Abstract: A touch sensing device is provided. The provided touch sensing device may include a touch sensing circuit having a conducting unit for generating an alternating current (AC) touch signal, a phase delaying circuit electrically coupled to the touch sensing circuit for receiving the AC touch signal and delaying the AC touch signal for a predetermined phase so as to derive a delayed signal, and a determination circuit electrically coupled to the touch sensing circuit and the phase delaying circuit for comparing intensities of the delayed signal and the AC touch signal with a predetermined threshold in order to derive a waveform-overlapping time period. When the waveform-overlapping time period is longer than a predetermined period, the determination circuit concludes the conducting unit is approached or contacted by the conductor.

Abstract: A transparent conductive structure applied to a touch panel includes a substrate unit, a first coating unit, a transparent conductive unit, and a second coating unit. The substrate unit includes a transparent substrate. The first coating unit includes a first coating layer formed on the top surface of the transparent substrate. The transparent conductive unit includes a transparent conductive layer formed on the top surface of the first coating layer. The transparent conductive layer includes a plurality of conductive circuits arranged to form a predetermined circuit pattern. The second coating unit includes a second coating layer formed on the top surface of the transparent conductive layer. The second coating layer has a touching surface formed on the top side thereof for an external object to touch. The second coating layer is substantially formed by mixing silicon oxide, aluminum oxide, lithium oxide and Teflon.

Abstract: A touch sensing device is provided. The provided touch sensing device may include a touch sensing circuit having a conducting unit for generating an alternating current (AC) touch signal, a phase delaying circuit electrically coupled to the touch sensing circuit for receiving the AC touch signal and delaying the AC touch signal for a predetermined phase so as to derive a delayed signal, and a determination circuit electrically coupled to the touch sensing circuit and the phase delaying circuit for comparing intensities of the delayed signal and the AC touch signal with a predetermined threshold in order to derive a waveform-overlapping time period. When the waveform-overlapping time period is longer than a predetermined period, the determination circuit concludes the conducting unit is approached or contacted by the conductor.

Abstract: A composite poly-silicon substrate for solar cell having a first substrate layer and a second substrate layer is disclosed. The purity of the first substrate layer ranges from 2N to 3N. The second substrate layer is formed on the first substrate layer, and the purity of the second substrate layer ranges from 6N to 9N.

Abstract: A manufacturing method of a composite poly-silicon substrate of solar cells includes the following steps: providing a first substrate layer having a purity ranging from 2N to 3N; and forming a second substrate layer on the first substrate layer, where the purity of the second substrate layer ranges from 6N to 9N.

Abstract: The present invention discloses a conductive film including a substrate, a reflective index adjusting structure, and a transparent conductive layer. The reflective index adjusting structure may be disposed on the substrate, and the transparent conductive layer may be disposed on the reflective index adjusting structure, which may be disposed between the transparent conductive layer and the substrate. The transparent conductive layer may cover parts of the reflective index adjusting structure. When a light enters into the transparent conductive layer/the reflective index adjusting structure of the conductive film with an incident angle, the light may be associated with a first reflectance/a second reflectance. The difference between the first reflectance and the second reflectance is designed to be lower than a first threshold value. Accordingly, the present invention may eliminate the display difference between an etched and a non-etched area of the conductive film and improve the visual quality.

Abstract: The present invention discloses a conductive film including a substrate, a first hard coated layer, a second hard coated layer, a first refraction layer, a second refraction layer, and a transparent conductive layer, which are arranged in a predetermined order. The second hard coated layer has the silicon-based material accounting for certain percentages of the weight thereof, and the transparent conductive layer may cover parts of the second refraction layer. When a light enters into the transparent conductive layer/the second refraction layer with an incident angle, the light may be associated with a first reflectance/a second reflectance. The difference between the first reflectance and the second reflectance is designed to be lower than a first threshold value. Accordingly, the present invention may eliminate the display difference between an etched and a non-etched area of the conductive film and improve the visual quality.

Abstract: The present invention discloses a conductive film including a substrate, a hard coated layer, a first refraction layer, a second refraction layer, and a transparent conductive layer. The hard coated layer may be disposed on the substrate with the silicon-based material accounting for certain percentages of the weight thereof. Placement of the first refraction layer, the second refraction layer, and the transparent conductive layer may be arranged in a predetermined order. The transparent conductive layer may cover parts of the second refraction layer. When a light enters into the transparent conductive layer and the second refraction layer with an incident angle, the light may be associated with a first reflectance and a second reflectance, respectively. The difference between the first reflectance and the second reflectance may be lower than a first threshold value for eliminating the display difference between an etched and a non-etched area of the conductive film.

Abstract: A conductive multilayer structure includes a substrate, a transparent conductive film, a hard-coated layer and a protective layer. The substrate has opposite first and second surfaces, and has non-organic powders mixed therein. The thickness of the substrate is ranged from 100 micrometers to 125 micrometers. The transparent conductive film is formed on the first surface. The hard-coated layer is formed on the second surface. The protective layer is formed on the hard-coated layer.

Abstract: A transparent conductive structure applied to a touch panel includes a substrate unit, a first coating unit, a transparent conductive unit, and a second coating unit. The substrate unit includes a transparent substrate. The first coating unit includes a first coating layer formed on the top surface of the transparent substrate. The transparent conductive unit includes a transparent conductive layer formed on the top surface of the first coating layer. The transparent conductive layer includes a plurality of embedded conductive circuits embedded therein and arranged to form a predetermined embedded circuit pattern. The second coating unit includes a second coating layer formed on the top surface of the transparent conductive layer to cover the embedded conductive circuits. The second coating layer has a touching surface formed on the top side thereof, and the touching surface allows an external object (such as user's finger or touch pen) to touch.

Abstract: A transparent conductive structure applied to a touch panel includes a substrate unit, a first coating unit, a transparent conductive unit, and a second coating unit. The substrate unit includes a transparent substrate. The first coating unit includes a first coating layer formed on the top surface of the transparent substrate. The transparent conductive unit includes a transparent conductive layer formed on the top surface of the first coating layer. The transparent conductive layer includes a plurality of conductive circuits arranged to form a predetermined circuit pattern. The second coating unit includes a second coating layer formed on the top surface of the transparent conductive layer. The second coating layer has a touching surface formed on the top side thereof for an external object to touch. The second coating layer is substantially formed by mixing silicon oxide, aluminum oxide, lithium oxide and Teflon.

Abstract: A transparent conductive structure applied to a touch panel includes a substrate unit, a first coating unit, a transparent conductive unit, and a second coating unit. The substrate unit includes a transparent substrate. The first coating unit includes a first coating layer formed on the top surface of the transparent substrate. The transparent conductive unit includes a transparent conductive layer formed on the top surface of the first coating layer. The transparent conductive layer includes two transparent conductive films stacked on top of each other and a plurality of embedded conductive circuits formed between the two transparent conductive films and arranged to form a predetermined embedded circuit pattern. The second coating unit includes a second coating layer formed on the top surface of the transparent conductive layer. The second coating layer has a touching surface on the top side thereof for an external object to touch.

Abstract: A transparent conductive structure applied to a touch panel includes a substrate unit, a first coating unit, a transparent conductive unit, and a second coating unit. The substrate unit includes a transparent substrate. The first coating unit includes a first coating layer formed on the top surface of the transparent substrate. The transparent conductive unit includes a transparent conductive layer formed on the top surface of the first coating layer. The transparent conductive layer includes a plurality of conductive circuits arranged to form a predetermined circuit pattern. The second coating unit includes a second coating layer formed on the top surface of the transparent conductive layer to cover the conductive circuits. The second coating layer has a touching surface formed on the top side thereof, and the touching surface allows an external object (such as user's finger, any type of touch pen, or etc.) to touch.

Abstract: A transparent conductive structure applied to a touch panel includes a substrate unit, a first coating unit, a transparent conductive unit, and a second coating unit. The substrate unit includes a transparent substrate. The first coating unit includes a first coating layer formed on the top surface of the transparent substrate. The transparent conductive unit includes a transparent conductive layer formed on the top surface of the first coating layer. The transparent conductive layer includes a plurality of embedded conductive circuits embedded into the first coating layer and arranged to form a predetermined embedded circuit pattern. The second coating unit includes a second coating layer formed on the top surface of the transparent conductive layer. The second coating layer has a touching surface formed on the top side thereof, and the touching surface allows an external object (such as user's finger, any type of touch pen, or etc.) to touch.

Abstract: A transparent conductive structure includes a substrate unit, a first coating unit, a diffusion barrier structure, a second coating unit, a third coating unit and a conductive unit. The substrate unit includes a plastic substrate. The first coating unit includes a first coating layer formed on the plastic substrate. The diffusion barrier structure is formed on the first coating layer. The diffusion barrier structure includes a first oxide unit having a plurality of first oxide layers and a second oxide unit having a plurality of second oxide layers. The first oxide layers and the second oxide layers are stacked on top of each other alternately. The second coating unit includes a second coating layer formed on the diffusion barrier structure. The third coating unit includes a third coating layer formed on the second coating layer. The conductive unit includes a transparent conductive film formed on the third coating layer.

Abstract: A transparent conductive structure includes a substrate unit and a conductive unit. The substrate unit includes at least one plastic substrate. The conductive unit includes at least one transparent conductive film and at least one nanometer conductive group formed at the same time, wherein the transparent conductive film is formed on the plastic substrate, and the nanometer conductive group includes a plurality of conductive nanowire filaments mixed or embedded in the transparent conductive film. In other words, both the transparent conductive film and the nanometer conductive group in the instant disclosure can be respectively formed by two different forming methods (such as sputtering and vaporing) at the same time, and the conductive nanowire filaments of the nanometer conductive group can be formed inside the transparent conductive film.

Abstract: A multi-layer coating structure with anti-reflection, anti-static and anti-smudge functions includes a substrate and a coating module. The coating module is formed on a front surface of the substrate and composed of a plurality of indium tin oxide compound coating layers and a plurality of silicon dioxide compound coating layers that are alternately stacked upon each other. The coating module further includes a fluorocarbon compound coating layer that is the uppermost layer of the coating module. Because the surface layer has good electrical conductive properties, the surface layer reduces much of the work in the grounding process and also increases the total yield and reliability in high volume production. The present invention provides a surface conductive layer structure with an anti-reflection coating that can be applied to the LCD and PDP display industries for glass and plastic film substrates.

Abstract: A manufacturing method of conductive circuits of a touch panel includes the following steps: providing a substrate with a conductive area thereon; providing at least one hard coating layer on the conductive area of the substrate; forming a plurality of grooves on the hard coating layer; forming a metal layer on the hard coating layer and in the grooves; and heating the metal layer so as to condense the metallic materials thereof in the grooves due to surface tension, thus forming a plurality of conductive circuits.

Abstract: A multilayer film structure for increasing transmittance includes a transparent substrate and a multifunctional film module. The multifunctional film module is formed on a front surface of the transparent substrate and composed of a plurality of dielectric layers and a plurality of metal layers. The dielectric layers and the metal layers are alternately stacked onto each other, and each metal layer is formed by mixing at least two metals. Each dielectric layer is a silicon carbide compound layer that is SiC, and each metal layer is formed by mixing Ag and Cu.

Abstract: An extreme low resistivity light attenuation anti-reflection coating structure in order to increase transmittance of blue light, includes a substrate and a coating module. The coating module is formed on a front surface of the substrate and composed of a plurality of silicon carbide compound coating layers, a plurality of Al-based oxide coating layers and a plurality of metal coating layers that are alternately stacked onto each other.