Abstract: A method is disclosed for measuring alignment of polysilicon shapes relative to a silicon area wherein the presence of an electrical coupling is used to determine the presence of bias or misalignment. Bridging vertices on the polysilicon shapes are formed. Bridging vertices over the silicon area create low resistance connections between those bridging vertices and the silicon area; other bridging vertices over ROX (recessed oxide) areas do not create low resistance connections between those other bridging vertices and the silicon area. Determining which bridging vertices have low resistance connections to the silicon area and how many bridging vertices have low resistance connections to the silicon area are used to determine the bias and misalignment of the polysilicon shapes relative to the silicon area.

Abstract: A method and apparatus implement adaptive power supply (APS) system voltage level activation eliminating the use of electronic Fuses (eFuses). A primary chip includes an adaptive power supply (APS). A secondary chip circuit includes at least one pair of hard-wired APS setting connections. Each hard-wired APS setting connection is defined by a selected one of a voltage supply connection and a ground potential connection. A respective inverter couples a control signal from each of the hard-wired APS setting connections to a power communication bus connected to the APS on the primary chip.

Abstract: A method and apparatus implement adaptive power supply (APS) system voltage level activation eliminating the use of electronic Fuses (eFuses), and a design structure on which the subject circuit resides are provided. A primary chip includes an adaptive power supply (APS). A secondary chip circuit includes at least one pair of hard-wired APS setting connections. Each hard-wired APS setting connection is defined by a selected one of a voltage supply connection and a ground potential connection. A respective inverter couples a control signal from each of the hard-wired APS setting connections to a power communication bus connected to the APS on the primary chip.

Abstract: Embodiments of the invention provide a relatively uniform width fin in a Fin Field Effect Transistors (FinFETs) and apparatus and methods for forming the same. A fin structure may be formed such that the surface of a sidewall portion of the fin structure is normal to a first crystallographic direction. Tapered regions at the end of the fin structure may be normal to a second crystal direction. A crystallographic dependent etch may be performed on the fin structure. The crystallographic dependent etch may remove material from portions of the fin normal to the second crystal direction relatively faster, thereby resulting in a relatively uniform width fin structure.

Abstract: Methods and apparatus are provided for implementing silicon wafer chip carrier passive devices including customized silicon capacitors and resistors mounted directly on a module or carrier package. A plurality of system design inputs is received for a package arrangement. A respective physical design is generated for customized passive devices, a logic chip, and a chip carrier. Silicon devices are fabricated utilizing the generated respective physical design for customized passive devices and the logic chip and a carrier package is fabricated. The fabricated silicon devices are assembled on the carrier package.

Abstract: Circuitry and methods are disclosed for quantitatively characterizing the delay of Embedded Dynamic Random Access Memory (EDRAM) and Dynamic Random Access Memory (DRAM). The performance critical portion of the memory is placed in a ring oscillator designed such that the delay through the portion, from a rising input to the memory to a rising output, can be accurately determined. Recently, such memory elements have begun to be implemented on chips along with high-speed logic circuitry. However, the performance characteristics of the memory elements do not track the performance characteristics of the logic circuitry. The current invention allows the memory performance to be characterized along with, or separately from, characterization of the logic circuitry.

Abstract: A method and apparatus for reducing parasitic bipolar transistor leakage current in a Silicon on Insulator (SOI) Metal Oxide Semiconductor (MOS). A capacitor is operatively coupled between the base and emitter terminals of the parasitic bipolar transistor. The capacitor effectively reduces the base to emitter voltage of the parasitic transistor thereby reducing leakage current generated at the collector terminal.

Abstract: Methods and silicon-on-insulator (SOI) semiconductor structures are provided for implementing transistor source connections for SOI transistor devices using buried dual rail distribution. A SOI semiconductor structure includes a SOI transistor having a silicide layer covering a SOI transistor source, a predefined buried conduction layer to be connected to a SOI transistor source, and an intermediate conduction layer between the SOI transistor and the predefined buried conduction layer. A first hole for a transistor source connection to a local interconnect is anisotropically etched in the SOI semiconductor structure to the silicide layer covering the SOI transistor source. A second hole aligned with the local interconnect hole is anisotropically etched through the SOI semiconductor structure to the predefined buried conduction layer. An insulator is disposed between the second hole and the intermediate conduction layer.

Abstract: Methods and semiconductor structures are provided for implementing buried dual rail power distribution and integrated decoupling capacitance for silicon on insulator (SOI) devices. A bulk silicon substrate layer is provided that defines one power distribution rail. A high energy deep oxygen implant is performed to create a deep buried oxide layer and a first intermediate silicon layer. The deep buried oxide layer is disposed between the bulk silicon substrate layer and the first intermediate silicon layer. The first intermediate silicon layer defines another power distribution rail. A lower energy oxygen implant is performed to create a shallow buried oxide layer and a second intermediate silicon layer The shallow buried oxide layer is disposed between the first intermediate silicon layer and the second intermediate silicon layer. A connection to the bulk silicon substrate layer is formed without making electrical connection to the intermediate silicon layers.

Abstract: An SRAM memory cell made with increased stability using SOI technology is provided. Increased stability occurs because of raising the threshold voltage of the transfer nfets connected to the word line. Preferably the increase of threshold voltage is achieved using boron ion implantation.

Abstract: Methods and apparatus are provided for creating field effect transistor (FET) body connections with high-quality matching characteristics and no area penalty for partially depleted silicon-on-insulator (SOI) circuits. The FET body connections are created for partially depleted silicon-on-insulator (SOI) technologies by forming adjacent FET devices inside a shallow trench shape. The adjacent FET devices share a common diffusion area, such as source or drain. Selectively spacing apart adjacent gate lines form an underpath connecting bodies of the adjacent FET devices. The underpath is defined by forming an undepleted region on top of a buried oxide layer. The adjacent polysilicon gate lines are selectively spaced apart to define a depth of depletion in a shared diffusion region for creating the underpath. Also, adjacent FET devices with connecting bodies can be built by adding an ion implant masking step to the fabrication process. This masking step changes the depletion depth under the shared diffusion area.

Abstract: A method and semiconductor structure are provided for implementing body contacts for semiconductor-on-insulator transistors. A bulk semiconductor substrate is provided. A mask is applied to the bulk semiconductor substrate to block an insulating implant layer in selected regions. The selected regions provide for body contact for transistors. Holes are formed extending into the bulk semiconductor substrate. The holes are filled with an electrically conductive material to create stud contacts to the bulk semiconductor substrate. In the preferred embodiment, the semiconductor-on-insulator is silicon on an oxide insulating layer and the invention provides a body contact for SOI transistors.

Abstract: A method and semiconductor structure are provided for implementing dual plane body contacts for silicon-on-insulator (SOI) transistors. A bulk silicon substrate is provided. A deep ion implant layer is implanted to reside below an oxide insulator. An oxygen implant layer is implanted while applying a mask to block the oxygen implant layer in selected regions. The selected regions provide for body contact for the SOI transistors. Holes are formed extending into the deep ion implant layer and the bulk silicon substrate. The holes are filled with an electrically conductive material to create stud contacts to the deep ion implant layer and the bulk silicon substrate.