Abstract: A process is provided for fabricating a wafer including a plurality of chips separated by scribe lines. The method includes locking at least one chip on the wafer using a secret key, and writing the secret key into at least one memory present on the wafer.

Abstract: A method for detecting and reporting changes in functional features of a simulation model caused by a software revision is disclosed. In one aspect, the method is independent of simulation model architecture. One performs regression testing with a plurality of feature-specific modules. The feature-specific modules are configured to generate a first set of information with the simulation model and compare the first set of information to a second set of corresponding information from the simulation model. In the above-described testing, the first set of information postdates the software revision and the second set of information predates the software revision.

Abstract: It is disclosed that, as an embodiment, a test circuit includes a test signal supply unit configured to supply a test signal via a signal line to signal receiving units provided in a plurality of columns, wherein the test signal supply unit is a voltage buffer or a current buffer, and the test circuit has a plurality of test signal supply units and a plurality of signal lines, and wherein at least one test signal supply unit is electrically connected to one signal line different from a signal line to which another test signal supply unit is electrically connected.

Abstract: An electronic circuit module and a method of manufacturing the electronic circuit module are disclosed. In one embodiment, the electronic circuit module includes i) a substrate on which a circuit is formed, ii) a plurality of electrical devices electrically connected to the circuit and iii) a first molding unit coated on the substrate to cover at least the electrical devices. The module further includes i) a test terminal unit comprising a plurality of test wires and configured to inspect the circuit, wherein each of the test wires comprises a first end electrically connected to the circuit and a second end exposed from the first molding unit, and wherein the second ends of the test wires form an inspection unit and are adjacent to each other on the substrate and ii) a second molding unit coated on the substrate to cover the second ends of the test wires.

Abstract: The invention provides a method for forming a testing wiring structure of a thin film transistor (TFT) motherboard for applying signals to a plurality of signal lines in a pixel region on the motherboard and a method for forming the same. The formed testing wiring structure comprises a gate layer metallic testing wiring and a drain layer metallic testing wiring that is over and intersects the gate layer metallic testing wiring. A pixel electrode layer testing wiring is further provided over the drain layer metallic testing wiring in an intersecting region where the drain layer metallic testing wiring intersects the gate layer metallic testing wiring. The pixel electrode layer testing wiring is electrically connected to the drain layer metallic testing wiring to be a redundant testing wiring of the drain layer metallic testing wiring.

Abstract: A sample with at least a first structure and a second structure is measured and a first model and a second model of the sample are generated. The first model models the first structure as an independent variable and models the second structure. The second model of the sample models the second structure as an independent variable. The measurement, the first model and the second model together to determine at least one desired parameter of the sample. For example, the first structure may be on a first layer and the second structure may be on a second layer that is under the first layer, and the processing of the sample may at least partially remove the first layer, wherein the second model models the first layer as having a thickness of zero.

Abstract: A contactor and an associated contact structure, probe card and test apparatus are provided. The contact may include a base part having three or more steps in a stairway state, a support part with a rear end side provided at the base part and a front end side sticking out from the base part, and a conductive part formed on a surface of the support part and electrically contacting a contact of a device under test.

Abstract: A semiconductor process test structure comprises an electrode, a charge-trapping layer, and a diffusion region. The test structure is a capacitor-like structure in which the charge-trapping layer will trap charges during various processing steps. Gate-induced drain leakage (GIDL) measurement techniques can then be used to characterize the charging status of the test structure.

Abstract: A method for manufacturing system includes 3D-IC comprising at least first layer of first transistors and second layers of second transistors and, perform a test for the circuit constructed with said first transistors and switch in function constructed with said second transistors to replace function constructed with said first transistors.

Abstract: A system and method employing at least one semiconductor device, or an arrangement of insulating and metal layers, having at least one detecting region which can include, for example, a recess or opening therein, for detecting a charge representative of a component of a polymer, such as a nucleic acid strand, proximate to the detecting region, and a method for manufacturing such a semiconductor device. The system and method can thus be used for sequencing individual nucleotides or bases of ribonucleic acid (RNA) or deoxyribonucleic acid (DNA). The semiconductor device includes at least two doped regions, such as two n-type regions implanted in a p-type semiconductor layer or two p-type regions implanted in an n-type semiconductor layer. The detecting region permits a current to pass between the two doped regions in response to the presence of the component of the polymer, such as a base of a DNA or RNA strand.

Abstract: A test structure for a through-silicon-via (TSV) in a semiconductor chip includes a first contact, the first contact being electrically connected to a first TSV; and a second contact, wherein the first contact, second contact, and the first TSV form a first channel, and a depth of the first TSV is determined based on a resistance of the first channel. A method of determining a depth of a through-silicon-via (TSV) in a semiconductor chip includes etching a first TSV into the semiconductor chip; forming a first channel, the first channel comprising the first TSV, a first contact electrically connected to the first TSV, and a second contact; connecting a current source to the second contact; determining a resistance across the first channel; and determining a depth of the first TSV based on the resistance of the first channel.

Abstract: A semiconductor structure including a test structure for detection of a gap in a conductive layer of the semiconductor structure includes a semiconductor substrate; the test structure, the test structure being located on the semiconductor substrate, the test structure comprising a multilayer gate stack, wherein the multilayer gate stack includes a single conductive layer region including: a gate dielectric located on the semiconductor substrate; the conductive layer located on the gate dielectric; and an undoped amorphous silicon layer located on the conductive layer; and wherein the test structure is configured to detect the presence of the gap in the conductive layer.

Abstract: By providing a test structure for evaluating the patterning process and/or the epitaxial growth process for forming embedded semiconductor alloys in sophisticated semiconductor devices, enhanced statistical relevance in combination with reduced test time may be accomplished.

Abstract: A device and method are provided for detecting stress migration properties of a semiconductor module mounted in a housing. A stress migration test (SMT) structure is formed in the semiconductor module. An integrated heating (IH) device is formed within or in direct proximity to the SMT structure. The SMT structure includes a first interconnect region in a first interconnect layer, a second interconnect region in a second interconnect layer, and a connecting region electrically connecting the interconnect regions through a first insulating layer. The IH device includes a heating interconnect region through which a heating current flows. The heating interconnect region is within or outside the first or second interconnect region or connecting region. When the heating current is applied, a measurement voltage is applied to the SMT structure, and a current through the SMT structure is measured to detect stress migration properties of the semiconductor module.

Abstract: A semiconductor device having the structure, which is adopted for the highly precise visual inspection with a lower cost, is achieved. A semiconductor device is a semiconductor device having a region for forming an electric circuit, and includes seal rings provided in an interconnect layer and surrounding the region for forming an electric circuit, and a dummy metal via provided in the interconnect layer and located outside of the seal rings. In a cross section perpendicular to an elongating direction of the seal ring, the width of the dummy metal via is smaller than the width of the seal ring.

Abstract: A probe having a sufficient height is manufactured by selectively depositing, over the main surface of a wafer, a copper film in a region in which a metal film is to be formed and a region which will be outside an adhesion ring when a probe card is fabricated; forming the metal film, polyimide film, interconnect, another polyimide film, another interconnect and a further polyimide film; and then removing the wafer and copper film. According to the present invention, when probe testing is performed using a prober (thin film probe) having the probe formed in the above-described manner while utilizing the manufacturing technology of semiconductor integrated circuit devices, it is possible to prevent breakage of the prober and a wafer to be tested.

Abstract: In embodiments of the current invention, methods of combinatorial processing and a test chip for use in these methods are described. These methods and test chips enable the efficient development of materials, processes, and process sequence integration schemes for semiconductor manufacturing processes. In general, the methods simplify the processing sequence of forming devices or partially formed devices on a test chip such that the devices can be tested immediately after formation. The immediate testing allows for the high throughput testing of varied materials, processes, or process sequences on the test chip. The test chip has multiple site isolated regions where each of the regions is varied from one another and the test chip is designed to enable high throughput testing of the different regions.

Abstract: A rewritable nonvolatile memory includes a test cell that is dedicated to testing the storage characteristics of other, similar, storage cells formed within the same integrated circuit memory. The test cell may be share the same structure and composition as storage cells and may be positioned proximate storage cells.

Abstract: The invention can provide apparatus and methods of creating metal gate structures on wafers in real-time using Lithography-Etch-Lithography-Etch (LELE) processing sequence. Real-time data and/or historical data associated with LELE processing sequences can be fed forward and/or fed back as fixed variables or constrained variables in internal-Integrated-Metrology modules (i-IMM) to improve the accuracy of the metal gate structures.

Abstract: A test structure for testing transistor gate structures in an IC device includes one or more probe pads formed at an active area of the IC device; one or more first conductive lines formed at the active area of the IC device, in electrical contact with the one or more probe pads; one or more second conductive lines formed at a gate conductor level of the IC device, in electrical contact with the one or more first conductive lines; and a gate electrode structure to be tested in electrical contact with the one or more second conductive lines; wherein the electrical contact between the one or more second conductive lines and the one or more first conductive lines is facilitated by a localized dielectric breakdown of a gate dielectric material disposed between the one or more second conductive lines and the one or more first conductive lines.

Abstract: A test chip comprises at least one level having an array of regions. Each region is capable of including at least one test structure. At least some of the regions include respective test structures. The level has a plurality of driver lines that provide input signals to the test structures. The level has a plurality of receiver lines that receive output signals from the test structures. The level has a plurality of devices for controlling current flow. Each test structure is connected to at least one of the driver lines with a first one of the devices in between. Each test structure is connected to at least one of the receiver lines with a second one of the devices in between, so that each of the test structures can be individually addressed for testing using the driver lines and receiver lines.

Abstract: A method of forming a device is disclosed. The method includes providing a substrate on which the device is formed. It also includes forming a test cell on the substrate. The test cell includes a defect programmed into the cell to facilitate defect detection.

Abstract: A semiconductor apparatus includes: a semiconductor chip, wherein a conductive layer is formed at one side of the semiconductor chip and one or more of probe pads are formed at the other side thereof; a plurality of through-silicon vias (TSVs), wherein one side of each of the plurality of TSVs is coupled to the conductive layer and the other side of one or more of the plurality of TSVs is coupled to the probe pad; a plurality of latch units each configured to be assigned to the plurality of corresponding TSVs and store a test signal, wherein the test signal is inputted via the probe pad and is transferred via the plurality of corresponding TSVs to the plurality of assigned latch units, respectively; and a signal combination unit configured to combine a plurality of signals stored in the plurality of latch units to output the result as an error detection signal.

Abstract: A semiconductor package includes a semiconductor chip having a circuit section. A first chip selection electrode passes through a first position of the semiconductor chip, and the first chip selection electrode has a first resistance and outputs a first signal. A second chip selection electrode passes through a second position of the semiconductor chip, and the second chip selection electrode has a second resistance greater than the first resistance and outputs a second signal. A signal comparison part is formed in the semiconductor chip and is electrically connected to the first and second chip selection electrodes. The signal comparison part compares the first signal applied from the first chip selection electrode to the second signal applied from the second chip selection electrode and outputs a chip selection signal to the circuit section depending upon the result of the comparison.

Abstract: Crack sensors for semiconductor devices, semiconductor devices, methods of manufacturing semiconductor devices, and methods of testing semiconductor devices are disclosed. In one embodiment, a crack sensor includes a conductive structure disposed proximate a perimeter of an integrated circuit. The conductive structure is formed in at least one conductive material layer of the integrated circuit. The conductive structure includes a first end and a second end. A first terminal is coupled to the first end of the conductive structure, and a second terminal is coupled to the second end of the conductive structure.

Abstract: The variation in the contact pressures of the plurality of contact terminals to the plurality of chip electrodes is decreased. A thin-film sheet (first sheet) includes: a principal surface (contact-terminal formation surface) on which a plurality of contactors (contact terminals) are formed; and a rear surface positioned on an opposite side to the principal surface. Also, in the thin film sheet, a plurality of wirings and dummy wiring are arranged between the principal surface and the rear surface. A slit formed of an opening portion penetrating from the principal surface of the thin-film sheet to the rear surface thereof is formed along the wiring between the dummy wiring and the contactor arranged at an end of a contactor group (first contact terminal group) in which the plurality of contactors are aligned.

Abstract: A sensor circuit for a flow sensor comprises terminating impedances connected in parallel to the sound transducers and has a signal generator, which is configured as a power source. The circuit arrangement is suitable particularly for the operation of an airflow sensor in internal combustion engines.

Abstract: The present invention is directed to a system that programmably interconnects integrated circuit chips and other components at near-intra-chip density. The system's contact structure allows it to adapt to components with a wide variety of contact spacings and interconnection requirements, the use of releasable attachment means allows component placement to be modified as needed, the system identifies the contacts and the components to facilitate specifying the inter-component connections, and the system provides signal conditioning and retiming to minimize issues with signal integrity and signal skew.

Abstract: A method for determining the presence of a sacrificial layer under a structure. The method includes providing at least one structure arranged above a substrate having a major surface lying in a plane, the at least one structure being clamped at at least one side. The method further includes exerting a force, such as a mechanical force, on the at least one structure. The force may have a predetermined amplitude and a component perpendicular to the substrate. Still further, the method includes determining the deflection of the at least one structure perpendicular to the plane of the substrate, and correlating the deflection of the at least one structure to the presence of a sacrificial layer between the substrate and the structure.

Abstract: The invention provides a testing wiring structure of a thin film transistor (TFT) motherboard for applying signals to a plurality of signal lines in a pixel region on the motherboard and a method for forming the same. The testing wiring structure comprises a gate layer metallic testing wiring and a drain layer metallic testing wiring that is over and intersects the gate layer metallic testing wiring. The gate layer metallic testing wiring are connected to a portion of the plurality of signal lines and the drain layer metallic testing wiring both are connected to remaining portion of the plurality of signal lines. A pixel electrode layer testing wiring is further provided over the drain layer metallic testing wiring in an intersecting region where the drain layer metallic testing wiring intersects the gate layer metallic testing wiring.

Abstract: By forming a trench-like test opening above a respective test metal region during the etch process for forming via openings in a dielectric layer stack of sophisticated metallization structures of semiconductor devices, the difference in etch rate in the respective openings may be used for generating a corresponding variation of electrical characteristics of the test metal region. Consequently, by means of the electrical characteristics, respective variations of the etch process may be identified.

Abstract: A block of phase change material located in a semiconductor chip is reset to an amorphous state. The block of phase change material may be connected to an internal resistance measurement circuit that can transmit the measured resistance data to input/output pads either in an analog output format or in a digital output format. Depending on the ambient temperature, the resistance of the block of phase change material changes. By measuring a fractional resistance change compared to the resistance of the phase change material at a calibration temperature, the temperature of the region around the phase change material can be accurately measured. A logic decoder and an input/output circuit may be employed between the internal resistance measurement circuit and the input/output pads. A plurality of temperature sensing circuits containing phase change material blocks may be employed in the semiconductor chip to enable an accurate temperature profiling during chip operation.

Abstract: The present invention is a method for evaluating a silicon wafer by measuring, after fabricating a MOS capacitor by forming an insulator film and one or more electrodes sequentially on a silicon wafer, a dielectric breakdown characteristic of the insulator film by applying an electric field from the electrodes thus formed to the insulator film, the method in which the silicon wafer is evaluated at least by setting an area occupied by all the electrodes thus formed to 5% or more of an area of a front surface of the silicon wafer when the one or more electrodes are formed. This provides an evaluation method that can detect a defect by a simple method such as the TDDB method with the same high degree of precision as that of the DSOD method.

Abstract: A technique of manufacturing a semiconductor device capable of performing a probe test by a common test apparatus as normal LSI chips even for large-area chips is provided. A chip comprising a device formed on a device area by a semiconductor process and including a plurality of test areas sectioned by chip areas is prepared. Next, pads to be electrically connected to the device are formed at corresponding positions on the respective plurality of test areas. Subsequently, the respective test areas are tested by a same probe card via the plurality of pads.

Abstract: A semiconductor wafer in which a plurality of regions, designed to become semiconductor chips are provided in a matrix array with interposition of a dicing line(s) respectively separating the regions. The semiconductor wafer comprises: a plurality of test pads provided in an area(s) of the semiconductor wafer disposed between the semiconductor chips, inclusive of the dicing line(s); an inter-test pad interconnect(s) provided in parallel with the test pads in the area(s) of the semiconductor wafer disposed between the regions to become semiconductor chips; the inter-test pad interconnect(s) being connected to the test pads; and an inter-chip interconnect that interconnects at least two of the regions designed to become semiconductor chips; the inter-test pad interconnect being electrically connected to the inter-chip interconnect.

Abstract: A test structure including at least one ground pad, an input pad, at least one first through-silicon via (TSV), at least one second TSV and an output pad is disclosed. The ground pad receives a ground signal during a test mode. The input pad receives a test signal during the test mode. The first TSV is coupled to the input pad. The output pad is coupled to the second TSV. No connection line occurs between the first and the second TSVs. During the test mode, a test result is obtained according to the signal of at least one of the first and the second TSVs, and structural characteristics can be obtained according to the test result.

Abstract: A dicing method, integrated circuit chip testing method, substrate holding apparatus, and adhesive film are disclosed. A first adhesive film 22 in which the adhesion is reduced by ultraviolet radiation is stretched inside a ring-like frame 21 larger than a wafer size, and a wafer W is adhered on the first adhesion film 22. A second adhesive film 4 in which the adhesion of the two surfaces is reduced by heating is adhered on a plate-like jig 3. After the first film is adhered on the second film, dicing is performed. Since the wafer is adhered to the jig, the relative positions of chips do not shift from each other. This makes it possible to load the wafer together with the jig into a testing apparatus and align electrode pads of the chips with a probe. This allows, e.g., collective testing of a plurality of chips.

Abstract: A probe card having a plurality of silicon finger contactors contacting pads provided on a tested semiconductor wafer and a probe board mounting the plurality of silicon finger contactors on its surface, wherein each silicon finger contactor has a base part on which a step difference is formed, a support part with a rear end side provided at the base part and with a front end side sticking out from the base part, and a conductive part formed on the surface of the support part, each silicon finger contactor mounted on the probe board so that an angle part of the step difference formed on the base part contacts the surface of the probe board.

Abstract: Some embodiments include methods for quality testing material removal procedures. A test structure is formed to contain a pair of electrically conductive segments. The segments are the same relative to a detectable property as long as they are electrically connected, but becoming different relative to such property if they are disconnected from one another. A material is formed over the test structure, and across a region of a semiconductor substrate proximate to the test structure. The material is subjected to a procedure which removes at least some of it, and which fabricates a structure of an integrated circuit construction in the region proximate to the test structure. After the procedure, it is determined if the segments are the same relative to the detectable property.

Abstract: Stacking techniques are illustrated in example embodiments of the present invention wherein semiconductor dies are mounted in a module to become a MCM which serves as the basic building block. A combination of these modules and dies in a substrate creates a package with specific function or a range of memory capacity. Several example system configurations are provided using BGA and PGA to illustrate the stacking technique. Several pin assignment and signal routing techniques are illustrated wherein internal and external signals are routed from main board to various stacked modules. Expansion can be done both on the vertical and horizontal orientations.

Abstract: When forming critical threshold adjusting semiconductor alloys and/or strain-inducing embedded semiconductor materials in sophisticated semiconductor devices, at least the corresponding etch processes may be monitored efficiently on the basis of mechanically gathered profile measurement data by providing an appropriately designed test structure. Consequently, sophisticated process sequences performed on bulk semiconductor devices may be efficiently monitored and/or controlled by means of the mechanically obtained profile measurement data without significant delay. For example, superior uniformity upon providing a threshold adjusting semiconductor alloy in sophisticated high-k metal gate electrode structures for non-SOI devices may be achieved.

Abstract: A pattern of conductive ink is disposed on the topside of the unsingulated integrated circuits of a wafer, and, typically after wafer probing, the pattern of conductive ink is removed. The conductive ink pattern provides an electrical pathway between bond pads on an integrated circuit and large contact pads disposed on the topside of the integrated circuit. Each of the large contact pads is much greater in area than the corresponding bond pads, and are spaced apart so that the pitch of the large contact pads is much greater than that of the bond pads. In one aspect of the present invention, the conductive ink includes a mixture of conductive particles and wafer bonding thermoset plastic. In another aspect of the present invention, the conductive ink is heated and disposed on a wafer by an ink jet printing system.

Abstract: A wafer level integration module and method for fabricating are disclosed according to a construction whereby semiconductor functional device fabrication is carried out only after interconnect structures are processed on a bare wafer. The fabrication and processing include forming interconnect structures in a first side of a wafer. An insulation layer is deposited on the first side of the wafer. A conductive layer is deposited on the insulation layer so as to fill the interconnect structures and contact the insulation layer on the walls thereof. The conductive layer on the interconnect structures forms interconnection contacts on the first side of the wafer and interconnection vias extending into the wafer. The conductive layer including the interconnection contacts is exposed on the first side of the wafer. A semiconductor functional device is fabricated on the first side of the wafer and interconnected with the interconnection contacts during the fabricating.

Abstract: An object is to prevent a breakage of a membrane probe and a wafer to be tested in a probe testing using a membrane probe with styluses formed by a manufacturing technology for a semiconductor integrated circuit device. Measures are: obtaining an image of a region PCA within the surface of a wafer including a region OGA pressed by a pressing member, at the center of which a chip just after probe-tested is located, by an imaging means such as a camera; comparing an image of a normal chip obtained in advance and an image of all the chips within the region PCA; and judging thereby whether an abnormal shape is caused or not in all the chips within the region PCA.

Abstract: The present invention discloses a semiconductor wafer having a scribe line dividing the semiconductor wafer into a matrix of plural semiconductor chips. The semiconductor wafer includes a polysilicon layer, a poly-metal interlayer insulation film formed on the polysilicon layer, and a first metal wiring layer formed on the poly-metal interlayer insulation film. The semiconductor wafer includes a process-monitor electrode pad formed on a dicing area of the scribe line. The process-monitor electrode pad has a width greater than the width of the dicing area. The process-monitor electrode pad includes a contact hole formed in the poly-metal insulation film for connecting the first metal wiring layer to the polysilicon layer.

Abstract: A semiconductor device according to one embodiment of this invention includes: a semiconductor chip; a plurality of external connection pads and a plurality of first test pads, both of which are formed in a central region of a top surface of the semiconductor chip; a plurality of external connection electrodes each formed on a corresponding one of the external connection pads, the external connection electrodes being for connecting the external connection pads and an outside of the semiconductor device.

Abstract: Memory device, comprising a storage material, a first electrode connected to the storage material; and a second electrode associated to the storage material.

Abstract: A probe having a sufficient height is manufactured by selectively depositing, over the main surface of a wafer, a copper film in a region in which a metal film is to be formed and a region which will be outside an adhesion ring when a probe card is fabricated; forming the metal film, polyimide film, interconnect, another polyimide film, another interconnect and a further polyimide film; and then removing the wafer and copper film. According to the present invention, when probe testing is performed using a prober (thin film probe) having the probe formed in the above-described manner while utilizing the manufacturing technology of semiconductor integrated circuit devices, it is possible to prevent breakage of the prober and a wafer to be tested.

Abstract: A method of enabling a circuit board analysis is disclosed. The method comprising removing a portion of the circuit board on a first side of the circuit board opposite a second side of the circuit board having an integrated circuit package; removing the circuit board from the integrated circuit package; performing a dye mapping to analyze bonds between the integrated circuit package and the circuit board; and performing an analysis of the integrated circuit package.

Abstract: An integrated circuit includes a functional block having a plurality of standard cells. The plurality of standard cells includes a plurality of functional standard cells and a filler standard cell. Each functional standard cell of the plurality of functional standard cells has a rectangular boundary. The filler standard cell has a rectangular boundary adjacent to at least one of the functional standard cells. The filler standard cell is selectable between a first state and a second state. The filler standard cell is non-functional in the first state. The filler standard cell has functional test structures coupled to a first metal layer in the second state. This allows for test structures helpful in analyzing functionality of circuit features such as transistors without requiring additional space on the integrated circuit.