Abstract: A thin film transistor array substrate and the manufacturing method thereof are disclosed herein. A first patterned metal layer, an insulating layer, a patterned layer, and a second patterned metal layer are sequentially formed on a substrate. Then, a number of scan lines and a number of source lines are disposed on the substrate and define a number of pixel regions. A number of the storage capacitance lines are disposed on the substrate in a direction extending along the scan lines and across the pixel regions, wherein each of the storage capacitance lines is essentially perpendicular to each of the source lines and to form a cross portion. A number of patterned thin films are disposed on the storage capacitance lines and above the cross portion.

Abstract: The present invention relates to an interpolation method for enlarging an image, wherein the image is composed of plural scanning lines. Firstly, it selects four adjacent continuous pixels xk?1, xk, xk+1, and xk+2 which have the pixel values f(xk?1), f(xk), f(xk+1), and f(xk+2) respectively on each of the scanning lines; next, it determines three linear equations Lk?1, Lk, and Lk+1 according to every two adjacent pixel values f(xk?1) and f(xk), f(xk) and f(xk+1), and f(xk+1) and f(xk+2), respectively; then, it selects a pixel x to be interpolated between the pixel xk and the pixel xk+1; finally, it applies the pixel x to the three linear equations Lk?1, Lk, and Lk+1 to determine three candidate pixel values which are weighted and combined to obtain pixel value f(x) of the pixel x.

Abstract: A thin film transistor array substrate and the manufacturing method thereof are disclosed herein. A first patterned metal layer, an insulating layer, a patterned layer, and a second patterned metal layer are sequentially formed on a substrate. Then, a number of scan lines and a number of source lines are disposed on the substrate and define a number of pixel regions. A number of the storage capacitance lines are disposed on the substrate in a direction extending along the scan lines and across the pixel regions, wherein each of the storage capacitance lines is essentially perpendicular to each of the source lines and to form a cross portion. A number of patterned thin films are disposed on the storage capacitance lines and above the cross portion.

Abstract: A polyurethane composite is disclosed comprising rigid polyurethane and foamed thereupon a flexible integral skin (surface pore closed) polyurethane foam, wherein the rigid polyurethane having a density range of 600 kg/m3 to 1200 kg/m3, a Shore A hardness range of 90 to 99, a Shore D hardness range of 40 to 80, a tensile strength range of 10 MPa to 60 MPa, a flexural strength range of 20 MPa to 60 Mpa, a elastic flexural modulus range of 800 MPa to 2500 Mpa, an elongation rate at break of 10-100% and an elongation at break of 25-150%; wherein the flexible integral skin (surface pore closed) polyurethane foam having a density range of 60 kg/m3 to 200 kg/m3, a tensile strength of 60 kPa to 250 kPa, an elongation at break of 70-180%, a tearing strength of 130-220 N/m, a resilience of falling ball of 40-70%, IFD25% of 200-600 N and IFD65% of 600-1800 N.

Abstract: An immunoassay cartridge for sensing at least one analyte in a biological sample is disclosed. The immunoassay cartridge comprises a supporting plate, a reaction cavity made within the supporting plate and having at least one analyte-binding molecule immobilized therein, a sample receiving end connected to the reaction cavity to allow the biological sample to flow into the reaction cavity for forming at least one complex of the analyte and the analyte-binding molecule, a first package containing a recognizing molecule, a first channel communicating the first package and the reaction cavity to allow the recognizing molecule to flow into the reaction cavity for forming a first product of the complex and the complex-binding molecule, a second package containing a buffer solution and a second channel communicating the second package and the reaction cavity to allow the buffer solution to flow into the reaction cavity.

Abstract: A thin film transistor array substrate and the manufacturing method thereof are disclosed herein. A first patterned metal layer, an insulating layer, a patterned layer, and a second patterned metal layer are sequentially formed on a substrate. Then, a plurality of scan lines and a plurality of source lines are disposed on the substrate and define a plurality of pixel regions. A plurality of the storage capacitance lines are disposed on the substrate in a direction extending along the scan lines and across the pixel regions, wherein each of the storage capacitance lines is essentially perpendicular to each of the source lines and to form a cross portion. A plurality of patterned thin films are disposed on the storage capacitance lines and above the cross portion.

Abstract: The present invention relates to an interpolation method for enlarging an image, wherein the image is composed of plural scanning lines. Firstly, it selects four adjacent continuous pixels xk?1, xk, xk+1, and xk+2 which have the pixel values f(xk?1), f(xk), f(xk+1), and f(xk+2) respectively on each of the scanning lines; next, it determines three linear equations Lk?1, Lk, and Lk+1 according to every two adjacent pixel values f(xk?1) and f(xk), f(xk) and f(xk+1), and f(xk+1) and f(xk+2), respectively; then, it selects a pixel x to be interpolated between the pixel xk and the pixel xk+1; finally, it applies the pixel x to the three linear equations Lk?1, Lk, and Lk+1 to determine three candidate pixel values which are weighted and combined to obtain pixel value f(x) of the pixel x.

Abstract: An immunoassay cartridge for sensing at least one analyte in a biological sample is disclosed. The immunoassay cartridge comprises a supporting plate, a reaction cavity made within the supporting plate and having at least one analyte-binding molecule immobilized therein, a sample receiving end connected to the reaction cavity to allow the biological sample to flow into the reaction cavity for forming at least one complex of the analyte and the analyte-binding molecule, a first package containing a recognizing molecule, a first channel communicating the first package and the reaction cavity to allow the recognizing molecule to flow into the reaction cavity for forming a first product of the complex and the complex-binding molecule, a second package containing a buffer solution and a second channel communicating the second package and the reaction cavity to allow the buffer solution to flow into the reaction cavity.

Abstract: Novel microporous crystal morphologies are produced by combining a polar solute, a silicon or phosphorous source, and a structure directing agent. A premixed mixture of at least one surfactants and a hydrophobic solvent is added to the previously mixed three species and shaken to for a reverse microemulsion. The microemulsion is stirred overnight, at about room temperature and then iced for five to ten minutes. A metal source is added and vigorously shaken for about two minutes. The mixture is then aged for about two hours at about room temperature. After which, a mineralizer is added and the resultant mixture aged for about two hours at about room temperature. The mixture is then heated to about 100-220° C. The final novel product is then isolated.