Patent application number | Description | Published |
20090236644 | HIGH EFFICIENCY CMOS IMAGE SENSOR PIXEL EMPLOYING DYNAMIC VOLTAGE SUPPLY - A global shutter compatible pixel circuit comprising a reset gate (RG) transistor is provided in which a dynamic voltage is applied to the drain of the reset gate transistor in order to reduce a floating diffusion (FD) leakage therethrough during signal hold time. The drain voltage of the reset gate transistor is held at a lower voltage than a circuit supply voltage to minimize the off-state leakage through the RG transistor, thus reducing the change in the voltage at the floating diffusion during the signal hold time. In addition, a design structure for such a circuit providing a dynamic voltage to the drain of a reset gate of a pixel circuit is also provided. | 09-24-2009 |
20090276739 | IC CHIP AND DESIGN STRUCTURE INCLUDING STITCHED CIRCUITRY REGION BOUNDARY IDENTIFICATION - Stitched circuitry region boundary identification for a stitched IC chip layout is presented along with a related IC chip and design structure. One method includes obtaining a circuit design for an integrated circuit (IC) chip layout that exceeds a size of a photolithography tool field, wherein the IC chip layout includes a stitched circuitry region; and modifying the IC chip layout to include a boundary identification identifying a boundary of the stitched circuitry region at which stitching occurs, wherein the boundary identification takes the form of a negative space in the IC chip layout. One IC chip may include a plurality of stitched circuitry regions; and a boundary identification identifying a boundary between a pair of the stitched circuitry regions, wherein the boundary identification takes the form of a negative space in a layer of the IC chip. | 11-05-2009 |
20100097511 | HIGH EFFICIENCY CMOS IMAGE SENSOR PIXEL EMPLOYING DYNAMIC VOLTAGE SUPPLY - A global shutter compatible pixel circuit comprising a reset gate (RG) transistor is provided in which a dynamic voltage is applied to the drain of the reset gate transistor in order to reduce a floating diffusion (FD) leakage therethrough during signal hold time. The drain voltage of the reset gate transistor is held at a lower voltage than a circuit supply voltage to minimize the off-state leakage through the RG transistor, thus reducing the change in the voltage at the floating diffusion during the signal hold time. In addition, a design structure for such a circuit providing a dynamic voltage to the drain of a reset gate of a pixel circuit is also provided. | 04-22-2010 |
Patent application number | Description | Published |
20080203537 | Differential Junction Varactor - Structure and methods for a differential junction varactor. The structure includes: a silicon first region formed in a silicon substrate, the first region of a first dopant type; and a plurality of silicon second regions in physical and electrical contact with the first region, the plurality of second regions spaced apart and not in physical contact with each other, the plurality of second regions of a second dopant type, the first dopant type different from the second dopant type; a cathode terminal electrically connected to the first region; a first anode terminal electrically connected to a first set of second regions of the plurality of second regions; and a second anode terminal electrically connected to a second set of second silicon regions of the plurality of second regions, second regions of the first set of second regions alternating with second regions of the second set of second regions. | 08-28-2008 |
20080232025 | MIM CAPACITOR AND METHOD OF MAKING SAME - A MIM capacitor device and method of making the device. The device includes an upper plate comprising one or more electrically conductive layers, a dielectric block comprising one or more dielectric layers, a lower plate comprising one or more electrically conductive layer; and a spreader plate comprising one or more electrically conductive layers. | 09-25-2008 |
20080315274 | DEEP TRENCH CAPACITOR AND METHOD OF MAKING SAME - A trench capacitor and method of forming a trench capacitor. The trench capacitor including: a trench in a single-crystal silicon substrate, a conformal dielectric liner on the sidewalls and the bottom of the trench; an electrically conductive polysilicon inner plate filling regions of the trench not filled by the liner; an electrically conductive doped outer plate in the substrate surrounding the sidewalls and the bottom of the trench; a doped silicon region in the substrate; a first electrically conductive metal silicide layer on a surface region of the doped silicon region exposed at the top surface of the substrate; a second electrically conductive metal silicide layer on a surface region of the inner plate exposed at the top surface of the substrate; and an insulating ring on the top surface of the substrate between the first and second metal silicide layers. | 12-25-2008 |
20090004809 | Method of Integration of a MIM Capacitor with a Lower Plate of Metal Gate Material Formed on an STI Region or a Silicide Region Formed in or on the Surface of a Doped Well with a High K Dielectric Material - A MIM capacitor is formed on a semiconductor substrate having a top surface and including regions formed in the surface selected from a Shallow Trench Isolation (STI) region and a doped well having exterior surfaces coplanar with the semiconductor substrate. A capacitor lower plate is either a lower electrode formed on the STI region in the semiconductor substrate or a lower electrode formed by a doped well formed in the top surface of the semiconductor substrate that may have a silicide surface. A capacitor HiK dielectric layer is formed on or above the lower plate. A capacitor second plate is formed on the HiK dielectric layer above the capacitor lower plate. A dual capacitor structure with a top plate may be formed above the second plate with vias connected to the lower plate protected from the second plate by side wall spacers. | 01-01-2009 |
20090100388 | DEEP TRENCH CAPACITOR AND METHOD OF MAKING SAME - A trench capacitor, method of forming a trench capacitor and a design structure for a trench capacitor. The trench capacitor including: a trench in a single-crystal silicon substrate, a conformal dielectric liner on the sidewalls and the bottom of the trench; an electrically conductive polysilicon inner plate filling regions of the trench not filled by the liner; an electrically conductive doped outer plate in the substrate surrounding the sidewalls and the bottom of the trench; a doped silicon region in the substrate; a first electrically conductive metal silicide layer on a surface region of the doped silicon region exposed at the top surface of the substrate; a second electrically conductive metal silicide layer on a surface region of the inner plate exposed at the top surface of the substrate; and an insulating ring on the top surface of the substrate between the first and second metal silicide layers. | 04-16-2009 |
20090283840 | METAL GATE INTEGRATION STRUCTURE AND METHOD INCLUDING METAL FUSE, ANTI-FUSE AND/OR RESISTOR - A semiconductor structure and a method for fabricating the semiconductor structure provide a field effect device located and formed upon an active region of a semiconductor substrate and at least one of a fuse structure, an anti-fuse structure and a resistor structure located and formed at least in part simultaneously upon an isolation region laterally separated from the active region within the semiconductor substrate. The field effect device includes a gate dielectric comprising a high dielectric constant dielectric material and a gate electrode comprising a metal material. The at least one of the fuse structure, anti-fuse structure and resistor structure includes a pad dielectric comprising the same material as the gate dielectric, and optionally, also a fuse, anti-fuse or resistor that may comprise the same metal material as the gate electrode. | 11-19-2009 |