthogonal array. External rings of concentric modulation ring pairs are externally tangentially connected to basic rings. Concentric sub-ring pairs and filling rings are arranged within basic rings, secondary sub-rings are arranged within concentric sub-ring pairs, and modulation sub-rings are arranged within concentric modulation ring pairs. Where rings are tangentially connected, wires overlap or metal ensures reliable electrical connections between connected rings, thus all rings are conductive. The metal grid structure significantly reduces non-uniformity of grid high-order diffracted light intensity distribution, causing stray light distribution caused by diffraction to be more uniform and imaging to be less affected.

An optical window based on an array of rings and sub-rings having a triangular and orthogonal mixed distribution is suited for electromagnetic shielding. The array has metal rings of the same diameter acting as basic rings closely arranged according to an equilateral triangular and two-dimensional orthogonal square mixed arrangement and is loaded on an optical window transparent substrate surface. Adjacent basic rings are connected externally tangentially. Metal sub-rings are arranged within each basic ring and connected thereto internally tangentially. Each basic ring and its sub-rings constitute a basic unit. At tangential connection locations of the rings, wires overlap or metal is provided to ensure reliable electrical connections between connected rings, thus all rings are conductive. The metal grid structure significantly reduces non-uniformity of grid high-order diffracted light intensity distribution, thereby causing stray light distribution caused by diffraction to be more uniform and imaging to be less affected.

An optical film includes a transparent support and at least one antistatic layer formed from a composition containing an electrically conductive polymer, a polyfunctional monomer having two or more polymerizable groups, at least one compound selected from a compound represented by the formula (1) as defined herein, a compound represented by the formula (2) as defined herein and a trivalent phosphorus compound, and a photopolymerization initiator.

Embodiments of this application relate to the technical field of camera modules to resolve an issue of miniaturization of camera modules. The embodiments of this application provide a camera module and an electronic apparatus. The camera module includes: a circuit board; an image sensor and a driver circuit that are located on the circuit board; an upper lens barrel and a lower lens barrel that are located on a side of the image sensor away from the circuit board; a connecting circuit located on the lower lens barrel; and an adjustable lens disposed inside between the upper lens barrel and the lower lens barrel. The adjustable lens is electrically connected to the driver circuit through the connecting circuit, so as to deform under driving of the driver circuit to adjust a focal power of the camera module. Such camera module has an advantage of small volume ratio.