Abstract: A cellular phone is provided with a media scanning capability. Scanner optics, an optional light source and related scanning circuitry is integrated within a cellular phone to enable image or text scanning, facsimile, text-to-speech conversion, and language translation. Position sensors provide position data as the scanner is manually moved, in one or more passes across the scanned media, to enable a bit-mapped image of the strip to be created in a data buffer. Image data from the strips is processed to remove redundant overlap data and skew position errors, to give a bit-mapped final image of the entire scanned item. Image compression is provided to compress the image into standard JPEG format for storage or transmission, or into facsimile format for transmission of the document to any fax machine. Optical character recognition (OCR) is provided to convert image data to text which may be sent as email, locally displayed, stored for later use, or further processed.

Abstract: A test circuit for, and method of, determining electrical properties of an underlying interconnect layer and an overlying interconnect layer of an integrated circuit (IC) and an IC incorporating the test circuit or the method. In one embodiment, the test circuit includes a gate chain having a ring path and a stage. In one embodiment, the stage includes: (1) a underlying test segment in the underlying interconnect layer, (2) a overlying test segment in the overlying interconnect layer and (3) logic circuitry activatible after formation of the underlying interconnect layer and before formation of the overlying interconnect layer to place the underlying test segment in the ring path and further activatible after the formation of the overlying interconnect layer to substitute the overlying test segment for the underlying test segment in the ring path.

Abstract: The invention provides a method for manufacturing an integrated circuit. The method, in one embodiment, includes inspecting a semiconductor wafer including a plurality of die for a defect, the inspecting providing an image of the semiconductor wafer including the defect. The method further includes identifying an area of the semiconductor wafer from the image, wherein the identified area encompasses at least those die including any portion of the defect, and dicing the semiconductor wafer into individual die. The die defined by the identified area, in this embodiment, are then discarded.

Abstract: A semiconductor device comprising source and drain regions and insulating region and a plate structure. The source and drain regions are on or in a semiconductor substrate. The insulating region is on or in the semiconductor substrate and located between the source and drain regions. The insulating region has a thin layer and a thick layer. The thick layer includes a plurality of insulating stripes that are separated from each other and that extend across a length between the source and the drain regions. The plate structure is located between the source and the drain regions, wherein the plate structure is located on the thin layer and portions of the thick layer, the plate structure having one or more conductive bands that are directly over individual ones of the plurality of insulating stripes.

Abstract: A semiconductor device comprising a first transistor device on or in a semiconductor substrate and a second transistor device on or in the substrate. The device further comprises an insulating trench located between the first transistor device and the second transistor device. At least one upper corner of the insulating trench is a rounded corner in a lateral plane of the substrate.

Abstract: A method for manufacturing an isolation structure is disclosed that protects the isolation structure during etching of a dichlorosilane (DCS) nitride layer. The method involves the formation of a bis-(t-butylamino)silane-based nitride liner layer within the isolation trench, which exhibits a five-fold greater resistance to nitride etching solutions as compared with DCS nitride, thereby allowing protection against damage from unintended over-etching. The bis-(t-butylamino)silane-based nitride layer also exerts a greater tensile strain on moat regions that results in heightened carrier mobility of active regions, thereby increasing the performance of NMOS transistors embedded therein.

Abstract: An integrated circuit (25) formed at a semiconducting surface of a substrate including a common p-layer (38) includes functional circuitry (24) formed on the p-layer (38) including a plurality of terminals (IN, OUT, I/O) coupled to the functional circuitry (24). At least one ESD protection cell (30; in more detail 200) is connected to at least one of the plurality of terminals of the functional circuitry (24). The protection cell includes at least a first Nwell (37) formed in the p-layer (38), a p-doped diffusion (36) within the first Nwell (37) to form at least one Nwell diode comprising an anode (37) and a cathode (36). An NMOS transistor 200 is formed in or on the p-layer (38) comprising a n+ source (43), n+drain (44) and a channel region comprising a p-region (41) between the source and drain, and a gate electrode (45) on a gate dielectric (46) on the channel region.

Abstract: Integrated circuits using buried layers under epitaxial layers present a challenge in aligning patterns for surface components to the buried layers, because the epitaxial material over the buried layer diminishes the visibility of and shifts the apparent position of the buried layer. A method of measuring the lateral offset, known as the epi pattern shift, between a buried layer and a pattern for a surface component using planar processing technology and commonly used semiconductor fabrication metrology tools is disclosed. The disclosed method may be used on a pilot wafer to provide optimization data for a production line running production wafers, or may be used on production wafers directly. An integrated circuit fabricated using the instant invention is also disclosed.

Abstract: Methods of analyzing equivalency with respect to split and limited release lots of wafers of integrated circuits. One embodiment of the split-lot method includes: (1) dividing a set of data regarding the split lot into control and experimental subsets, (2) summarizing statistics regarding the set and the subsets to an experimental unit above a site level and (3) performing a two-way analysis of variance with respect to the statistics to determine the equivalency, using the set for one way of the analysis of variance and the subsets for another way of the analysis of variance.

Abstract: A method for manufacturing a semiconductor device that method comprises forming a thin film resistor by a process that includes depositing a resistive material layer on a semiconductor substrate. The process also includes depositing an insulating layer on the resistive material layer, and performing a first dry etch process on the insulating layer to form an insulative body. The process further includes performing a second dry etch process on the resistive material layer to form a resistive body. The resistive body and the insulative body have substantially identical perimeters.

Abstract: The present application is directed to apparatus and methods for determining a magnitude of defocus and a direction of defocus for a photolithography process. A sub-resolution feature on a reticle which is not printed on a wafer at the best focus offset, but is formed on a wafer at some defocus during the photolithography process is analyzed to determine the magnitude and direction of defocus. The magnitude and direction of defocus are used to adjust the photolithography process to an optimal focus based on the determined magnitude of defocus and the determined direction of defocus.

Abstract: Devices and methods are presented to fabricate dummy moats in an isolation region on a substrate. Presently, dummy moats are prone to losing impedance after the silicidation process. In high-voltage devices, silicided dummy moats reduce the breakdown voltage between active regions, particularly when the dummy moat overlaps or is in close proximity to a junction. The present devices and methods disclose a dummy moat covered with an oxide layer. During the silicidation process, the dummy moat and other designated isolation regions remain non-silicided. Thus, high and stable breakdown voltages are maintained.

Abstract: Conduction between source and drain or emitter and collector regions is an important characteristic in transistor operation, particularly for lateral bipolar transistors. Accordingly, techniques that can facilitate control over this characteristic can mitigate yield loss by promoting the production of transistors that have an increased likelihood of exhibiting desired operational performance. As disclosed herein, well regions are established in a semiconductor substrate to facilitate, among other things, control over the conduction between the source and drain regions of a lateral bipolar transistor, thus mitigating yield loss and other associated fabrication deficiencies. Importantly, an additional mask is not required in establishing the well regions, thus further mitigating (increased) costs associated with promoting desired device performance.

Abstract: The present disclosure is directed to a method for monitoring focus of a photolithography system. The method comprises providing a substrate and depositing a photoresist layer on the substrate. At least one photomask is provided comprising one or more forbidden pitch photomask patterns formed thereon. The forbidden pitch patterns are imaged in the photoresist layer by exposing the photoresist layer to radiation through the at least one photomask. The imaged forbidden pitch patterns are developed in the photoresist. Focus error information regarding the imaging process can be determined using the developed forbidden pitch patterns.

Abstract: The formation of a lithographic mask (100) is disclosed, where the mask (100) can be used in forming integrated circuits onto a semiconductor substrate. A layer of etch stop material (106) is sandwiched between first (102) and second (108) layers of transmissive material that are substantially transparent to lithographic light. The layer of etch stop material (106) serves as an etch stop when a circuit pattern is etched into the second layer of transmissive material (108). This allows the second layer of etch stop material (108) to be etched to a more precise depth thereby providing a desired phase shift and concurrently controlling critical dimension width.

Abstract: The present application is directed a method for determining the position of photomask patterns in a mask making process. The method comprises providing one or more mask rules defining the minimum spacing between photomask patterns. The method further comprises determining the position of a first photomask pattern relative to an adjacent second photomask pattern, the first photomask pattern having a critical edge for defining a critical dimension of a first device structure and a non-critical edge for defining a non-critical dimension. The non-critical edge is attached to the critical edge so that the positioning of the non-critical edge will affect the length of the critical edge. The non-critical edge of the first photomask pattern is positioned a distance X from an edge of the second photomask pattern, wherein the distance X is chosen to be substantially the minimum spacing allowed by the mask rules.

Abstract: A method of manufacturing a semiconductor device. The method comprises fabricating a ferroelectric capacitor. The capacitor's fabrication includes forming conductive and ferroelectric material layers on a semiconductor substrate, forming a hardmask layer on the conductive and ferroelectric material layers, forming an organic bottom antireflective coating layer on the hardmask layer, and, patterning the organic bottom antireflective coating layer. Seasoning in a hardmask etching chamber is substantially unaffected by the patterning.

Abstract: The present invention provides, in one embodiment, a method of manufacturing a metal oxide semiconductor (MOS) transistor (100). The method comprises forming an active area (105) in a substrate (115), wherein the active area (105) is bounded by an isolation structure (120). The method further includes placing at least one stress adjuster (130) adjacent the active area (105), wherein the stress adjuster (130) is positioned to modify a mobility of a majority carrier within a channel region (155) of the MOS transistor (100). Other embodiments of the present invention include a MOS transistor device (200) and a process (300) for constructing an integrated circuit.

Abstract: Exemplary embodiments provide a tri-layer resist (TLR) stack used in a photolithographic process, and methods for resist reworking by a single plasma etch process. The single plasma etch process can be used to remove one or more portions/layers of the TLR stack that needs to be reworked in a single process. The removed portions/layers can then be re-formed and resulting in a reworked TLR stack for subsequent photo-resist (PR) processing. The disclosed plasma-etch resist rework method can be a fast, simple, and cost effective process used in either single or dual damascene tri-layer patterning processes for the fabrication of, for example, sub 45-nm node semiconductor structures.

Abstract: An integrated circuit back end capacitor structure includes a first dielectric layer on a substrate, a thin film bottom plate on the first dielectric layer, and a second dielectric layer on the first dielectric layer and the bottom plate, and a thin film top plate disposed on the second dielectric layer. The thin film top plate and bottom plate are composed of thin film resistive layers, such as sichrome, which also are utilized to form back end thin film resistors having various properties. Interconnect conductors of a metallization layer contact the top and bottom plates through corresponding vias.