Abstract: The present disclosure relates to a liquid crystal panel and a liquid crystal device (LCD). The liquid crystal panel includes a first substrate, a second substrate opposite to the first substrate, and at least one polymer dispersed liquid crystal (PDLC) being configured between the first substrate and the second substrate, and a plurality of reflective walls. The first substrate is spaced apart from the second substrate. The reflective walls are arranged within the PDLC in sequence. The reflective walls are spaced apart from each other along a direction parallel to the liquid crystal panel. The reflective walls are configured to reflect light beams irradiating on the reflective walls such that an optical amount of the light beams before reflection being greater than the optical amount of the light beams after the reflection.

Abstract: A graphene display, and the graphene display's driving method and device are disclosed. The graphene display driving method includes: obtaining the grey-level values of the three primary colors of a pixel to be input; determining the colors and the grey-level values of the two dynamic subpixels and the static subpixel according to the grey-level values of the pixel's three primary colors and a pre-determined correspondence relationship between three primary colors' grey-level values and four primary colors' grey-level values; and applying driving voltages respectively corresponding to the colors and grey-level values of the two dynamic subpixels and the static subpixel to the two dynamic subpixels and the static subpixel. The present disclosure is able to achieve a greater gamut, enhance display quality, and reduce power consumption of the display.

Abstract: The present invention discloses an application of neuraminidase and inhibitors thereof in myocardial ischemia and myocardial infarction, provides a correlation between neuraminidase and myocardial ischemic damage to prove the myocardial ischemic damage can be alleviated by inhibiting the activity of neuraminidase, and to prove the neuraminidase can be used as a target for screening drugs for preventing, alleviating and/or treating myocardial ischemic damage. The present invention also demonstrates the alleviating effect of neuraminidase inhibitors on myocardial ischemic damage. Neuraminidase inhibitors improves myocardial ischemic damage by reducing the level of neuraminidase. The present invention further provides a pharmaceutical preparation comprising neuraminidase inhibitor(s) and pharmaceutically acceptable carrier(s), the pharmaceutical preparation can be used for reducing the level of neuraminidase, thus improving myocardial ischemic damage.

Abstract: The present disclosure provides a light source component, which includes a power supply plate; at least two point light sources disposed on the power supply plate; and a reflective block disposed on the power supply plate and between two point light sources adjacent to each other, wherein the reflective block is used to reflect light emitted from the point light sources thereto along a direction away from the power supply plate. The present disclosure further provides a backlight module and a liquid crystal display with the light source component. The present disclosure can reduce the amount of the point light source used and save the cost significantly when manufacturing point light sources of the same number by disposing a reflective block which serves equivalently as a point light source between the point light sources.

Abstract: A backlight module includes a glue frame, a light guide plate, a first light source assembly, and a second light source assembly. The light guide plate and the first and second light source assemblies are accommodated in the glue frame. The first light source assembly includes a light source that includes LED light sources mounted on a substrate. The second light source assembly includes a plurality of laser light sources mounted on a substrate and a diffuser. The light guide plate includes first and second incident surfaces. The light source of the first light source assembly and the first incident surface are oppositely positioned. The laser light sources and the second incident surface are oppositely positioned. The diffuser is positioned between the laser light sources and the second incident surface with predetermined distances. Colors of the LED light sources and the laser light sources are complementary colors.

Abstract: An antenna for generating an arbitrarily directed Bessel beam, including a beam-forming plane and a feeding horn, the beam-forming plane is a dual-layer dielectric substrate structure having a beam focusing function, including: a printed circuit bottom layer, a high-frequency dielectric substrate lower layer, a printed circuit middle layer, a high-frequency dielectric substrate upper layer, and, a printed circuit upper layer; the printed circuit bottom layer, the high-frequency dielectric substrate lower layer, the printed circuit middle layer, the high-frequency dielectric substrate upper layer, and the printed circuit upper layer are co-axially stacked from the bottom to the top: the beam-forming plane is entirely divided into periodically arranged beam-forming units by a plurality of meshes, and each beam-forming unit consists of printed circuit upper, middle and lower metal patches of which centers are on the same longitudinal axis, the high-frequency dielectric substrate lower layer and the high-frequenc

Abstract: The present disclosure discloses a backlight module and a liquid crystal display device, the backlight module includes a light source; a spectrally selective element arranged in the light path between the light source to the light-emitting surface of the backlight module, is used to pass through the red, green and blue spectral and limit or block the remaining spectrum. Through the above, the present disclosure may increase the color gamut of the display device and improve the color saturation of the display device.

Abstract: The present application discloses a graphene display, and a driving method and a driving apparatus for a graphene display, the driving apparatus for a graphene display includes obtaining the grayscale values of the three primary colors of the pixel to be input; determining the color and grayscale values of three dynamic sub-pixels according to the grayscale values of the three primary colors of the pixel and the correspondence relationship of the preset grayscale values of the three primary colors and the grayscale values of the five primary colors; applying the driving voltages to the three dynamic sub-pixels respectively corresponding to the color and grayscale values of three dynamic sub-pixels. By the method described above, the gamut of the display is increased, to increase the display performance of the display and decrease the power consumption of the display.

Abstract: The present disclosure proposes a display. The display includes a first display panel, a second display panel, and a connecting mechanism, connecting the first display panel and the second display panel, for adjusting relative positions of the first display panel and the second display panel. By means of the connecting mechanism, relative positions of the first display panel and the second display panel are adjustable. Therefore, the display can be applied to a plurality of scenarios and saves material cost.

Abstract: A graphene display is provided. The graphene display includes a first graphene light-emitting unit and a second graphene light-emitting unit which are stacked and overlapped, and a metal shield layer disposed between the first graphene light-emitting unit and the second graphene light-emitting unit. The graphene display is simple in structure, and the colors of the emitted light at the two sides will not change because of the electric field of the gate electrode pattern so as to have more stable color and color reproduction.

Abstract: Disclosed is a display method of a multi-primary color graphene display device. The method includes the steps of: dividing a pixel color gamut into color patches; determining a color patch to which a pixel chromaticity coordinate belongs; displaying through three dynamic sub-pixels according to the color patch to which the pixel chromaticity coordinate belongs; and determining output brightness of the dynamic sub-pixels by coordinates of a white point, coordinates of the dynamic sub-pixels, an output brightness value when gray level 255 in red is input, an output brightness value when gray level 255 in green is input, and an output brightness value when gray level 255 in blue is input respectively. When input gray level values of RGB three pixels are approximately the same, output brightness and white chromaticity are basically close to the same, guaranteeing the consistency of the chromaticity coordinates of the white point.

Abstract: Provided is a quantum dot LED package structure comprising a bottom bracket, an external bracket, a quantum dot layer light emitting chip, an inorganic barrier layer and a top silica gel layer, wherein the inorganic barrier layer covers the external bracket and the quantum dot layer light emitting chip on the bottom bracket to package the external bracket and the quantum dot layer light emitting chip; the external bracket and the quantum dot layer light emitting chip are packaged by using the inorganic barrier layer, and a top silica gel layer is provided on the inorganic barrier layer, and the water and oxygen barrier condition that the existing package structure simply using the silica gel layer cannot meet can be satisfied and good heat dissipation can be provided. Thus, the issues of mass production difficulty, high cost, low luminous efficiency, difficulty to achieve narrow border application can be solved.

Abstract: A graphene display is provided. The graphene display includes a first graphene light-emitting unit and a second graphene light-emitting unit, which are stacked and overlapped, and a metal shield layer disposed between the first graphene light-emitting unit and the second graphene light-emitting unit. The graphene display is simple in structure, and the colors of the emitted light at the two sides will not change because of the electric field of the gate electrode pattern so as to have more stable color and color reproduction.

Abstract: The present invention provides a backlight module. The backlight module includes a plastic frame, a backlight source and a light guide plate. The backlight source and the light guide plate are received in the plastic frame. The light guide plate includes a light incident surface and a light emitting surface. The backlight source includes a circuit board, a reflecting collimator lens fixed to the circuit board and a LED lamp disposed inside the reflecting collimator lens. The reflecting collimator lens includes a parabolic reflecting surface, and the LED lamp is located at a center location of the parabolic reflecting surface. The light incident surface is covered with a color polarizing layer, and the parabolic reflecting surface faces toward the color polarizing layer. The present invention also discloses a display device.

Abstract: The present disclosure relates to a LED lamp source and the manufacturing method and the backlight module thereof. The LED lamp source includes a substrate and a LED chip, fluorescent adhesive, and a white reflective layer being fixed on the substrate. The fluorescent adhesive encapsulates the LED chip on the substrate, and the white reflective layer is configured for reflecting light beams emitted from the fluorescent adhesive and being radiated on the white reflective layer. A positive projection of the fluorescent adhesive on the substrate is within the positive projection of the white reflective layer on the substrate.

Abstract: Provided is a quantum dot LED package structure comprising a bottom bracket, an external bracket, a quantum dot layer light emitting chip, an inorganic barrier layer and a top silica gel layer, wherein the inorganic barrier layer covers the external bracket and the quantum dot layer light emitting chip on the bottom bracket to package the external bracket and the quantum dot layer light emitting chip; the external bracket and the quantum dot layer light emitting chip are packaged by using the inorganic barrier layer, and a top silica gel layer is provided on the inorganic barrier layer, and the water and oxygen barrier condition that the existing package structure simply using the silica gel layer cannot meet can be satisfied and good heat dissipation can be provided. Thus, the issues of mass production difficulty, high cost, low luminous efficiency, difficulty to achieve narrow border application can be solved.

Abstract: The present disclosure relates to a display device includes a display panel and a backlight source. The display panel includes a top substrate and a down substrate opposite to the top substrate. The top substrate includes a reflective filter layer and a colorful luminous layer. The colorful luminous layer respectively emit red, green, and blue light beams emitting out from the reflective filter layer. The reflective filter layer reflects a portion of the light beams from the backlight source to the reflective filter layer into the colorful luminous layer to further activate the colorful luminous layer to emit the light beams to enhance an optical performance.

Abstract: A graphene light emitting display and a method of manufacturing the same are disclosed. The method comprises: manufacturing a graphene oxide (GO) thin film on a surface of a substrate with a thin film transistor formed thereon; providing a photomask corresponding to the GO thin film to form a source electrode, a drain electrode and a graphene quantum dot layer of a graphene light emitting transistor; and wherein the photomask includes: a complete transparent part corresponding to the region in which the source electrode and the drain electrode are located; a light blocking part corresponding to the region in which the thin film transistor is located; and a semitransparent part corresponding to the region in which the graphene quantum dot layer is located; wherein an insulating layer and a water and oxygen isolating layer are formed sequentially on a surface of the substrate with the graphene light emitting transistor formed thereon.

Abstract: A method for debugging an overdrive table is disclosed. The method comprises the steps of establishing debugging conditions for debugging overdrive gray-scale values in overdrive table of different primary colors according to a partition mode of a liquid crystal display device, backlights of two color fields, and a refresh rate of the backlight. According to the method, various factors which influence the display effect of the liquid crystal display panel are taken into consideration when the overdrive table is debugged, whereby the accuracy of the overdrive table can be improved significantly, and a better display effect can be achieved.

Abstract: A quantum dot light source and a quantum dot backlight module are disclosed. The quantum dot light source includes a light strip including a circuit board and multiple light-emitting diodes, wherein an outer side surface of the circuit board is concave to provide multiple receiving chambers, the receiving chambers are used to install the light-emitting diodes, and the light-emitting diodes do not exceed the outer side surface of the circuit board, and a quantum dot film covering on the receiving chambers of the circuit board. The manufacturing cost of the quantum dot light source of the present invention is lower, and the light-emitting quality is stable.