| Patent application number | Description | Published |
|---|
| 20080265333 | STRUCTURE AND METHOD FOR ENHANCED TRIPLE WELL LATCHUP ROBUSTNESS - Disclosed is a triple well CMOS device structure that addresses the issue of latchup by adding an n+ buried layer not only beneath the p-well to isolate the p-well from the p-substrate but also beneath the n-well. The structure eliminates the spacing issues between the n-well and n+ buried layer by extending the n+ buried layer below the entire device. The structure also addresses the issue of threshold voltage scattering by providing a p+ buried layer below the entire device under the n+ buried layer or below the p-well side of the device only either under or above the n+ buried layer) Latchup robustness can further be improved by incorporating into the device an isolation structure that eliminates lateral pnp, npn, or pnpn devices and/or a sub-collector region between the n+ buried layer and the n-well. | 10-30-2008 |
| 20090020856 | SEMICONDUCTOR DEVICE STRUCTURES AND METHODS FOR SHIELDING A BOND PAD FROM ELECTRICAL NOISE - Semiconductor device structures and methods for shielding a bond pad from electrical noise generated by active circuitry of an integrated circuit carried on a substrate. The structure includes electrically characterized devices placed in a pre-determined arrangement under the bond pad. The pre-determined arrangement of the electrically characterized devices provides for a consistent high frequency environment under the bond pad, which simplifies modeling of the bond pad by a circuit designer. | 01-22-2009 |
| 20090106713 | DESIGN STRUCTURE INCORPORATING SEMICONDUCTOR DEVICE STRUCTURES THAT SHIELD A BOND PAD FROM ELECTRICAL NOISE - Design structure embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes active circuitry on a substrate, a bond pad carried by the substrate, and a shielding structure disposed between the substrate and the bond pad. The shielding structure includes a plurality of electrically characterized devices configured to reduce noise transmission from the active circuitry to the bond pad. | 04-23-2009 |
| 20090152592 | STRUCTURE FOR A LATCHUP ROBUST ARRAY I/O USING THROUGH WAFER VIA - A design structure including: an I/O cell and an ESD protection circuit in a region of an integrated circuit chip containing logic circuits; an electrically conductive through via extending from a bottom surface of the substrate toward a top surface of the substrate between the I/O cell and an ESD protection circuit and at least one of the logic circuits. | 06-18-2009 |
| 20090152593 | STRUCTURE FOR A LATCHUP ROBUST GATE ARRAY USING THROUGH WAFER VIA - A structure, method and a design structure for preventing latchup in a gate array. The design structure including: a NFET gate array and a PFET gate array in a substrate; an electrically conductive through via extending from a bottom surface of the substrate toward a top surface of the substrate the NFET gate array and PFET gate array, the through via electrically contacting the P-well. | 06-18-2009 |
| 20090152632 | LATCHUP ROBUST ARRAY I/O USING THROUGH WAFER VIA - A structure and a method for preventing latchup. The structure including: an I/O cell and an ESD protection circuit in a region of an integrated circuit chip containing logic circuits; an electrically conductive through via extending from a bottom surface of the substrate toward a top surface of the substrate between the I/O cell and an ESD protection circuit and at least one of the logic circuits. | 06-18-2009 |
| 20090166798 | DESIGN METHODOLOGY FOR GUARD RING DESIGN RESISTANCE OPTIMIZATION FOR LATCHUP PREVENTION - A design structure is disclosed for a circuit optimizing guard ring design by optimizing the path resistance value between the components of the parasitic lateral bipolar transistors in a CMOS circuit and the power supply or ground. By comparing the calculated path resistance value to a maximum resistance number derived from specifications, elements that need further redesign are identified. Repeated redesign with several redesign options eventually lead to an optimized guard ring structure that provides area-efficient and sufficient latchup protection for the CMOS circuit. A design structure employing such an optimized guard ring is also provided. | 07-02-2009 |
| 20100032767 | STRUCTURE AND METHOD OF LATCHUP ROBUSTNESS WITH PLACEMENT OF THROUGH WAFER VIA WITHIN CMOS CIRCUITRY - A method of manufacturing a semiconductor structure includes: forming a trench in a back side of a substrate; depositing a dopant on surfaces of the trench; forming a shallow trench isolation (STI) structure in a top side of the substrate opposite the trench; forming a deep well in the substrate; out-diffusing the dopant into the deep well and the substrate; forming an N-well and a P-well in the substrate; and filling the trench with a conductive material. | 02-11-2010 |
| 20100032809 | METAL WIRING STRUCTURE FOR INTEGRATION WITH THROUGH SUBSTRATE VIAS - An array of through substrate vias (TSVs) is formed through a semiconductor substrate and a contact-via-level dielectric layer thereupon. A metal-wire-level dielectric layer and a line-level metal wiring structure embedded therein are formed directly on the contact-via-level dielectric layer. The line-level metal wiring structure includes cheesing holes that are filled with isolated portions of the metal-wire-level dielectric layer. In one embodiment, the entirety of the cheesing holes is located outside the area of the array of the TSVs to maximize the contact area between the TSVs and the line-level metal wiring structure. In another embodiment, a set of cheesing holes overlying an entirety of seams in the array of TSVs is formed to prevent trapping of any plating solution in the seams of the TSVs during plating to prevent corrosion of the TSVs at the seams. | 02-11-2010 |
| 20100038750 | Structure, Design Structure and Method of Manufacturing a Structure Having VIAS and High Density Capacitors - A semiconductor structure and design structure includes at least a first trench and a second trench having different depths arranged in a substrate, a capacitor arranged in the first trench, and a via arranged in the second trench. | 02-18-2010 |
| 20100041203 | Structure, Design Structure and Method of Manufacturing a Structure Having VIAS and High Density Capacitors - A method of making a semiconductor structure includes forming at least a first trench and a second trench having different depths in a substrate, forming a capacitor in the first trench, and forming a via in the second trench. A semiconductor structure includes a capacitor arranged in a first trench formed in a substrate and a via arranged in a second trench formed in the substrate. The first and second trenches have different depths in the substrate. | 02-18-2010 |
| 20100117122 | Optimized Device Isolation - A structure for a semiconductor device includes an isolated MOSFET (e.g., NFET) having triple-well technology adjacent to an isolated PFET which itself is adjacent to an isolated NFET. The structure includes a substrate in which is formed a deep n-band region underneath any n-wells, p-wells and p-band regions within the substrate. One p-band region is formed above the deep n-band region and underneath the isolated p-well for the isolated MOSFET, while another p-band region is formed above the deep n-band region and underneath all of the p-wells and n-wells, including those that are part of the isolated PFET and NFET devices within the substrate. The n-wells for the isolated MOSFET are connected to the deep n-band region. The resulting structure provides for improved device isolation and reduction of noise propagating from the substrate to the FETs while maintaining the standard CMOS spacing layout spacing rules and electrical biasing characteristics both external and internal to the triple-well isolation regions. | 05-13-2010 |
| 20100155897 | DEEP TRENCH VARACTORS - A deep trench varactor structure compatible with a deep trench capacitor structure and methods of manufacturing the same are provided. A buried plate layer is formed on a second deep trench, while the first trench is protected from formation of any buried plate layer. The inside of the deep trenches is filled with a conductive material to form inner electrodes. At least one doped well is formed outside and abutting portions of the first deep trench and constitutes at least one outer varactor electrode. Multiple doped wells may be connected in parallel to provide a varactor having complex voltage dependency of capacitance. The buried plate layer and another doped well connected thereto constitute an outer electrode of a linear capacitor formed on the second deep trench. | 06-24-2010 |
| 20100207173 | ASYMMETRIC JUNCTION FIELD EFFECT TRANSISTOR - A junction field effect transistor (JFET) in a semiconductor substrate includes a source region, a drain region, a channel region, an upper gate region, and a lower gate region. The lower gate region is electrically connected to the upper gate region. The upper and lower gate regions control the current flow through the channel region. By performing an ion implantation step that extends the thickness of the source region to a depth greater than the thickness of the drain region, an asymmetric JFET is formed. The extension of depth of the source region relative to the depth of the drain region reduces the length for minority charge carriers to travel through the channel region, reduces the on-resistance of the JFET, and increases the on-current of the JFET, thereby enhancing the overall performance of the JFET without decreasing the allowable Vds or dramatically increasing Voff/Vpinch. | 08-19-2010 |
| 20100230752 | SOI (SILICON ON INSULATOR) SUBSTRATE IMPROVEMENTS - A structure, and a method for forming the same. The structure includes a semiconductor substrate which includes a top substrate surface, a buried dielectric layer on the top substrate surface, N active semiconductor regions on the buried dielectric layer, N active devices on the N active semiconductor regions, a plurality of dummy regions on the buried dielectric layer, a protection layer on the N active devices and the N active semiconductor regions, but not on the plurality of dummy regions. The N active devices comprise first active regions which comprise a first material. The plurality of dummy regions comprise first dummy regions which comprise the first material. A first pattern density of the first active regions and the first dummy regions is uniform across the structure. A trench in the buried dielectric layer such that side walls of the trench are aligned with the plurality of dummy regions. | 09-16-2010 |
| 20100264545 | Metal Fill Structures for Reducing Parasitic Capacitance - Vertically-staggered-level metal fill structures include inner contiguous metal fill structures and outer contiguous metal fill structures. A dielectric material portion is provided between each contiguous metal fill structure. Vertical extent of each contiguous metal fill structure is limited up to three vertically adjoining metal interconnect levels, thereby limiting the capacitance of each contiguous metal fill structure. Capacitive coupling between the contiguous metal fill structures and the metal interconnect structures is minimized due to the fragmented structure of contiguous metal fill structures. | 10-21-2010 |
| 20100279483 | LATERAL PASSIVE DEVICE HAVING DUAL ANNULAR ELECTRODES - A lateral passive device is disclosed including a dual annular electrode. The annular electrodes form an anode and a cathode. The annular electrodes allow anode and cathode series resistances to be optimized to the lowest values at a fixed device area. In addition, the parasitic capacitance to a bottom plate (substrate) is greatly reduced. In one embodiment, a device includes a first annular electrode surrounding a second annular electrode formed on a substrate, and the second annular electrode surrounds an insulator region. A related method is also disclosed. | 11-04-2010 |
| 20110147808 | ASYMMETRIC JUNCTION FIELD EFFECT TRANSISTOR - A junction field effect transistor (JFET) in a semiconductor substrate includes a source region, a drain region, a channel region, an upper gate region, and a lower gate region. The lower gate region is electrically connected to the upper gate region. The upper and lower gate regions control the current flow through the channel region. By performing an ion implantation step that extends the thickness of the source region to a depth greater than the thickness of the drain region, an asymmetric JFET is formed. The extension of depth of the source region relative to the depth of the drain region reduces the length for minority charge carriers to travel through the channel region, reduces the on-resistance of the JFET, and increases the on-current of the JFET, thereby enhancing the overall performance of the JFET without decreasing the allowable Vds or dramatically increasing Voff/Vpinch. | 06-23-2011 |
