Abstract: A touch display device includes a first substrate, a second substrate, a number of first sensing electrodes formed on the first substrate, a number of second sensing electrodes formed on the second substrate, a touch integrated circuit set on the first substrate, and a number of connecting wires formed on the first substrate. The touch integrated circuit includes a number of first pins correspondingly connected to the first sensing electrodes and a number of second pins correspondingly connected to the second sensing electrodes. The connecting wires correspondingly connect two opposite terminals of the first sensing electrodes with two opposite ends of the first pins. A part of connectint wires are arranged between the first pins and the second pins. The first substrate includes a shielding sheet formed in the first substrate and located above the part of the connecting wires arranged between the first pins and the second pins.

Abstract: In an aspect, a display device including: an entire window, said entire window including a display area and a non-display area outside the display area; a display panel; a first adhesive layer disposed on the display panel; a touch screen panel disposed on the first adhesive layer; a first light blocking member disposed on the touch screen panel; a second adhesive layer disposed on the touch screen panel and the first light blocking member; and a protection window disposed on the second adhesive layer is provided.

Abstract: An electric device of this disclosure includes: a display device including: a display element configured to display an image; a light source; an intermediate frame configured to hold the light source; and a planar light source device configured to illuminate the display element, and a proximity sensor arranged at an outside of the display device and configured to detect approaching information to the display device. The intermediate frame is provided with an extension part extending outwardly from the display device and a holding part configured to integrally hold the proximity sensor is formed at the extension part.

Abstract: Display device includes a display panel. The display panel includes a first substrate, a sealant, and, a second substrate fastended to the first substrate via the sealant. At least one of the first substrate and the second substrate is a non-planar substrate including at least two portions correspondingly extending in different planes.

Abstract: Disclosed is a display device. The display device includes a gate line and a data line intersecting the gate line to define a pixel area on a substrate, a TFT formed in the pixel area and including a gate electrode, a semiconductor layer, a source electrode, and a drain electrode, a first protective layer formed on the TFT structured such that a first hole exists through the first protective layer, a second protective layer formed on the first protective layer and structured such that a second hole exists through the second protective layer, wherein the size of the second hole differs from a size of the first hole, a pixel electrode formed on the second protective layer and at least partially filling the first and second holes, the pixel electrode connected to the drain electrode through the first and second holes.

Abstract: Disclosed herein is a display device including a substrate, a plurality of pixel electrodes arranged in a form of a matrix in a plane parallel with the substrate, a display functional layer exerting an image display function on a basis of an image signal supplied to the plurality of pixel electrodes, a driving electrode opposed to the plurality of pixel electrodes, and a plurality of detecting electrodes arranged in a form of a plane opposed to the driving electrode, separated and arranged at a pitch of a natural number multiple of an arrangement pitch of the pixel electrodes in one direction in the arrangement plane, and each capacitively coupled with the driving electrode.

Abstract: A liquid crystal display is provided that includes: a first display panel including a thin film transistor and a plurality of pixel electrodes; a second display panel facing the first display panel with a cell gap therebetween; a lower resistive layer disposed on the first display panel; an upper resistive layer disposed on the second display panel; and a sensing spacer connecting the lower resistive layer and the upper resistive layer.

Abstract: A liquid crystal display device in which a touch panel is embedded in a liquid crystal panel, which reduces the number of processes and eases assembly. The liquid crystal display device includes first and second substrates opposite each other, a thin film transistor array formed on the first substrate, a touch sensing part formed on the second substrate including a plurality of transparent X electrodes, a plurality of transparent Y electrodes orthogonally intersecting each other and a first transparent insulating film between the X electrodes and the Y electrodes, a color filter array formed on the touch sensing part, and a liquid crystal layer formed between the thin film transistor array and the color filter array.

Abstract: A barrier functional film that includes a substrate, at least one side wall barrier structure, a releasing film, and an adhesive is provided. The side wall barrier structure is located on the substrate. The releasing film is located above the substrate, and the side wall barrier structure is located between the substrate and the releasing film. The adhesive covers the side wall barrier structure and is located between the substrate and the releasing film. An environmental sensitive electronic device, a display apparatus, and a manufacturing method of a barrier functional film are also provided.

Abstract: A capacitive touch module includes a first glass layer, a second glass layer, a liquid crystal layer, a first insulating layer, a second insulating layer, a plurality of first electrodes, second electrodes and third electrodes. The liquid crystal layer is arranged between the first glass layer and the second glass layer. The first insulating layer is formed between the first glass layer and the liquid crystal layer. The second insulating layer is formed between the liquid crystal layer and the second glass layer. The plurality of first electrodes are formed between the liquid crystal layer and the first insulating layer along a first axis. The plurality of second electrodes are formed between the second insulating layer and the second glass layer along the first axis. The plurality of third electrodes are formed between the first insulating layer and the first glass layer along a second axis.

Abstract: It is an object to provide a touch panel which includes an A/D converter circuit and has a function of image shooting with high resolution and high-level gray scale and at high operation speed. A touch panel includes a plurality of pixels each provided with a display element and a photo sensor, an A/D converter to which a first potential is applied from a photo sensor, and a reading circuit. The A/D converter includes an oscillation circuit which changes the oscillating frequency of a first signal to be generated in accordance with the first potential and stops oscillating when a second potential is applied thereto from the reading circuit, and a counter circuit which generates a second signal having a discrete value determined in accordance with the oscillating frequency.

Abstract: A liquid crystal display device capable of reducing or preventing display irregularities is provided. In the liquid crystal display device including: an upper frame, a lower frame, a BL resin frame and a liquid crystal display panel and used as a display part as incorporated in an equipment, the liquid crystal display panel is fixed by the upper frame (fixation area). The BL resin frame includes BL resin frame ribs serving as a receiving part to receive a fixing device for fixing the liquid crystal display device to the equipment.

Abstract: A touch-sensing display panel including a front substrate, scan lines, data lines, pixel structures, photo-sensors, readout devices, a rear substrate and a display medium is provided. The front substrate has an inner surface. The scan lines and the data lines are on the inner surface of the front substrate and intersected to each other. The pixel structures are disposed on the inner surface of the front substrate, and each pixel structure is electrically connected to one of the scan lines and one of the data lines correspondingly. The photo-sensors are disposed on the inner surface of the front substrate. Each readout device is electrically connected to one of the photo-sensor correspondingly. The rear substrate is disposed opposite to the front substrate. The display medium is sealed between the front substrate and the rear substrate.

Abstract: Methods and devices for shielding displays from electrostatic discharge (ESD) are provided. In one example, a display of an electronic device may include a high resistivity shielding layer configured to protect electrical components from static charges. The display may also include a conductive layer electrically coupled to the high resistivity shielding layer and configured to decrease a discharge time of static charges from the high resistivity shielding layer. The display may include a grounding layer and a conductor electrically coupled between the conductive layer and the grounding layer to direct static charges from the conductive layer to the grounding layer.

Abstract: The transfer film of the present invention has a temporary support and a colored layer, and the colored layer contains at least (A) a white inorganic pigment and (B) a silicone-based resin.

Abstract: A touch panel assembly including a touch panel and a flexible printed circuit board is provided. The touch panel includes a sensing area, at least one input element, a bonding area, a plurality of first connecting traces and a plurality of second connecting traces. The sensing area has a sensing array. The input element is located at a side of the sensing area. The bonding area is located between the sensing area and the input element. The first connecting traces and the second connecting traces are connected with the sensing array and the input element respectively and extend into bonding area. The flexible printed circuit board has a bonding portion. The flexible printed circuit board is attached to the bonding area through the bonding portion, and is electrically connected to the first connecting traces and the second connecting traces. An electronic device is also provided.

Abstract: A display device includes: a display panel configured for displaying an image; at least one panel attached to the display panel; an adhesive layer formed between the display panel and the at least one panel and configured to attach the at least one panel to the display panel; a plurality of print layers formed on an outer circumferential surface of the at least one panel to block light transmitted through the adhesive layer; and a plurality of bubble outlets formed in at least one of the plurality of print layers to discharge bubbles included in the adhesive layer.

Abstract: An electrode structure for a touchscreen is provided. The electrode structure includes a flexible substrate and a plurality of electrode lines, wherein the electrode line includes a first adhesive layer, a second adhesive layer, a conductive layer, a first resist layer and a second resist layer. Through the configuration above, the electrode structure of the present application adheres the flexible substrate strongly by the first adhesive layer, and the second adhesive layer strengthen the adhesion between the first adhesive layer and the conductive layer, so that the conductive layer may be firmly adhered to the flexible substrate, even change the shape of the substrate, the electrode lines are not easy to fall off. The present invention also provides an electrode structure for scattering the reflective metallic luster to make observer imperceptible and reduce the backlight interference.

Abstract: A capacitive touch panel has multiple electrode couples formed on a substrate. Each electrode couple has multiple first electrodes and multiple second electrodes. Each of the first electrode and the second electrode has three traces. Each end of one of the three traces is connected to one end of one of the other two traces. The three traces of the first electrode and the three traces of the second electrode are alternately arranged. Given the foregoing layout of the electrode couples, the first electrodes and the second electrodes have symmetrical capacitance values and resistance values. Accordingly, the capacitive touch panel has an enhance signal-to-noise ratio and an anti-interference capability.

Abstract: There are disclosed display devices with integral touch screens and methods for operating display panels. A display panel may include a plurality of pixels, each pixel controlled by a corresponding one of a plurality of column electrodes and a corresponding one of a plurality of row electrodes. Each column electrode may be coupled to a respective column driver circuit and at least some of the column electrodes may be coupled to respective column sensing circuits adapted to sense capacitive coupling between the respective column electrodes and a probe adjacent to an external surface of the display panel. Each row electrode may be coupled to a respective row driver circuit and at least some of the row electrodes may be coupled to respective row sensing circuits adapted to sense capacitive coupling between the respective row electrodes and a probe adjacent to an external surface of the display panel.

Abstract: According to embodiments of the invention, an in-cell capacitive contact panel and a manufacturing method thereof are provided. The in-cell capacitive touch panel comprises an array substrate. The array substrate comprises a display pixel structure and a touch circuit, and the touch circuit comprises a sensing unit and an amplifying unit connected with each other. The sensing unit is connected to a gate line in the display pixel structure. A switch-on voltage is provided by the gate line in the display pixel structure to the sensing unit, a voltage is generated in the sensing unit after the sensing unit is switched on, the voltage generated in the sensing unit is changed by a touch operation, the amplifying unit amplifies the voltage change in the sensing unit and outputs the amplified voltage change.

Abstract: An in-cell touch display structure includes: an upper substrate, a lower substrate, a display material layer configured between the upper and lower substrates, and a thin film transistor and sensing electrode layer. The thin film transistor and sensing electrode layer includes a gate line sub-layer having a plurality of gate lines and a plurality of connection segments separated by the gate lines, and a source line sub-layer having a plurality of source lines, a plurality of sensing conductor lines, and a plurality of sensing conductor segments separated by the source lines and the sensing conductor lines, wherein part of the sensing conductor segments and part of the connection segments are electrically connected together to form a plurality of sensing conductor blocks.

Abstract: An in-cell touch liquid crystal display module includes a first glass substrate, a metal film disposed on the first glass substrate, a liquid crystal layer disposed on the metal film, a second glass substrate disposed on the liquid crystal layer, a conductive layer disposed on the second glass substrate for generating a sensing signal in response to a touch of the conductive layer, a flexible circuit board comprising a plurality of wires coupling the conductive layer, for transmitting the sensing signal, a conductive adhesive for adhering and fastening the flexible circuit board on the second glass substrate, and an insulating adhesive disposed on an periphery of the first glass substrate, for adhering the flexible circuit board on the first glass substrate.

Abstract: A touch panel includes dummy electrodes, disposed in a transmit electrode layer or a receive electrode layer whichever is below an isolation layer. In one embodiment, an anti-reflective layer includes at least one composite refractive-index three-layer structure. In another embodiment, the receive electrode layer is disposed below the isolation layer, and the receive electrode layer and the dummy electrodes are electrically coupled to a same electric potential.

Abstract: A touch device includes a first conducting layer, a second conducting layer, and a resistance reduction layer. The first conducting layer is insulated to the second conducting layer to form a touch sensing structure. The resistance reduction layer is coupled to the first conducting layer. A combination of the resistance reduction layer and the first conducting layer has a resistance that is less than an intrinsic resistance of the first conducting layer.

Abstract: Disclosed is a touch panel including a cover substrate including an active area and an inactive area, and a printing layer only on the inactive area. The printing layer includes a first printing layer, and a second printing layer to surround the first printing layer. The second printing layer includes a top surface making contact with the top surface of the first printing layer and a lateral side making contact with a lateral side of the first printing layer. The lateral side of the second printing layer has an average inclination angle in a range of about 1.5° to about 2.7° with respect to one surface of the cover substrate.

Abstract: An in-cell touch display structure includes: upper and lower substrates, a display material layer configured between the upper and lower substrates, and a thin film transistor and sensing electrode layer including a gate line sub-layer and a source line sub-layer. The gate line sub-layer includes plural gate lines arranged in a first direction, and plural first sensing conductor segments arranged in a second direction, The first sensing conductor segments are separated by the gate lines. The source line sub-layer includes plural source lines arranged in the second direction, plural second sensing conductor segments arranged in the first direction, and plural connection traces arranged in the second direction and parallel to the source lines. The second sensing conductor segments are separated by the source lines and the connection traces. The first sensing conductor segments are electrically connected to the second sensing conductor segments for forming a plurality sensing conductor blocks.

Abstract: A photosensitive pixel circuit of a touch module including an output transistor and a light detection unit is provided. The output transistor receives a reference signal and provides a touch voltage controlled by a light detection voltage. The light detection unit is electrically connected to the output transistor, and receives a touch scan signal. The light detection unit detects an intensity of a light according to the touch scan signal so as to correspondingly provide the light detection voltage.

Abstract: A display unit which can realize reduction in thickness and weight of the display unit by omitting a void between a touch panel and a display panel, and its manufacturing method. Whole faces of the touch panel and the display panel are directly bonded together with an adhesive layer in between. The display panel has a structure wherein a driving substrate in which organic light emitting devices are formed and a sealing substrate are bonded together with an adhesive layer in between. The touch panel has a structure wherein a lower plastic film in which a transparent electrode is formed and a touch-side plastic film in which a transparent electrode is formed are layered so that the transparent electrodes are placed opposite. The display panel is constructed with only the driving substrate, and the organic light emitting devices are sealed by the touch panel instead of the sealing substrate. Therefore, thickness and weight of the display unit can be further reduced.

Abstract: Embodiments of the present invention provide a double-vision touch display device and a manufacturing method thereof, and the double-vision touch display device comprises: a touch circuit; a grating, wherein, the touch circuit comprises: first touch electrodes, second touch electrodes, and a touch control module, and the first touch electrodes cross with and are insulated from the second touch electrodes, and the first touch electrodes and the second touch electrodes are connected with the touch control module, respectively, and the grating is made from an opaque conductive material and formed with the first touch electrodes synchronously.

Abstract: A touch display device includes an LCD panel, a flexible sensor film disposed on the LCD panel, a cover lens disposed on the flexible sensor film, a first adhesive layer between the flexible sensor film and the LCD panel, a second adhesive layer between the flexible sensor film and the cover lens, and a system mechanism part enclosing the above-described components.

Abstract: A touch panel includes a substrate, a plurality of first conductive elements, and a plurality of second conductive elements. Each of the first conductive elements includes a plurality of first conductive patterns and a plurality of first connection portions alternately connected with each other. The first conductive elements and the second conductive elements are intersected with each other and electrically insulated. Each of the second conductive elements includes a plurality of intersection portions respectively intersected with the first connection portions of each of the first conductive elements. A linewidth of the intersection portions is W1, and 100 ?m<W1?300 ?m.

Abstract: A liquid crystal display device and method for manufacturing the same are provided. A liquid crystal display (LCD) with a touch function includes: a pixel thin film transistor (TFT) in a display area, and a buffer TFT of a gate driver in a non-display area, wherein a lightly-doped drain (LDD) length of the buffer TFT is shorter than a lightly doped drain (LDD) length of the pixel TFT.

Abstract: A touch panel having a light transmitting area and a light shielding area adjacent to the light transmitting area is provided. The touch panel includes a cover plate, a first decoration layer, a touch-sensing element and a metal conductive layer. The first decoration layer is disposed on the cover plate and located in the light shielding area. The first decoration layer has at least one hollow area. The touch-sensing element is disposed on the cover plate and at least located in the light transmitting area. The metal conductive layer is disposed on the first decoration layer, located in the light shielding area and surrounds the touch-sensing element. A portion of the metal conductive layer surrounds the hollow area.

Abstract: A touch panel for a touch sensitive liquid crystal display is disclosed. The touch panel is a multiplier expandable with a combination of two or more independent basic conductive patterns. The combination of basic conductive patterns devised for a touch panel made the display profile diversified as building blocks. Different display profile can be made including but not limited to landscape, portrait, L, T, U, C, Z, N, and cross. The combination of basic conductive patterns devised for a touch panel also simplifies the structure of a touch sensitive expandable display system and therefore shorten the timing for developing new large touch sensitive display products.

Abstract: Provided is a touch panel substrate to be used in a touch panel, the touch panel substrate having improved display qualities. A touch panel substrate of one embodiment of the present invention is provided with a first detection electrode having a plurality of first lattice electrodes that are aligned in the lateral direction. Each of the first lattice electrodes includes conductor lines formed in a lattice shape parallel to the outer shape of each of the first lattice electrodes, and in each of the first lattice electrodes, the diagonal line between the two opposing corners adjacent to first relay wiring is tilted with respect to the lateral direction.

Abstract: A touch panel includes a substrate, a decoration pattern, a covering layer, and a touch sensing element. The substrate has a first region and a second region. The decoration pattern is disposed on the first region of the substrate and has a first thickness. The covering layer includes a first portion covering the second region of the substrate and a second portion covering the decoration pattern, wherein the second portion has a second thickness and the first portion has a third thickness. The second thickness is less than the third thickness. The touch sensing element is disposed on the covering layer.

Abstract: A touch screen includes a plurality of first transparent electrodes extending in a first direction and a plurality of second transparent electrodes extending in a second direction intersecting the first direction disposed on the substrate; first conductive layers located on at least one side of the first transparent electrodes and connected in parallel with the first transparent electrodes; and/or second conductive layers located on at least one side of the second transparent electrodes and connected in parallel with the second transparent electrodes; the first conductive layers and the second conductive layers are metal layers or alloy layers. A manufacturing method of the touch screen and a display device having the touch screen are further disclosed.

Abstract: Disclosed is a touch window. The touch window includes a cover substrate; a ground electrode on the cover substrate; and a circuit substrate on the cover substrate, including aground connecting part connected with the ground electrode and an open area to expose the ground connecting part, wherein the ground electrode is electrically connected to the ground connecting part through the open area.

Abstract: An electronic device may have a touch screen display or other input-output device that includes transparent conductive electrodes. The transparent conductive electrodes may be formed from a material that has a relatively high index of refraction such as indium tin oxide. Surrounding layers of the touch screen display such as a touch sensor substrate and an underlying display layer may have lower index of refraction values. To prevent abrupt index-of-refraction discontinuities that lead to unwanted reflections and visible artifacts on the display, the transparent conductive electrodes may be embedded within a dielectric layer. The dielectric layer may have a graded index of refraction. The graded index of refraction may be varied continuously or in a stepwise fashion by adjusting the composition of materials that are incorporated into the dielectric layer as a function of position within the layer.

Abstract: A curved touch device is provided in the present invention including a back cover and a touch panel corresponding to the back cover, where at least one edge portion of the touch panel is a curve surface jointing with the one edge of the back cover.

Abstract: In a seal part where a translucent opposite substrate and an element substrate are bonded together, a peripheral member is provided in such a manner as to be buried in a sealing member. This prevents the sealing member from breaking, thus making it possible to make the seal part durable to improve the strength of the panel. Further, an output wiring connected to an electrode pattern of a sensing unit can be protected by being covered with a protective insulating layer. The peripheral member and the protective insulating layer can be formed by the same insulating material. This makes it possible to simplify the process to reduce production costs.

Abstract: An electronic device includes a case frame including a component receiving space, a substrate assembly received in the component receiving space of the case frame, and a display module electrically connected to the substrate assembly and coupled to the case frame to form an exterior of the electronic device. Thus, the electronic device can lower a production cost by reducing the number of the components, increase production efficiency by reducing the assembly processes, and achieve slimness and lightness compared to a conventional electronic device.

Abstract: A touch panel includes a transparent substrate, electrodes, traces and at least two ground rings on the transparent substrate. The traces connect the electrodes to transmit signals. At least two ground rings connect to each other through a plurality of bridges and surround the electrodes and the traces. Each bridge has at least one ESD tip or peak to enhance local electric field strength and electrostatic discharge.

Abstract: An operating device for an electric appliance has a display panel for a user to read off information and to operate the electric appliance with operating elements, wherein the display panel has an LCD display covering substantially the area of the display panel. The LCD display has several separate active areas, wherein behind the LCD display a transparent flat material or foil is provided as a picture carrier having several separate pictures on one of its surfaces. Behind the transparent picture carrier a backlight device is provided for lighting through the picture carrier and the LCD display.

Abstract: A touch display device including a display, a touch panel and a transparent shielding layer is provided. The touch panel is disposed on the display, and includes a substrate and touch sensors positioned thereon. The transparent shielding layer is set between the display and the touch sensors of the touch panel, and includes an edge region and a central region wherein the impedance of the edge region is less than or equal to that of the central region.

Abstract: A method for making a liquid crystal display module is provided. In the method, a first polarizing layer is provided. A free-standing transparent conductive layer is disposed on a surface of the first polarizing layer. At least two driving-sensing electrodes are disposed on a surface of the transparent conductive layer and spaced from the first polarizing layer. The at least two driving-sensing electrodes are spaced from each other and electrically connected with the transparent conductive layer. The first polarizing layer, the at least two driving-sensing electrodes, and the transparent conductive layer cooperatively form a polarizer. The polarizer is fixed to a liquid crystal module to form the liquid crystal display module.

Abstract: A sensor device includes: a first base material and a second base material disposed apart to face each other; a plurality of first adhesion sections that are two-dimensionally arranged in a gap between the first base material and the second base material and have elasticity; and a mitigation section configured to mitigate an increase in contact area of each of the first adhesion sections to one of the first base material and the second base material, the contact area increasing as the gap narrows.

Abstract: A pressure-sensitive adhesive layer-bearing polarizing film for a transparent conductive coating, includes an iodine-based polarizing film and a pressure-sensitive adhesive layer placed on at least one side of the polarizing film, wherein the iodine-based polarizing film includes an iodine-based polarizer containing 1 to 14% by weight of iodine and/or iodide ions and having a thickness of 2 to 40 ?m and a transparent protective film provided on at least one side of the polarizer and having a water-vapor permeability of 1,000 g/(m2·24 hours) or less at 60° C. and 90% R.H., and the pressure-sensitive adhesive layer has a saturated water content of 3.5% by weight or less at 60° C. and 90% R.H.

Abstract: A touch device includes a cover substrate, a thin substrate, a first adhesive layer, a first touch sensing unit and a first outer unit. The thin substrate is disposed opposite to the cover substrate. The thin substrate has a first surface and a second surface opposite to the first surface. The first surface faces the cover substrate. A thickness of the thin substrate is thicker than or equal to 0.05 millimeter and thinner than or equal to 0.25 millimeter. The first adhesive layer is disposed between the cover substrate and the thin substrate. The first touch sensing unit is disposed on the thin substrate. The first outer unit is electrically connected to the first touch sensing unit.