Abstract: A method of testing an integrated circuit (IC) chip and a related test structure are disclosed. A test structure includes a monitor chain proximate to at least one solder bump pad, the monitor chain including at least one metal via stack, each metal via stack extending from a lower metal layer in the IC chip to an upper metal layer in the IC chip, such that the monitor chain forms a continuous circuit proximate to the at least one solder bump pad, and where each metal via stack is positioned substantially under the solder bump. A method for testing to detect boundaries of safe effective modulus includes performing a stress test on an IC chip containing the test structure joined to a semiconductor package.

Abstract: Methods and structures are provided for packaging identically processed chips in a stacked structure. A latch chain includes a first latch chain, having a single or multiple latches, associated with a first chip. The first latch chain is structured to read data information from the first chip. The latch chain includes a second latch chain, having a single or multiple latches, associated with a second chip. The second latch chain is structured to read data information from the second chip. The first latch chain and the second latch chain are connected to one another such that form a single latch chain that crosses chip boundaries. The first latch chain and the second latch chain are structured to provide identification information for identifying the first chip and the second chip, respectively.

Abstract: One embodiment is a non-volatile memory cell with random access read, program, and erase. The memory cell includes a cell transistor that includes a source region, a drain region, a first insulating spacer, and a second insulating spacer. The memory cell also includes a source-side transistor, a drain-side transistor, a source-side multiplexer, a drain-side multiplexer, a source-side sense amplifier, and a drain-side write driver. A first binary value is stored in a first bit in the memory cell by trapping or releasing a first electric charge in the first insulating spacer. The first bit is read by sensing the resistive change in the cell transistor or by sensing the threshold voltage change in the cell transistor.

Abstract: Normally closed (shut) micro-electro-mechanical switches (MEMS), methods of manufacture and design structures are provided. A method of forming a micro-electrical-mechanical structure (MEMS), includes forming a plurality of electrodes on a substrate, forming a beam structure in electrical contact with a first of the electrodes, and bending the beam structure with a thermal process. The method further includes forming a cantilevered electrode extending over an end of the bent beam structure, and returning the beam structure to its original position, which will contact the cantilevered electrode in a normally closed position.

Abstract: Detection circuits, methods of use and manufacture and design structures are provided herein. The structure includes at least one signal line traversing one or more metal layers of an integrated circuit. Circuitry is coupled to the at least one signal line, which is structured to receive a signal with a known signal from the at least one signal line or a signal from a different potential and, based on which signal is received, determine whether there is a structural defect in the integrated circuit.

Abstract: An integrated circuit package including a package substrate, a metal lid mounted to the package substrate, and a stack of two or more integrated circuit chips electrically connected to each other by through substrate vias. The stack of two or more integrated circuit chips is disposed within the metal lid and electrically mounted to the package substrate. An inner surface of a top of the metal lid is electrically connected to ground wires in the package substrate by the through substrate vias. The TSVs provide electromagnetic interference shielding. A conductive thermal interface material may also be used. An alternative embodiment includes a single integrated circuit chip using TSVs to ground the metal lid.

Abstract: One embodiment is a non-volatile memory cell with random access read, program, and erase. The memory cell includes a cell transistor that includes a source region, a drain region, a first insulating spacer, and a second insulating spacer. The memory cell also includes a source-side transistor, a drain-side transistor, a source-side multiplexer, a drain-side multiplexer, a source-side sense amplifier, and a drain-side write driver. A first binary value is stored in a first bit in the memory cell by trapping or releasing a first electric charge in the first insulating spacer. The first bit is read by sensing the resistive change in the cell transistor or by sensing the threshold voltage change in the cell transistor.

Abstract: A nonvolatile static random access memory (SRAM) device includes a pair of cross-coupled, complementary metal oxide semiconductor (CMOS) inverters configured as a storage cell for a bit of data and a pair of magnetic spin transfer devices coupled to opposing sides of the storage cell. The magnetic spin transfer devices are configured to retain the storage cell data therein following removal of power to the SRAM device, and are further configured to initialize the storage cell with the retained data upon application of power to the SRAM device.

Abstract: Disclosed is a design structure of an improved large scale memory system and, more particularly, an improved memory system that incorporates an array of memory cells that are subjected to minimal location dependent power variations and that, optionally, allows for bi-directional random access of millions of bits. Specifically, the system architecture provides a consistent amount of bit line resistance in the write and read paths to each memory cell in the array, independent of position, in order to minimize variations in power delivery to the cells and, thereby, allow for optimal cell distributions. The system architecture further allows current to pass in either direction through the cells in order to minimize element electro-migration and, thereby, extend memory cell life.

Abstract: Disclosed is an across-chip temperature sensing circuit and an associated method that can be used to profile the across-chip temperature gradient. The embodiments incorporate a plurality of phase change elements distributed approximately evenly across the semiconductor chip. These phase change elements are programmed to have essentially the same amorphous resistance. Temperature-dependent behavior exhibited by each of the phase change elements individually is compared to a reference (e.g., generated by a discrete reference phase change element, generated by another one of the phase change elements, or generated by an external reference) in order to profile the temperature gradient across the semiconductor chip. Once profiled, this temperature gradient can be used to redesign and/or relocate functional cores, to set stress limits for qualification of functional cores and/or to adjust operating specifications of functional cores.

Abstract: An apparatus for sensing the data state of a multiple level, programmable resistive memory device includes an active clamping device connected to a data leg that is selectively coupled a programmable resistive memory element, the clamping device configured to clamp a fixed voltage, at a first node of the data leg, across the memory element, thereby establishing a fixed current sinking capability thereof; and a plurality of differential amplifiers, each of the differential amplifiers configured to compare a first voltage input, taken at a second node of the data leg, with a second voltage input; wherein the second voltage input for each differential amplifier comprises different reference voltages with respect to one another so as to enable each differential amplifier to detect a different resistance threshold, thereby determining a specific resistance state of the programmable resistive memory element.

Abstract: An apparatus for directly measuring performance offset of NFET transistors with respect to PFET transistors in CMOS device processing includes a ring oscillator whose frequency is used to measure random across chip variations, as well as correlated across chip variations; a balanced inverter having a input driven by the ring oscillator, wherein the balanced inverter is designed to be formed such that a current drive capability of one or more NFET devices of the inverter is substantially equal to a current drive capability of one or more PFET devices of the inverter at a given operating temperature; and a capacitor coupled to an output of the inverter, with a voltage across the capacitor indicative of whether a skew exists between NFET device performance and PFET device performance.

Abstract: A nonvolatile static random access memory (SRAM) device includes a pair of cross-coupled, complementary metal oxide semiconductor (CMOS) inverters configured as a storage cell for a bit of data and a pair of magnetic spin transfer devices coupled to opposing sides of the storage cell. The magnetic spin transfer devices are configured to retain the storage cell data therein following removal of power to the SRAM device, and are further configured to initialize the storage cell with the retained data upon application of power to the SRAM device.

Abstract: A nonvolatile static random access memory (SRAM) device includes a pair of cross-coupled, complementary metal oxide semiconductor (CMOS) inverters configured as a storage cell for a bit of data and a pair of magnetic spin transfer devices coupled to opposing sides of the storage cell. The magnetic spin transfer devices are configured to retain the storage cell data therein following removal of power to the SRAM device, and are further configured to initialize the storage cell with the retained data upon application of power to the SRAM device.

Abstract: Disclosed is an across-chip temperature sensing circuit and an associated method that can be used to profile the across-chip temperature gradient. The embodiments incorporate a plurality of phase change elements distributed approximately evenly across the semiconductor chip. These phase change elements are programmed to have essentially the same amorphous resistance. Temperature-dependent behavior exhibited by each of the phase change elements individually is compared to a reference (e.g., generated by a discrete reference phase change element, generated by another one of the phase change elements, or generated by an external reference) in order to profile the temperature gradient across the semiconductor chip. Once profiled, this temperature gradient can be used to redesign and/or relocate functional cores, to set stress limits for qualification of functional cores and/or to adjust operating specifications of functional cores.

Abstract: A design structure embodied in a machine readable medium used in a design process includes an apparatus for initializing a reference cell in a toggle switched MRAM device, with a first sense amplifier configured for performing a first read operation of the reference cell by comparing current through the reference cell with the average current passing through a pair of data cells; a first latch for storing the result of the first read operation; a second latch for storing the result of a second read operation by the first sense amplifier, wherein the second read operation is performed following the first read operation and the inversion of the value of one of the pair of the data cells; a third latch for storing the result of a third read operation by the first sense amplifier, wherein the third read operation is performed following the second read operation and the inversion of the value of the other of the pair of the data cells; and a majority compare device configured to compare of the results of the first

Abstract: An apparatus for sensing the data state of a multiple level, programmable resistive memory device includes an active clamping device connected to a data leg that is selectively coupled a programmable resistive memory element, the clamping device configured to clamp a fixed voltage, at a first node of the data leg, across the memory element, thereby establishing a fixed current sinking capability thereof; and a plurality of differential amplifiers, each of the differential amplifiers configured to compare a first voltage input, taken at a second node of the data leg, with a second voltage input; wherein the second voltage input for each differential amplifier comprises different reference voltages with respect to one another so as to enable each differential amplifier to detect a different resistance threshold, thereby determining a specific resistance state of the programmable resistive memory element.

Abstract: A precision sense amplifier apparatus includes a current source configured to introduce an adjustable reference current through a reference leg; a current mirror configured to mirror the reference current to a data leg, the data leg selectively coupled to a programmable resistance memory element; an active clamping device coupled to the data leg, and configured to clamp a fixed voltage across the memory element, thereby establishing a fixed current sinking capability thereof; and a differential sense amplifier having a first input thereof coupled to the data leg and a second input thereof coupled to the reference leg; wherein an output of the differential sense amplifier assumes a first logic state whenever the reference current is less than the fixed current sinking capability of the memory element, and assumes a second logic state whenever the reference current exceeds the fixed current sinking capability.

Abstract: A design structure embodied in a machine readable medium used in a design process includes an apparatus for initializing a reference cell in a toggle switched MRAM device, with a first sense amplifier configured for performing a first read operation of the reference cell by comparing current through the reference cell with the average current passing through a pair of data cells; a first latch for storing the result of the first read operation; a second latch for storing the result of a second read operation by the first sense amplifier, wherein the second read operation is performed following the first read operation and the inversion of the value of one of the pair of the data cells; a third latch for storing the result of a third read operation by the first sense amplifier, wherein the third read operation is performed following the second read operation and the inversion of the value of the other of the pair of the data cells; and a majority compare device configured to compare of the results of the first

Abstract: A precision sense amplifier apparatus includes a current source configured to introduce an adjustable reference current through a reference leg; a current mirror configured to mirror the reference current to a data leg, the data leg selectively coupled to a programmable resistance memory element; an active clamping device coupled to the data leg, and configured to clamp a fixed voltage across the memory element, thereby establishing a fixed current sinking capability thereof; and a differential sense amplifier having a first input thereof coupled to the data leg and a second input thereof coupled to the reference leg; wherein an output of the differential sense amplifier assumes a first logic state whenever the reference current is less than the fixed current sinking capability of the memory element, and assumes a second logic state whenever the reference current exceeds the fixed current sinking capability.