Abstract: A resistor is disclosed. The resistor is disposed on a substrate, in which the resistor includes: a dielectric layer disposed on the substrate; a polysilicon structure disposed on the dielectric layer; two primary resistance structures disposed on the dielectric layer and at two ends of the polysilicon structure; and a plurality of secondary resistance structures disposed on the dielectric layer and interlaced with the polysilicon structures.

Abstract: A semiconductor structure includes a first capacitor and a second capacitor. The first capacitor includes a plurality of first units and each first unit includes a plurality of first finger electrodes. The second capacitor includes a plurality of second units and each second unit includes a plurality of second finger electrodes. The first units and the second units are alternately arranged to form an array. The semiconductor structure further includes a plurality of first connecting lines and a plurality of second connecting lines being parallel with each other. The first connecting lines are electrically connected to the first finger electrodes, and the second connecting lines are electrically connected to the second finger electrodes. The first finger electrodes and its adjacent first connecting lines form a straight line, and the second finger electrodes and its adjacent second connecting lines form another straight line.

Abstract: A MOS capacitor includes a substrate, a p-type MOS (pMOS) transistor positioned on the substrate, and an n-type MOS (nMOS) transistor positioned on the substrate. More important, the pMOS transistor and the nMOS transistor are electrically connected in parallel. The MOS transistor further includes a deep n-well that encompassing the pMOS transistor and the nMOS transistor.

Abstract: A semiconductor structure includes a first capacitor and a second capacitor. The first capacitor includes a plurality of first units and each first unit includes a plurality of first finger electrodes. The second capacitor includes a plurality of second units and each second unit includes a plurality of second finger electrodes. The first units and the second units are alternately arranged to form an array. The semiconductor structure further includes a plurality of first connecting lines and a plurality of second connecting lines being parallel with each other. The first connecting lines are electrically connected to the first finger electrodes, and the second connecting lines are electrically connected to the second finger electrodes. The first finger electrodes and its adjacent first connecting lines form a straight line, and the second finger electrodes and its adjacent second connecting lines form another straight line.

Abstract: A sequential solid phase immunoassay and system is disclosed. The immunoassay utilizes the secondary antibody method for the detection of antibodies in a membrane-based test. The system comprises a test strip including a nitrocellulose membrane having an immobilized antigen in a capture zone on the membrane and a stabilized liquid secondary antibody conjugate. The sequential solid phase immunoassay is performed in a sequential manner with the addition of a fluid specimen being followed by the addition of the stabilized liquid secondary antibody conjugate. The sequential procedure using the system includes allowing the fluid specimen containing antibodies specific to the antigen to pass laterally from the test strip first end through the capture zone. The immobilized antigens in the capture zone capture antibodies specific to the antigen. The stabilized liquid secondary antibody conjugate then binds to the captured antibodies and can be detected visually or by a machine or reader.

Abstract: A capacitor structure includes a plurality of conductive line levels located over the substrate. Each of the conductive line levels includes a first conductive line and a second conductive line. The first conductive lines in the conductive line levels form a first conductive line co-plane and the second conductive lines in the conductive line levels form a second conductive line co-plane. A first conductive end is electrically connected to the first conductive lines on the conductive line levels. A second conductive end is electrically connected to the second conductive lines on the conductive line levels. A plurality of vias are located between the neighboring conductive line levels and placed on only one of the first and second conductive line co-planes on a same level.

Abstract: A capacitor structure includes a plurality of conductive line levels located over the substrate. Each of the conductive line levels includes a first conductive line and a second conductive line. The first conductive lines in the conductive line levels form a first conductive line co-plane and the second conductive lines in the conductive line levels form a second conductive line co-plane. A first conductive end is electrically connected to the first conductive lines on the conductive line levels. A second conductive end is electrically connected to the second conductive lines on the conductive line levels. A plurality of vias are located between the neighboring conductive line levels and placed on only one of the first and second conductive line co-planes on a same level.

Abstract: A capacitor structure is provided. The capacitor structure comprises a plurality of parallel conductive line levels and a plurality of vias. Each conductive line level comprises first conductive lines parallel to each other and second conductive lines parallel to each other. Also, the first conductive lines on different conductive line levels are aligned to each other and the second conductive lines on different conductive line levels are aligned to each other so as to form first conductive line co-planes and second conductive line co-planes. The vias are located on the conductive line co-planes and between the conductive line levels for connecting the conductive lines on the neighboring conductive line levels. The vias, on a height level of each of the conductive line co-planes, are arranged only on one of the neighboring conductive line co-planes.

Abstract: A resistor is disclosed. The resistor is disposed on a substrate, in which the resistor includes: a dielectric layer disposed on the substrate; a polysilicon structure disposed on the dielectric layer; two primary resistance structures disposed on the dielectric layer and at two ends of the polysilicon structure; and a plurality of secondary resistance structures disposed on the dielectric layer and interlaced with the polysilicon structures.

Abstract: A semiconductor device structure including a substrate, a resistor, and a first gate structure is provided. The substrate includes a resistor region and a metal-oxide-semiconductor (MOS) transistor region. The resistor is disposed on the substrate within the resistor region. The resistor includes a first dielectric layer, a metal layer, a second dielectric layer, and a semiconductor layer sequentially stacked on the substrate. The first gate structure is disposed on the substrate within the MOS transistor region. The first gate structure includes the first dielectric layer, the metal layer, and the semiconductor layer sequentially stacked on the substrate.

Abstract: A capacitor structure is provided. The capacitor structure comprises a plurality of parallel conductive line levels and a plurality of vias. Each conductive line level comprises first conductive lines parallel to each other and second conductive lines parallel to each other. Also, the first conductive lines on different conductive line levels are aligned to each other and the second conductive lines on different conductive line levels are aligned to each other so as to form first conductive line co-planes and second conductive line co-planes. The vias are located on the conductive line co-planes and between the conductive line levels for connecting the conductive lines on the neighboring conductive line levels. The vias, on a height level of each of the conductive line co-planes, are arranged only on one of the neighboring conductive line co-planes.

Abstract: A method for forming a thin film resistor includes providing a substrate having a transistor region and a thin film resistor region defined thereon, sequentially forming a dielectric layer, a metal layer and a first hard mask layer on the substrate, patterning the first hard mask layer to form at least a thin film resistor pattern in the thin film resistor region, sequentially forming a polysilicon layer and a second hard mask layer on the substrate, patterning the second hard mask layer to form at least a gate pattern in the transistor region, and performing an etching process to form a gate and a thin film resistor respectively in the transistor region and the thin film resistor region.

Abstract: A semiconductor device structure including a substrate, a resistor, and a first gate structure is provided. The substrate includes a resistor region and a metal-oxide-semiconductor (MOS) transistor region. The resistor is disposed on the substrate within the resistor region. The resistor includes a first dielectric layer, a metal layer, a second dielectric layer, and a semiconductor layer sequentially stacked on the substrate. The first gate structure is disposed on the substrate within the MOS transistor region. The first gate structure includes the first dielectric layer, the metal layer, and the semiconductor layer sequentially stacked on the substrate.

Abstract: A semiconductor device structure including a substrate, a resistor, and a first gate structure is provided. The substrate includes a resistor region and a metal-oxide-semiconductor (MOS) transistor region. The resistor is disposed on the substrate within the resistor region. The resistor includes a first dielectric layer, a metal layer, a second dielectric layer, and a semiconductor layer sequentially stacked on the substrate. The first gate structure is disposed on the substrate within the MOS transistor region. The first gate structure includes the first dielectric layer, the metal layer, and the semiconductor layer sequentially stacked on the substrate.

Abstract: A sequential solid phase immunoassay and system is disclosed. The immunoassay utilizes the secondary antibody method for the detection of antibodies in a membrane-based test. The system comprises a test strip including a nitrocellulose membrane having an immobilized antigen in a capture zone on the membrane and a stabilized liquid secondary antibody conjugate. The sequential solid phase immunoassay is performed in a sequential manner with the addition of a fluid specimen being followed by the addition of the stabilized liquid secondary antibody conjugate. The sequential procedure using the system includes allowing the fluid specimen containing antibodies specific to the antigen to pass laterally from the test strip first end through the capture zone. The immobilized antigens in the capture zone capture antibodies specific to the antigen. The stabilized liquid secondary antibody conjugate then binds to the captured antibodies and can be detected visually or by a machine or reader.

Abstract: A method for forming a thin film resistor includes providing a substrate having a transistor region and a thin film resistor region defined thereon, sequentially forming a dielectric layer, a metal layer and a first hard mask layer on the substrate, patterning the first hard mask layer to form at least a thin film resistor pattern in the thin film resistor region, sequentially forming a polysilicon layer and a second hard mask layer on the substrate, patterning the second hard mask layer to form at least a gate pattern in the transistor region, and performing an etching process to form a gate and a thin film resistor respectively in the transistor region and the thin film resistor region.