A multilayer film having electrically controllable optical properties. The multilayer film has a first carrier film, a first planar electrode, an active layer having one or more layers in sequence, a second planar electrode, and a second carrier film, arranged one above the other in a planar manner. The first planar electrode and the active layer and optionally the second planar electrode are divided by at least one insulation line into at least two segments that are electrically insulated from one another. The insulation line is introduced with a laser through one of the carrier films and into the first planar electrode and the active layer and optionally the second planar electrode.

The present disclosure relates to a light control film and a display device including the same, and more particularly, a light control film includes a transparent resin layer including a plurality of grooves which is disposed to be spaced apart from each other; and a plurality of light shielding units disposed in the plurality of grooves, and each of the plurality of light shielding units includes a black resin and a plurality of dispersion particles dispersed in the black resin and the dispersion particles have a structure in which a plurality of second hollow particles is coupled onto a surface of a first hollow particle through a linking group and a size of the second hollow particle is smaller than a size of the first hollow particle.

A two-dimensionally extensive optical element having a light entry side and a light exit side. The optical element includes alternating transparent first regions and second regions having materials with different first refractive indices and second refractive indices. The first refractive index is higher than the second refractive index. First layers and second layers which are opaque or are switchable to be opaque are arranged at the light entry surfaces and light exit surfaces of the second regions. When the layers are opaque, the propagation directions of light passing through the optical element are limited compared to layers which are switched to be transparent.

Simple and cost-effective measurement of polarization components or the complete PSoL (the so-called Stokes parameters) is achieved without any mechanical movements or deformation by using liquid crystal elements. A transmission of a first polarization of light is greater than a transmission of a second orthogonal polarization of light and transmission of the second polarization is greater than 5%. In another of the different states, the device has different levels of transmission of the first and second polarizations of light. At least two orthogonal polarization component values characterizing the light can be resolved by comparing an intensity of light captured in a plurality of the different states.

A display device comprises a display, a rear frame, a speaker, and a speaker mounting portion. The rear frame is disposed on a rear side of the display. The speaker includes a speaker frame that is provided on a sound output side from which sound is output. The speaker is mounted to a rear side of the rear frame. The speaker mounting portion mounts the speaker to the rear frame. The speaker mounting portion includes a first portion that holds the speaker and is fixedly attached to the rear frame, and a second portion that is integrally formed with the first portion and is foldable against the first portion. The second portion contacts the speaker frame of the speaker in a folded state in which the second portion is folded against the first portion.

A multi-layer device and its method of manufacture are disclosed. The multi-layer device comprises a first electrode layer, a first repair layer, a functional layer, and a second electrode layer. The first repair layer comprises a conductive hydrogel film or conductive hydrogel beads, the conductive hydrogel film or the conductive hydrogel beads comprising conductive filler particles dispersed in a cross-linked polymer. The repair layer protects the multi-layer device from electrical short circuits. A multi-layer device is also disclosed including a light-transmissive electrode layer comprising a porous mesh or porous spheres.

A multi-layer device and its method of manufacture are disclosed. The multi-layer device comprises a first electrode layer, a first repair layer, a functional layer, and a second electrode layer. The first repair layer comprises a conductive hydrogel film or conductive hydrogel beads, the conductive hydrogel film or the conductive hydrogel beads comprising conductive filler particles dispersed in a cross-linked polymer. The repair layer protects the multi-layer device from electrical short circuits. A multi-layer device is also disclosed including a light-transmissive electrode layer comprising a porous mesh or porous spheres.

The disclosure relates to the technical field of display, in particular to a displaying substrate, a manufacturing method thereof and a display panel. The displaying substrate comprises a passivation layer (28) and a flat layer (29) covering the passivation layer (28), wherein the flat layer (29) comprises a first flat via hole and a plurality of second flat via holes, the passivation layer (28) comprises a first passivation via hole, and the first flat via hole and the first passivation via hole form a first sleeve hole (31); and the hole depth of the first flat via hole is smaller than that of each second flat via hole, and the hole depth of the first passivation via hole is greater than or equal to the difference between the maximum hole depth of all the second flat via holes and the hole depth of the first flat via hole.

A binocular telescope comprises a main housing, a first lens body and a second lens body which are rotatably mounted in the main housing, and a laser ranging component accommodated in the main housing, the laser ranging component comprising a base mounted in the main housing, a laser transmitting module and a laser receiving module which are mounted in the base, the laser ranging component being provided in front of the first lens body and the second lens body, so that a laser light path for range finding is separated from an observing light path of the first lens body and the second lens body, and the laser light path is independently provided in front of the observing light path.

A transparent display device includes a transmissive light valve panel, a transparent plate and at least one light emitting assembly. The transmissive light valve panel has a display surface. The transparent plate is disposed with respect to the transmissive light valve panel to form an optical space between the transparent plate and the transmissive light valve panel. The at least one light emitting assembly is disposed beside the optical space and adapted to generate light into the optical space. A light pattern of the light emitted from the light emitting assembly and directed to the optical space has at least one maximum peak in an angular range of 15 with respect to a direction parallel to the display surface of the transmissive light valve panel.