Abstract: The present disclosure relates to an array substrate, a method of manufacturing the same and a display device. The array substrate comprises a gate line PAD region and a data line PAD region. In the gate line PAD region of the array substrate, gate-line wirings, which are parallel to the gate lines and are electrically insulated from the gate lines, are provided between adjacent gate lines. In the data line PAD region of the array substrate, data-line wirings, which are parallel to the data lines and are electrically insulated from the data lines, are provided between adjacent data lines. Both of the gate-line wirings and the data-line wirings are conductive wiring segments. By forming the gate-line wirings and the data-line wirings in the PAD region, the ability of resisting scratch of the product can be improved while not deteriorating performance of display of the product.

Abstract: A detection device includes a chamber for vacuum coating, a capacitance measurement device and a baffle mechanism located in the chamber. The baffle mechanism is a closed structure encompassed by a number of baffle walls, wherein at least one baffle wall includes a fixed baffle plate and a moveable baffle plate. The moveable baffle plate is pivotable about the fixed baffle plate. The moveable baffle plate, after pivoting, may get parallel with an adjacent baffle wall. The adjacent baffle wall and the moveable baffle plate are respectively connected to the capacitance measurement device, and the capacitance measurement device is used to measure the capacitance between the adjacent baffle wall and the moveable baffle plate. The detection device may accurately detect the service life of the baffle mechanism and achieve precise management of the apparatus.

Abstract: The present invention provides an array substrate comprising a substrate, a metal conductive film layer, and an anti-reflective film layer located between the substrate and the metal conductive film layer, and a method for manufacturing the same, as well as a display device. The method comprises step S1: forming an anti-reflective film layer on a substrate by adjusting the reaction power and/or reactive gas flow during the formation of film by the chemical vapor deposition process; and step S2: forming a metal conductive film layer on the substrate finished in step S1. Through the preparation method of the array substrate, the anti-reflective film layer can have a sand-like granulation structure, such that light reflected from the metal conductive film layer can be blocked, thereby weakening or avoiding the light reflected from the surface of the metal conductive film layer, further improving the display effect of the array substrate.

Abstract: The present disclosure relates to an array substrate, a method of manufacturing the same and a display device. The array substrate comprises a gate line PAD region and a data line PAD region. In the gate line PAD region of the array substrate, gate-line wirings, which are parallel to the gate lines and are electrically insulated from the gate lines, are provided between adjacent gate lines. In the data line PAD region of the array substrate, data-line wirings, which are parallel to the data lines and are electrically insulated from the data lines, are provided between adjacent data lines. Both of the gate-line wirings and the data-line wirings are conductive wiring segments. By forming the gate-line wirings and the data-line wirings in the PAD region, the ability of resisting scratch of the product can be improved while not deteriorating performance of display of the product.

Abstract: The embodiments of the disclosure disclose a touch display panel, a method for fabrication thereof and a display device. The touch display panel comprises a display substrate, a transparent conductive layer formed on the display substrate, a transparent insulating layer formed on the transparent conductive layer, and a touch electrode formed on the transparent insulating layer. The embodiments of the disclosure can reduce accumulation of static electricity in the manufacture procedure of the display substrate and prevent electromagnetic interference when performing cell test by adding a transparent conductive layer and a transparent insulating layer between the touch substrate and the touch electrode.

Abstract: This disclosure discloses a touch display screen, a manufacturing method thereof and a display device. The touch display screen comprises: an opposite substrate, an array substrate, and a liquid crystal layer located between the opposite substrate and the array substrate, a side of the opposite substrate facing the liquid crystal layer being provided with a black matrix. The touch display screen further comprises: a first touch electrode, an insulating layer and a second touch electrode arranged in stack successively at a side of the opposite substrate back to the liquid crystal layer. The first touch electrode and the second touch electrode are located within an area corresponding to the black matrix respectively. The first touch electrode comprises a plurality of first touch sub-electrodes distributed along a first direction. The second touch electrode comprises a plurality of second touch sub-electrodes distributed along a second direction perpendicular to the first direction.

Abstract: A substrate and a manufacturing method thereof, and a display device are provided. The substrate comprises a base substrate (101), a metal black matrix (111) and an anti-reflection pattern (112A, 112B) for reducing optical reflectivity of the metal black matrix (111), which are arranged on the base substrate (101), and the anti-reflection pattern (112A, 112B) is arranged on a side of the metal black matrix (111) close to a light emission side of the substrate. The anti-reflection pattern (112A, 112B) reduces reflectivity of the metal black matrix (111) on outside ambient light, increases a display contrast of a display device that includes the substrate, and thus improves display quality of the pictures.

Abstract: The present disclosure provides a system and a method for debugging a robot based on artificial intelligence. The system includes: a mobile terminal; and the robot, in which the mobile terminal and the robot communicate with each other wirelessly, and the mobile terminal is configured to set a state parameter of each function node of the robot, and to send a control command to the robot according to the state parameter of each function node, so as to control the robot to perform a test.

Abstract: An array substrate and a manufacturing method thereof, a display panel and a display device are disclosed.

Abstract: The invention provides novel hydrophilic conjugated polymers, e.g., hydrophilic poly(arylene vinylenes) or PAVs, and preparation thereof, and methods and devices for their application in photovoltaics, and the resulting improved solar cells.

Abstract: Disclosed is an array substrate including a base substrate and a gate metal layer, a semiconductor layer, a source-drain metal layer, and a pixel electrode layer that are formed on the base substrate. The gate metal layer includes gate lines, gate electrodes of thin film transistors, and a plurality of first sensing lines extending along a row direction. The semiconductor layer includes an active layer of the thin film transistors, and a plurality of first photosensitive elements and a plurality of second photosensitive elements that are insulated from each other. The source-drain metal layer includes data lines, source electrodes and drain electrodes of the thin film transistors, and a plurality of second sensing lines extending along a column direction. Also disclosed are a method of fabricating the array substrate, an optical touch screen and a display device.

Abstract: A capability is provided for determining a fraction of content item versions to cache for use in responding to requests for content items. The fraction of content item versions to cache is determined based on a popularity distribution of the content item versions and cost model information associated with the content item versions. The cost model information may include information indicative of a cost of storing one of the content item versions and at least one of a cost of transcoding one of the content item versions or a cost of transferring one of the content item versions. The fraction of content item versions to cache may be determined based a skewness factor of the popularity distribution of the content item versions.

Abstract: An array substrate, a method for manufacturing the same and a display apparatus are provided. The array substrate comprises: a substrate (1); a common electrode (2) and a pixel electrode (10) sequentially formed on the substrate (1) and insulated from each other; a thin film transistor comprising a gate electrode (4), an active layer (7), a source electrode (8a) and a drain electrode (8b), wherein the drain electrode (8b) is electrically connected with the pixel electrode (10); a common electrode line (5) disposed in a same layer as the gate electrode (4); and an insulating layer (3) between the gate electrode (4) and the common electrode (2), wherein the common electrode (2) is connected with the common electrode line (5) through a through hole in the insulating layer (3).

Abstract: The present invention relates generally to a method of generating cells exhibiting multilineage potential and to cells generated thereby. More particularly, the present invention is directed to an in vitro method of generating mammalian stem cells from CD4* mononuclear cells, CD8* mononuclear cells, CD25* mononuclear cells, CD19* mononuclear cells or CD20* mononuclear cells and to cells generated thereby. This finding has now facilitated the design of means for reliably and efficiently generating populations of multilineage potential cells, such as stem cells, for use in a wide variety of clinical and research settings. These uses include, inter alia, the directed differentiation, either in vitro or in vivo, of the subject multilineage potential cells and the therapeutic or prophylactic treatment of a range of conditions either via the administration of the multilineage potential cells of the invention or the more fully differentiated cellular populations derived therefrom.

Abstract: Perovskite-containing solar cells are described herein. An inverted perovskite solar includes an anode substrate, a photoactive layer including a perovskite, a hole transport layer disposed between the anode substrate and the photoactive layer, an electron transport layer, a metal cathode layer, and an interlayer disposed between the electron transport layer and the metal cathode layer. A tandem solar cell includes a first sub-cell, a second sub-cell, and an interconnecting layer disposed between the first sub-cell and the second sub-cell. The first sub cell includes a perovskite layer having a thickness of 50 to 200 nanometers. The second sub-cell includes a photoactive layer and an interlayer disposed on the photoactive layer. The interlayers and the interconnecting layer each include a fullerpyrrolidine having a structure as defined herein.

Abstract: A memory management method and device are disclosed. The method includes: managing, by a storage management device, a memory; and when determining that a page table does not include a virtual address carried in a fetch request, managing, by the memory management device, the memory. When determining that the virtual address is valid, the memory management device applies for a blank page. The memory management device is located in a memory controller.

Abstract: An array substrate and a manufacturing method thereof, a display panel, and a display device are provided. The array substrate includes a substrate; a source-drain metallic layer and a first passivation metallic protective layer formed in sequence on the substrate, the source-drain metallic layer including a source electrode and a drain electrode not contacted with each other; a conductive protection layer formed on the substrate on which the first passivation metallic protection layer has been formed; and a pixel electrode formed on the substrate on which the conductive protection layer has been formed, the pixel electrode contacting the conductive protection layer.