Abstract: A memory system with transparent error correction circuitry provides full stuck-at fault coverage for both test data patterns and the corresponding error correction code (ECC) values. The memory system includes a semiconductor memory having a memory array, a memory interface and an error detection/correction unit. The memory array is configured to store test data patterns and corresponding error correction code (ECC) values. The memory interface is configured such that the ECC values are not directly accessible. The error detection/correction unit is configured to correct single-bit errors in the test data patterns and corresponding ECC values. A set of test data patterns associated with the semiconductor memory is selected such that any multiple-bit error in a test data pattern and the corresponding ECC value causes the error detection/correction unit to provide an output data pattern having an error, thereby rendering multiple-bit faults 100% detectable.

Abstract: An embedded memory system includes an array of dynamic random access memory (DRAM) cells, which are isolated with deep trench isolation, and logic transistors, which are isolated with shallow trench isolation. Each DRAM cell includes an access transistor and a capacitor structure. The capacitor structure is fabricated by forming a metal-dielectric-semiconductor (MOS) capacitor in a deep trench isolation region. A cavity is formed in the deep trench isolation, thereby exposing a sidewall region of the substrate. The sidewall region is doped, thereby forming one electrode of the cell capacitor. A gate dielectric layer is formed over the exposed sidewall, and a polysilicon layer is deposited over the resulting structure, thereby filling the cavity. The polysilicon layer is patterned to form the gate electrode of the access transistor and a capacitor electrode, which extends over the sidewall region and upper surface of the substrate.

Abstract: A method and structure for implementing a DRAM memory array as a second level cache memory in a computer system. The computer system includes a central processing unit (CPU), a first level SRAM cache memory, a CPU bus coupled to the CPU, and second level cache memory which includes a DRAM array coupled to the CPU bus. When accessing the DRAM array, row access and column decoding operations are performed in a self-timed asynchronous manner. Predetermined sequences of column select operations are then performed in a synchronous manner with respect to a clock signal. A widened data path is provided to the DRAM array, effectively increasing the data rate of the DRAM array. By operating the DRAM array at a higher data rate than the CPU bus, additional time is provided for precharging the DRAM array. As a result, precharging of the DRAM array is transparent to the CPU bus.

Abstract: An embedded memory system includes an array of dynamic random access memory (DRAM) cells, which are isolated with deep trench isolation, and logic transistors, which are isolated with shallow trench isolation. Each DRAM cell includes an access transistor and a capacitor structure. The capacitor structure is fabricated by forming a metal-dielectric-semiconductor (MOS) capacitor in a deep trench isolation region. A cavity is formed in the deep trench isolation, thereby exposing a sidewall region of the substrate. The sidewall region is doped, thereby forming one electrode of the cell capacitor. A gate dielectric layer is formed over the exposed sidewall, and a polysilicon layer is deposited over the resulting structure, thereby filling the cavity. The polysilicon layer is patterned to form the gate electrode of the access transistor and a capacitor electrode, which extends over the sidewall region and upper surface of the substrate.

Abstract: A non-volatile memory cell is fabricated using a conventional logic process, with minor modifications. The cell is fabricated by forming a shallow trench isolation (STI) region in a well region of a semiconductor substrate. A recessed region is formed in the STI region, wherein the recessed region extends into the STI region and exposes a sidewall region in the well region. A capacitor region is formed in the sidewall region. A dielectric layer is formed over the well region, including the sidewall region. A gate electrode is then formed over the dielectric layer, wherein a portion of the gate electrode extends into the recessed region. An access transistor of the cell is then formed in a self-aligned manner with respect to the gate electrode. A capacitor structure is formed by the gate electrode (in the recessed region), the dielectric layer on the sidewall region, and the capacitor region.

Abstract: A memory device that uses error correction code (ECC) circuitry to improve the reliability of the memory device in view of single-bit errors caused by hard failure or soft error. A write buffer is used to post write data, so that ECC generation and memory write array operation can be carried out in parallel. As a result there is no penalty in write latency or memory cycle time due to ECC generation. A write-back buffer is used to post corrected ECC words during read operations, so that write-back of corrected ECC words does not need to take place during the same cycle that data is read. Instead, write-back operations are performed during idle cycles when no external memory access is requested, such that the write back operation does not impose a penalty on memory cycle time or affect memory access latency.

Abstract: A vertical one-transistor, floating-body DRAM cell is fabricated by forming an isolation region in a semiconductor substrate, thereby defining a semiconductor island in the substrate. A buried source region is formed in the substrate, wherein the top/bottom interfaces of the buried source region are located above/below the bottom of the isolation region, respectively. A recessed region is etched into the isolation region, thereby exposing sidewalls of the semiconductor island, which extend below the top interface of the buried source region. A gate dielectric is formed over the exposed sidewalls, and a gate electrode is formed in the recessed region, over the gate dielectric. A drain region is formed at the upper surface of the semiconductor island region, thereby forming a floating body region between the drain region and the buried source region. Dielectric spacers are formed adjacent to the gate electrode, thereby covering exposed edges of the gate dielectric.

Abstract: A one-transistor, floating-body (1T/FB) dynamic random access memory (DRAM) cell is provided that includes a field-effect transistor fabricated using a process compatible with a standard CMOS process. The field-effect transistor includes a source region and a drain region of a first conductivity type and a floating body region of a second conductivity type, opposite the first conductivity type, located between the source region and the drain region. A buried region of the first conductivity type is located under the source region, drain region and floating body region. The buried region helps to form a depletion region, which is located between the buried region and the source region, the drain region and the floating body region. The floating body region is thereby isolated by the depletion region. A bias voltage can be applied to the buried region, thereby controlling leakage currents in the 1T/FB DRAM cell.

Abstract: A non-volatile memory cell is fabricated using a conventional logic process, with minor modifications. The cell is fabricated by forming a shallow trench isolation (STI) region in a well region of a semiconductor substrate. A recessed region is formed in the STI region, wherein the recessed region extends into the STI region and exposes a sidewall region in the well region. A capacitor region is formed in the sidewall region. A dielectric layer is formed over the well region, including the sidewall region. A gate electrode is then formed over the dielectric layer, wherein a portion of the gate electrode extends into the recessed region. An access transistor of the cell is then formed in a self-aligned manner with respect to the gate electrode. A capacitor structure is formed by the gate electrode (in the recessed region), the dielectric layer on the sidewall region, and the capacitor region.

Abstract: A memory system with transparent error correction circuitry provides full stuck-at fault coverage for both test data patterns and the corresponding error correction code (ECC) values. The memory system includes a semiconductor memory having a memory array, a memory interface and an error detection/correction unit. The memory array is configured to store test data patterns and corresponding error correction code (ECC) values. The memory interface is configured such that the ECC values are not directly accessible. The error detection/correction unit is configured to correct single-bit errors in the test data patterns and corresponding ECC values. A set of test data patterns associated with the semiconductor memory is selected such that any multiple-bit error in a test data pattern and the corresponding ECC value causes the error detection/correction unit to provide an output data pattern having an error, thereby rendering multiple-bit faults 100% detectable.

Abstract: A method and structure for implementing a DRAM memory array as a second level cache memory in a computer system. The computer system includes a central processing unit (CPU), a first level SRAM cache memory, a CPU bus coupled to the CPU, and second level cache memory which includes a DRAM array coupled to the CPU bus. When accessing the DRAM array, row access and column decoding operations are performed in a self-timed asynchronous manner. Predetermined sequences of column select operations are then performed in a synchronous manner with respect to a clock signal. A widened data path is provided to the DRAM array, effectively increasing the data rate of the DRAM array. By operating the DRAM array at a higher data rate than the CPU bus, additional time is provided for precharging the DRAM array. As a result, precharging of the DRAM array is transparent to the CPU bus.

Abstract: A non-volatile memory cell is fabricated using a conventional logic process, with minor modifications. The cell is fabricated by forming a shallow trench isolation (STI) region in a well region of a semiconductor substrate. A recessed region is formed in the STI region, wherein the recessed region extends into the STI region and exposes a sidewall region in the well region. A capacitor region is formed in the sidewall region. A dielectric layer is formed over the well region, including the sidewall region. A gate electrode is then formed over the dielectric layer, wherein a portion of the gate electrode extends into the recessed region. An access transistor of the cell is then formed in a self-aligned manner with respect to the gate electrode. A capacitor structure is formed by the gate electrode (in the recessed region), the dielectric layer on the sidewall region, and the capacitor region.

Abstract: A fault-tolerant, high-speed wafer scale system comprises a plurality of functional modules, a parallel hierarchical bus which is fault-tolerant to defects in an interconnect network, and one or more bus masters. This bus includes a plurality of bus lines segmented into sections and linked together by programmable bus switches and bus transceivers or repeaters in an interconnect network.

Abstract: A non-volatile memory (NVM) system includes a NVM cell having: a semiconductor region having a first conductivity type; a gate dielectric layer located over the semiconductor region; a gate electrode located over the gate dielectric layer; a source region and a drain region of a second conductivity type, opposite the first conductivity type, located in the semiconductor region and aligned with the gate electrode; a crown electrode having a base that contacts the gate electrode and walls that extend vertically from the base region, away from the gate electrode; a dielectric layer located over the crown electrode, wherein the dielectric layer extends over at least interior surfaces of the walls; and a plate electrode located over the dielectric layer, wherein the plate electrode extends over at least interior surfaces of the walls.

Abstract: A memory system that includes a DRAM cell that includes an access transistor and a storage capacitor. The storage capacitor is fabricated by forming a polysilicon crown electrode, a dielectric layer overlying the polysilicon crown, and a polysilicon plate electrode overlying the dielectric layer. A first set of thermal cycles are performed during the formation of the storage capacitor to form and anneal the elements of the capacitor structure. Subsequently, shallow P+ and/or N+ regions are formed by ion implantation, and metal salicide is formed. As a result, the relatively high first set of thermal cycles required to form the capacitor structure does not adversely affect the shallow P+ and N+ regions or the metal salicide. A second set of thermal cycles, which are comparable to or less than the first set of thermal cycles, are performed during the formation of the shallow regions and the metal salicide.

Abstract: Improved circuitry for connecting the memory array to a data bus allows for high speed accessing of the memory array. Sense amplifier latches are coupled to each column of memory cells. The latched sense amplifiers are coupled to decoders which, in turn, are coupled to data amplifiers. The data amplifiers are coupled to a data bus. Data being read from or written to the memory cells is via the sense amplifier latches, the decoders, and data amplifiers.

Abstract: A vertical one-transistor, floating-body DRAM cell is fabricated by forming an isolation region in a semiconductor substrate, thereby defining a semiconductor island in the substrate. A buried source region is formed in the substrate, wherein the top/bottom interfaces of the buried source region are located above/below the bottom of the isolation region, respectively. A recessed region is etched into the isolation region, thereby exposing sidewalls of the semiconductor island, which extend below the top interface of the buried source region. A gate dielectric is formed over the exposed sidewalls, and a gate electrode is formed in the recessed region, over the gate dielectric. A drain region is formed at the upper surface of the semiconductor island region, thereby forming a floating body region between the drain region and the buried source region. Dielectric spacers are formed adjacent to the gate electrode, thereby covering exposed edges of the gate dielectric.

Abstract: A memory system that includes a dynamic random access memory (DRAM) cell including an access transistor and a capacitor structure fabricated in a semiconductor substrate. The capacitor structure is fabricated by forming a cavity in a shallow trench isolation region, thereby exposing a sidewall region of the substrate below the upper surface of the substrate. A dielectric layer is formed over the upper surface and the sidewall region of the substrate. A polysilicon layer is formed over the dielectric layer and patterned to form a capacitor electrode of the capacitor structure that extends over the upper surface and the sidewall region of the substrate. The capacitor electrode is partially recessed below the upper surface of the substrate. The polysilicon layer is also patterned to form the gate electrode of the access transistor.

Abstract: A memory system includes a plurality of memory modules, each including at least one memory array. Each memory array has an associated line of sense amplifier latches, wherein each line of sense amplifier latches is activated independently. Each line of sense amplifier latches is capable of caching a row of data from the associated memory array. The capacity of each memory array and the number of memory arrays are selected such that a cache hit rate of over 90 percent is achieved for the memory system.

Abstract: A one-transistor, floating-body (1T/FB) dynamic random access memory (DRAM) cell is provided that includes a field-effect transistor fabricated using a process compatible with a standard CMOS process. The field-effect transistor includes a source region and a drain region of a first conductivity type and a floating body region of a second conductivity type, opposite the first conductivity type, located between the source region and the drain region. A buried region of the first conductivity type is located under the source region, drain region and floating body region. The buried region helps to form a depletion region, which is located between the buried region and the source region, the drain region and the floating body region. The floating body region is thereby isolated by the depletion region. A bias voltage can be applied to the buried region, thereby controlling leakage currents in the 1T/FB DRAM cell.