Patent application number | Description | Published |
20080225611 | METHOD AND APPARATUS FOR IMPROVING SRAM CELL STABILTY BY USING BOOSTED WORD LINES - The present invention relates to methods and apparatus for improving the stability of static random access memory (SRAM) cells by using boosted word lines. Specifically, a boosted word line voltage (Vdd′) is applied to the word line of a selected SRAM cell, while such a boosted word line voltage (Vdd′) is sufficiently higher than the power supply voltage (Vdd) of the SRAM cell so as to improve the cell stability to a desired level. Specifically, a specific boosted word line voltage is predetermined for each SRAM cell based on the specific cell configuration, by using a circuit simulation program, such as the BERKELEY-SPICE simulation program. A boost voltage generator is then used to apply the predetermined boosted word line voltage to the selected SRAM cell. | 09-18-2008 |
20080303139 | CHIP-IN-SLOT INTERCONNECT FOR 3D CHIP STACKS - A chip-in-slot interconnect for three-dimensional semiconductor chip stacks, and particularly having the ability of forming edge connections on semiconductor chips, wherein the semiconductor chips are mounted in one or more chip carriers which are capable of being equipped with embedded circuitry. Moreover, provision is made for unique methods for producing the edge connections on the semiconductor chips, for creating a semiconductor chip carrier, and for producing a novel semiconductor and combined chip carrier structure. | 12-11-2008 |
20090144670 | AUTOMATED OPTIMIZATION OF DEVICE STRUCTURE DURING CIRCUIT DESIGN STAGE - A method of improving a circuit design for a very large scale integrated circuit is provided which represents a plurality of semiconductor devices interconnected in a circuit. It is determined whether an edge of a feature of one of the plurality of semiconductor devices in the design can be moved in a first direction by a distance within a permitted range, such that a performance goal and a matching goal for the circuit are served. If so, the edge is moved in the first direction by the distance calculated to best serve the performance goal and the matching goal. The foregoing steps may be repeated for each of the plurality of semiconductor devices. If necessary, the foregoing steps may be repeated until the performance goal and matching goal for the circuit are deemed to be adequately served. | 06-04-2009 |
20090179193 | CARBON NANOTUBE BASED INTEGRATED SEMICONDUCTOR CIRCUIT - Gate electrodes are formed on a semiconducting carbon nanotube, followed by deposition and patterning of a hole-inducing material layer and an electron inducing material layer on the carbon nanotube according to the pattern of a one dimensional circuit layout. Electrical isolation may be provided by cutting a portion of the carbon nanotube, forming a reverse biased junction of a hole-induced region and an electron-induced region of the carbon nanotube, or electrically biasing a region through a dielectric layer between two device regions of the carbon nanotube. The carbon nanotubes may be arranged such that hole-inducing material layer and electron-inducing material layer may be assigned to each carbon nanotube to form periodic structures such as a static random access memory (SRAM) array. | 07-16-2009 |
20100050138 | SYSTEM AND METHODOLOGY FOR DETERMINING LAYOUT-DEPENDENT EFFECTS IN ULSI SIMULATION - A layout of a semiconductor circuit is analyzed to calculate layout-dependant parameters that can include a mobility shift and a threshold voltage shift. Layout-dependant effects that affect the layout dependant parameters may include stress effects, rapid thermal anneal (RTA) effects, and lithographic effects. Intrinsic functions that do not reflect the layout-dependant effects are calculated, followed by calculation of scaling modifiers based on the layout-dependant parameters. A model output function that reflects the layout-dependant effects is obtained by multiplication of each of the intrinsic functions with a corresponding scaling parameter. | 02-25-2010 |
20100117130 | HIGH PERFORMANCE CAPACITORS IN PLANAR BACK GATES CMOS - A method of manufacture and device for a dual-gate CMOS structure. The structure includes a first plate in an insulating layer and a second plate above the insulating layer electrically corresponding to the first plate. An isolation structure is between the first plate and the second plate. | 05-13-2010 |
20100295025 | CARBON NANOTUBE BASED INTEGRATED SEMICONDUCTOR CIRCUIT - Gate electrodes are formed on a semiconducting carbon nanotube, followed by deposition and patterning of a hole-inducing material layer and an electron inducing material layer on the carbon nanotube according to the pattern of a one dimensional circuit layout. Electrical isolation may be provided by cutting a portion of the carbon nanotube, forming a reverse biased junction of a hole-induced region and an electron-induced region of the carbon nanotube, or electrically biasing a region through a dielectric layer between two device regions of the carbon nanotube. The carbon nanotubes may be arranged such that hole-inducing material layer and electron-inducing material layer may be assigned to each carbon nanotube to form periodic structures such as a static random access memory (SRAM) array. | 11-25-2010 |
20110115054 | SEMISPHERICAL INTEGRATED CIRCUIT STRUCTURES - A diode comprises a substrate formed of a first material having a first doping polarity. The substrate has a planar surface and at least one semispherical structure extending from the planar surface. The semispherical structure is formed of the first material. A layer of second material is over the semispherical structure. The second material comprises a second doping polarity opposite the first doping polarity. The layer of second material conforms to the shape of the semispherical structure. A first electrical contact is connected to the substrate, and a second electrical contact is connected to the layer of second material. Additional semiconductor structures are formed by fabricating additional layers over the original layers. | 05-19-2011 |
20110263101 | CARBON NANOTUBE BASED INTEGRATED SEMICONDUCTOR CIRCUIT - Gate electrodes are formed on a semiconducting carbon nanotube, followed by deposition and patterning of a hole-inducing material layer and an electron inducing material layer on the carbon nanotube according to the pattern of a one dimensional circuit layout. Electrical isolation may be provided by cutting a portion of the carbon nanotube, forming a reverse biased junction of a hole-induced region and an electron-induced region of the carbon nanotube, or electrically biasing a region through a dielectric layer between two device regions of the carbon nanotube. The carbon nanotubes may be arranged such that hole-inducing material layer and electron-inducing material layer may be assigned to each carbon nanotube to form periodic structures such as a static random access memory (SRAM) array. | 10-27-2011 |
20120018806 | SEMICONDUCTOR-ON-INSULATOR (SOI) STRUCTURE WITH SELECTIVELY PLACED SUB-INSULATOR LAYER VOID(S) AND METHOD OF FORMING THE SOI STRUCTURE - Disclosed is a semiconductor-on-insulator (SOI) structure having sub-insulator layer void(s) selectively placed in a substrate so that capacitance coupling between a first section of a semiconductor layer and the substrate will be less than capacitance coupling between a second section of the semiconductor layer and the substrate. The first section may contain a first device on an insulator layer and the second section may contain a second device on the insulator layer. Alternatively, the first and second sections may comprise different regions of the same device on an insulator layer. For example, in an SOI field effect transistor (FET), sub-insulator layer voids can be selectively placed in the substrate below the source, drain and/or body contact diffusion regions, but not below the channel region so that capacitance coupling between the these various diffusion regions and the substrate will be less than capacitance coupling between the channel region and the substrate. Also, disclosed is an associated method of forming such an SOI structure. | 01-26-2012 |
20120185812 | SYSTEM, METHOD AND PROGRAM STORAGE DEVICE FOR DEVELOPING CONDENSED NETLISTS REPRESENTATIVE OF GROUPS OF ACTIVE DEVICES IN AN INTEGRATED CIRCUIT AND FOR MODELING THE PERFORMANCE OF THE INTEGRATED CIRCUIT BASED ON THE CONDENSED NETLISTS - A system and method for developing condensed netlists for sub-circuits within an integrated circuit and for modeling the performance of the integrated circuit based on the condensed netlists rather than full netlists. An IC layout is segmented into a plurality of sub-circuits, each comprising a group of one or more of a given type of active devices connected to (i.e., sharing) the same electrical sub-circuit terminals through a similar resistive network (i.e. such that they are subjected to approximately the same overall combined parasitic resistances). Full netlists corresponding to the sub-circuits are extracted from the layout and condensed. Each condensed netlist accounts for performance variations (e.g., as a function of variations in operating power supply voltages, operating temperatures and, optionally, self-heating and/or stress) exhibited by the active devices and resistive network in a sub-circuit. The condensed netlists for the sub-circuits are then simulated over the full range of operating temperatures and full range of operating power supply voltages for the integrated circuit in order to generate a performance model for the integrated circuit. | 07-19-2012 |
20120210283 | ANALYSIS OF COMPENSATED LAYOUT SHAPES - The disclosure relates to the analysis of compensated layout shapes. A method in accordance with an embodiment includes: analyzing a semiconductor layout using a bucket structure, the layout including a semiconductor device; and applying a pattern template to a content of the bucket structure to identify a shape adjacent to the semiconductor device; wherein the pattern template is derived from layout groundrules. | 08-16-2012 |
20120235233 | FIELD EFFECT TRANSISTOR STRUCTURE AND METHOD OF FORMING SAME - The disclosure relates generally to a metal-oxide-semiconductor field effect transistor (MOSFET) structures and methods of forming the same. The MOSFET structure includes at least one semiconductor body on a substrate; a dielectric cap on a top surface of the at least one semiconductor body, wherein a width of the at least one semiconductor body is less than a width of the dielectric cap; a gate dielectric layer conformally coating the at least one semiconductor body; and at least one electrically conductive gate on the gate dielectric layer. | 09-20-2012 |
20130087841 | PLATED STRUCTURES - A method and structure is directed to eDRAM cells with high-conductance electrodes. The method includes forming upper layers on a semiconductor substrate and forming an opening in the upper layers. The method further includes forming a trench in the semiconductor substrate, aligned with the opening. The method further includes forming a metal plate on all exposed surface in the trench by applying a metallic aqueous solution with an electrical bias to a backside of the semiconductor substrate | 04-11-2013 |
20140021548 | SEMICONDUCTOR-ON-INSULATOR (SOI) STRUCTURE WITH SELECTIVELY PLACED SUB-INSULATOR LAYER VOID(S) AND METHOD OF FORMING THE SOI STRUCTURE - Disclosed is a semiconductor-on-insulator (SOI) structure (e.g., an SOI field effect transistor (FET)) and method of forming the SOI structure so as to have sub-insulator layer void(s) selectively placed so that capacitance coupling between a first section of a semiconductor layer and the substrate will be less than capacitance coupling between a second section of the semiconductor layer and the substrate. The first section may contain a first device and the second section may contain a second device. Alternatively, the first and second sections may comprise different regions of the same device. For example, in an SOI FET, sub-insulator layer voids can be selectively placed in the substrate below the source, drain and/or body contact diffusion regions, but not below the channel region so that capacitance coupling between the these various diffusion regions and the substrate will be less than capacitance coupling between the channel region and the substrate. | 01-23-2014 |
20140151850 | PLATED STRUCTURES - A method and structure is directed to eDRAM cells with high-conductance electrodes. The method includes forming upper layers on a semiconductor substrate and forming an opening in the upper layers. The method further includes forming a trench in the semiconductor substrate, aligned with the opening. The method further includes forming a metal plate on all exposed surface in the trench by applying a metallic aqueous solution with an electrical bias to a backside of the semiconductor substrate. | 06-05-2014 |
20140201699 | METHODS FOR MODELING OF FINFET WIDTH QUANTIZATION - A method for modeling FinFET width quantization is described. The method includes fitting a FinFET model of a FinFET device to single fin current/voltage characteristics. The FinFET device comprises a plurality of fins. The method includes obtaining statistical data of at least one sample FinFET device. The statistical data includes DIBL data and SS data. The method also includes fitting the FinFET model to a variation in a current to turn off the finFETs device (I | 07-17-2014 |
20140201700 | APPARATUS FOR MODELING OF FINFET WIDTH QUANTIZATION - A method for modeling FinFET width quantization is described. The method includes fitting a FinFET model of a FinFET device to single fin current/voltage characteristics. The FinFET device comprises a plurality of fins. The method includes obtaining statistical data of at least one sample FinFET device. The statistical data includes DIBL data and SS data. The method also includes fitting the FinFET model to a variation in a current to turn off the finFETs device (I | 07-17-2014 |
20140310676 | METHODS FOR MODELING OF FINFET WIDTH QUANTIZATION - A method for modeling FinFET width quantization is described. The method includes fitting a FinFET model of a FinFET device to single fin current/voltage characteristics. The FinFET device comprises a plurality of fins The method includes obtaining statistical data of at least one sample FinFET device. The statistical data includes DIBL data and SS data. The method also includes fitting the FinFET model to a variation in a current to turn off the finFETs device (I | 10-16-2014 |
20140353755 | FIELD EFFECT TRANSISTOR STRUCTURE AND METHOD OF FORMING SAME - The disclosure relates generally to a metal-oxide-semiconductor field effect transistor (MOSFET) structures and methods of forming the same. The MOSFET structure includes at least one semiconductor body on a substrate; a dielectric cap on a top surface of the at least one semiconductor body, wherein a width of the at least one semiconductor body is less than a width of the dielectric cap; a gate dielectric layer conformally coating the at least one semiconductor body; and at least one electrically conductive gate on the gate dielectric layer. | 12-04-2014 |