A pixel unit structure, as well as a manufacturing method thereof, is provided. The pixel unit structure includes a display medium module and an active switching element. The display medium module includes a first electrode, a second electrode and a display medium. The first electrode and the second electrode are separated from each other, and the display medium is disposed between the first electrode and the second electrode. The active switching element is electrically connected to the first electrode, for allowing the first electrode and the second electrode to change the state of the display medium. The active switching element includes a wafer portion and a transistor portion, which is formed on the wafer portion. Therefore, the active switching element can be manufactured independently without the restriction from the display medium module.

A display device includes a substrate, at least one light emitting unit bound on the substrate, a transparency controllable unit disposed on the substrate, and an integrated circuit unit overlapped with the substrate. The integrated circuit unit includes a semiconducting structure and a conductive structure overlapped with the semiconducting structure. The integrated circuit unit is electrically connected to the at least one light emitting unit and the transparency controllable unit.

To increase the yield of the separation process. To produce display devices formed through the separation process with higher mass productivity. A first layer is formed using a material including a resin or a resin precursor over a substrate. Then, first heat treatment is performed on the first layer, whereby a first resin layer including a residue of an oxydiphthalic acid is formed. Then, a layer to be separated is formed over the first resin layer. Then, the layer to be separated and the substrate are separated from each other. The first heat treatment is performed in an atmosphere containing oxygen.

In a peeling starting portion preparing method of a laminate, for the laminate including a first substrate and a second substrate peelably attached via an adsorption layer, a knife is inserted with a predetermined amount from an end surface of the laminate into an interface between the first substrate and the adsorption layer so as to prepare the peeling starting portion at the interface. The knife includes a main body portion, a cutting edge portion continuous with the main body portion and tapered in a side view, and a ridge line which is a boundary between the main body portion and the cutting edge portion, and at least a part of the adsorption layer is scraped off by a ridge line portion including the ridge line.

A pixel unit structure, as well as a manufacturing method thereof, is provided. The pixel unit structure includes a display medium module and an active switching element. The display medium module includes a first electrode, a second electrode and a display medium. The first electrode and the second electrode are separated from each other, and the display medium is disposed between the first electrode and the second electrode. The active switching element is electrically connected to the first electrode, for allowing the first electrode and the second electrode to change the state of the display medium. The active switching element includes a wafer portion and a transistor portion, which is formed on the wafer portion. Therefore, the active switching element can be manufactured independently without the restriction from the display medium module.

A method of producing a CF board and an array board includes: a separation film forming process for forming separation films on supporting substrates; a component support forming process for forming resin substrates on the separation films; a thin film component forming process for forming TFTs and color filters that are thin film components on the resin substrates; a light applying process for applying light to the separation films for accelerating removals of the resin substrates; a determining process for determining whether levels of adhesion between the separation films and the resin substrates are high or low based on image data obtained through capturing of images of the separation films, and a removing process for removing the resin substrates from the supporting substrates if the levels of adhesion are determined low in the determining process.

Display panel and display device are provided. The display panel includes a substrate and an array layer arranged on a side of the substrate. The array layer includes a first metal layer, an active layer, and a second metal layer. Along a first direction, the first metal layer and the second metal layer are on two sides of the active layer, and the first direction is perpendicular to the substrate. The array layer includes at least one first transistor including a first sub-transistor and a second sub-transistor connected in series, and the first sub-transistor includes a first active layer in the active layer, the second sub-transistor includes a second active layer in the active layer, the first active layer is connected to the second active layer. Along the first direction, the first metal layer overlaps both the first active layer and the second active layer.

In a display device including a backlight and a display panel, the area of the backlight is divided into a plurality of unit regions; the display panel includes pixels which are larger in number than the unit regions; a frame rate of image data input to the device is converted to perform display while part of the unit regions in which black is displayed is in a non-light emission state; and the driving frequency of the backlight is converted in accordance with the display.

The invention provides a manufacturing method for flexible array substrate. The method comprises: adhering the flexible substrate to the rigid support plate to manufacture the back side driver circuit and the protective layer on the back side driver circuit; peeling the flexible substrate off, turning the flexible substrate over and then adhering again to the rigid supporting plate to manufacture the protecting layer and the adhesive layer; forming holes, front side driver circuit and display circuit on the flexible substrate, the back side driver circuit electrically connected to the display circuit and the back side driver circuit electrically connected to the display circuit through the holes to obtain a flexible array substrate with double-sided circuit structure. By distributing the circuit structure of the non-active area to both sides of flexible substrate, the width of the non-active area is reduced to realize an ultra-narrow border or borderless display.

There is provided a peeling method capable of preventing a damage to a layer to be peeled. Thus, not only a layer to be peeled having a small area but also a layer to be peeled having a large area can be peeled over the entire surface at a high yield. Processing for partially reducing contact property between a first material layer (11) and a second material layer (12) (laser light irradiation, pressure application, or the like) is performed before peeling, and then peeling is conducted by physical means. Therefore, sufficient separation can be easily conducted in an inner portion of the second material layer (12) or an interface thereof.