Abstract: A touch display having a laminated structure is provided in present disclosure. The touch display comprises a touch panel, a display module, and a step-shaped gasket element. The display module has a step-shaped structure formed due to a height difference, wherein the step-shaped structure is located in an edge area of the display module. The gasket element inosculates with the step-shaped structure of the display module to fill the height difference in the edge area of the display module. In accordance with present disclosure, the gasket element is not in a suspended state usually caused when the gasket element is not being supported by display module and is effectively laminated to an outer frame of display module, thereby enhancing the reliability of lamination of touch panel and display module. Moreover, a laminated structure and a laminating method for touch display having, the laminated structure are provided in present disclosure.

Abstract: The present disclosure relates to an optical panel, and more particularly, to a stack-up structure of an optical panel and the manufacturing method thereof, wherein the stack-up structure comprises: a first laminating element, which has a first laminating face; and a first protective layer, which is formed on the first laminating face of the first laminating element for flattening the first laminating face. The present disclosure allows a protective layer to be coated on a surface of a laminate to overcome unevenness problem on the surface of the laminating element, thereby avoiding generation of bubbles and enhancing the yield of products.

Abstract: A touch panel comprises of a plurality of first strip sensing electrodes and a plurality of second strip sensing electrodes. The first strip sensing electrodes are respectively disposed in a plurality of strip sensing regions with fixed lengths, and each of the second strip sensing electrodes is disposed corresponding to each of the first stripe sensing electrodes in each of the stripe sensing regions. Each second strip sensing electrode and corresponding first strip sensing electrode are electrically disconnected from each other. Length of each second strip sensing electrode and length of the corresponding first strip sensing electrode are complementary to each other. In one embodiment of the present disclosure, a method for manufacturing the touch panel is also disclosed.

Abstract: The present disclosure relates to an input interface and particularly to a novel touch panel which includes a plurality of first axial electrodes and a plurality of second axial electrodes. Each of the first axial electrodes is extended in a first direction. Each of the first axial electrodes includes a plurality of first inductive electrodes, a plurality of second inductive electrodes, and a plurality of first connecting lines. The first inductive electrodes and the second inductive electrodes are disposed alternatively along a first direction. Each of the first connecting lines is disposed between the first inductive electrodes and the second inductive electrodes. Each of the second axial electrodes is extended in a second direction. Each of the second axial electrodes has a plurality of hollow areas arranged along the second direction, and each of the first inductive electrodes is disposed within said hollow areas.

Abstract: The present disclosure relates to a touch technology, especially to a touch device and a manufacturing method thereof. The touch device comprises a sensing electrode structure, a shielding layer, a plurality of peripheral connection wires and a grounding wire. The shielding layer surrounds the periphery of the sensing electrode structure. The plurality of peripheral connection wires are located under the shielding layer and electrically connected to the sensing electrode structure. The grounding wire is electrically connected to the shielding layer. Thus, in accordance with the present disclosure, the touch device can shield external interference, and the reliability for operation of the touch circuit can be improved.

Abstract: The present disclosure relates to a touch technology, more particularly to a touch panel and a manufacturing method thereof. The touch panel comprises a touch area and a peripheral area. The touch panel further comprises: at least one peripheral line, each of which has a stacking structure and is disposed in the peripheral area surrounding the touch area for transmitting touch signals generated by the touch area. The stacking structure of each peripheral line improves stability of the touch signals transmission in the touch panel.

Abstract: The present disclosure relates to a touch display device and a method of manufacturing the same. The touch display device comprises a touch panel, a display module and a first adhesive layer formed by an ultraviolet-curing liquid adhesive, wherein the first adhesive layer laminates the touch panel and the display module. The touch display device further comprises of a lens and a second adhesive layer, wherein the second adhesive layer laminates the touch substrate layer and the lens. The present disclosure overcomes shading effect by curing the first adhesive layer and the second adhesive layer by adjusting the order of laminating the display module with the touch substrate and the lens so as to improve yield of lamination between the touch panel and the display module.

Abstract: A touch sensing device is disclosed. The touch sensing device comprises a touch sensing circuit layer disposed on a lower surface of a substrate; and a shielding structure disposed under the touch sensing circuit layer along with the touch sensing circuit layer at the same side of the substrate, wherein the shielding structure comprises a conductive layer and a supporting layer. An electronic device having the touch sensing device is also provided. The touch sensing device of the present disclosure can not only provide shielding function but also can avoid generating improper background capacitance, thereby preventing reduction or failure of touch sensitivity of the touch sensing device.

Abstract: The present disclosure relates to a display device, and more particularly to a reflective touch display and a fabrication method thereof The reflective touch display comprises a reflective display device, a first bonding layer, a light guiding plate, a second bonding layer, and a touch screen. The light guiding plate is laminated to top surface of the reflective display through the first bonding layer. The touch screen is laminated to top surface of the light guiding plate through the second bonding layer. The first bonding layer and the second bonding layer are formed by a liquid bonding material that transforms from a liquid state to a solid state, wherein refraction index of each of the first and second bonding layer is less than that of the light guiding plate. In accordance with the present disclosure, yield rate can be increased and production cost can be reduced.

Abstract: The present disclosure relates to a touch-on-lens (TOL) device and a method for manufacturing the same. The method includes forming a plastic layer and a touch layer; cutting the plastic layer and the touch layer; and filially laminating the plastic layer and the touch layer after cutting to a strengthened lens. The method can not only help keep good mechanical property but can also help improve the efficiency of mass production. Moreover, the present disclosure adopts a photoetching process to form a sensing pattern, thereby making the circuit thinner and beautifying the appearance.

Abstract: The present invention provides a touch sensing including a plurality of first sensing lines. Each first sensing line includes a first main trace and a plurality of first trace patterns wherein at least a first cross posit is disposed between the first main trace and the trace patterns. The present invention further provides a touch panel of using the same.

Abstract: The present disclosure provides a manufacturing method of a touch panel that comprises of: simultaneously baking a sensing electrode layer and a protective layer that covers the sensing electrode layer. The present disclosure solves the issue of the sensing electrode layer being easily oxidized or corroded when baked alone. The present disclosure also simplifies the manufacturing process of the touch panel. The present disclosure also provides a touch panel on the basis of the manufacturing method.

Abstract: A touch panel includes a substrate, a first and a second patterned conductive layers respectively disposed on an upper surface of the substrate and a lower surface opposite to the upper surface. The substrate has a first sensing area and a first circuit bonding area located on the upper surface. The first patterned conductive layer includes a plurality of first sensing series and a plurality of first dummy patterns respectively located in the first sensing area and the first circuit bonding area. Each of the first sensing series is electrically insulated from each other and has a first terminal extending into the first circuit bonding area. The first dummy patterns surround each first terminal and are electrically insulated from each first terminal. A plurality of first dummy patterns intervenes between any two adjacent first terminals in the first circuit bonding area.

Abstract: Methods for fabricating field emission display devices. A first substrate is provided. A cathode structure is formed on the first substrate. A surface treatment procedure is performed on the first substrate with cathode structure thereon. A second substrate opposing the first substrate is provided and assembled in vacuum with a wall rib therebetween. The surface treatment procedure includes free radical oxidization and a supercritical CO2 fluid cleaning.

Abstract: Methods for fabricating field emission display devices. A first substrate is provided. A cathode structure is formed on the first substrate. A surface treatment procedure is performed on the first substrate with cathode structure thereon. A second substrate opposing the first substrate is provided and assembled in vacuum with a wall rib therebetween. The surface treatment procedure includes free radical oxidization and a supercritical CO2 fluid cleaning.

Abstract: The present invention provides a cathode plate of the field emission display and the fabrication method thereof. The emission layer is formed on the electrode layer within the trench in a self-aligned way by screen printing or ink-jetting. Since the emission layer is accurately aligned with the electrode layer, the pattern quality is improved and the overflow or disrupture problems in screen printing are alleviated.

Abstract: Methods for fabricating carbon nano-tube (CNT) powders and field emission display devices. Carbon nano-tube powders are deposited and gathered in a vacuum chamber. A physical surface treatment is performed on the carbon nano-tube powders. The carbon nano-tube powders are mixed into a paste and screen printed on a substrate, wherein the physical surface treatment comprises laser radiation, ion-beam bombardment, high energy particle bombardment, or electron-beam bombardment.

Abstract: A field emission display module. A white field emission display (FED) comprises a plurality of dots (pixels) arranged in matrix, generating different gray levels according to external display data. A color filter display is disposed on the white field emission display, generating color images with the gray levels generated by the white field emission display.