Abstract: A method is provided for error correction of a memory. The method includes: providing a first memory and a second memory; initiating a read operation of the first memory to retrieve data; performing an error correction code (ECC) processing on the data, wherein the ECC processing for determining that at least a portion of the data is erroneous and for providing corrected data; and determining if an address of the erroneous data is stored in the second memory, if the address of the erroneous data is stored in the second memory, storing the corrected data in the second memory, and if the address of the erroneous data is not stored in the second memory, storing the address in the second memory.

Abstract: A method for refreshing a Dynamic Random Access Memory (DRAM) includes performing a refresh on at least a portion of the DRAM at a first refresh rate, and performing a refresh on a second portion of the DRAM at a second refresh rate. The second portion includes one or more rows of the DRAM which do not meet a data retention criteria at the first refresh rate, and the second refresh rate is greater than the first refresh rate.

Abstract: A testing system includes a tester probe and a plurality of integrated circuits. Tests are broadcast to the plurality of integrated circuits using carrierless ultra wideband (UWB) radio frequency (RF). All of the plurality of integrated circuits receive, at the same time, test input signals by way of carrierless UWB RF and all of the plurality of integrated circuits run tests and provide results based on the test input signals. Thus, the plurality of integrated circuits are tested simultaneously which significantly reduces test time. Also the tests are not inhibited by physical contact with the integrated circuits.

Abstract: A system has a first plurality of cores in a first coherency group. Each core transfers data in packets. The cores are directly coupled serially to form a serial path. The data packets are transferred along the serial path. The serial path is coupled at one end to a packet switch. The packet switch is coupled to a memory. The first plurality of cores and the packet switch are on an integrated circuit. The memory may or may not be on the integrated circuit. In another aspect a second plurality of cores in a second coherency group is coupled to the packet switch. The cores of the first and second pluralities may be reconfigured to form or become part of coherency groups different from the first and second coherency groups.

Abstract: A method for refreshing a Dynamic Random Access Memory (DRAM) includes performing a refresh on at least a portion of the DRAM at a first refresh rate, and performing a refresh on a second portion of the DRAM at a second refresh rate. The second portion includes one or more rows of the DRAM which do not meet a data retention criteria at the first refresh rate, and the second refresh rate is greater than the first refresh rate.

Abstract: An integrated circuit has a group of cores that communicate with a packet switch using carrierless ultra wideband (UWB) radio frequency (RF) signaling. The packet switch communicates outside the integrated circuit using optical signaling. The carrierless UWB provides for high frequency communication and processing without requiring additional space for interconnects. No special paths are necessary because the signals used by the cores for communicating with the packet switch are RF signals therefore they can be broadcast by the packet switch and be received by a plurality of cores. No conductor line or waveguide is required. Because the signals are carrierless, they can be transmitted with low power. With multiple cores providing information to the switch, the total information being received may exceed the capacity of the RF bandwidth so an external optical interface is provided to multiplex information provided via carrierless UWB RF signals by a plurality of cores.

Abstract: A method for refreshing a Dynamic Random Access Memory (DRAM) includes performing a refresh on at least a portion of the DRAM at a first refresh rate, and performing a refresh on a second portion of the DRAM at a second refresh rate. The second portion includes one or more rows of the DRAM which do not meet a data retention criteria at the first refresh rate, and the second refresh rate is greater than the first refresh rate.

Abstract: A system has a first plurality of cores in a first coherency group. Each core transfers data in packets. The cores are directly coupled serially to form a serial path. The data packets are transferred along the serial path. The serial path is coupled at one end to a packet switch. The packet switch is coupled to a memory. The first plurality of cores and the packet switch are on an integrated circuit. The memory may or may not be on the integrated circuit. In another aspect a second plurality of cores in a second coherency group is coupled to the packet switch. The cores of the first and second pluralities may be reconfigured to form or become part of coherency groups different from the first and second coherency groups.

Abstract: A system has a first plurality of cores in a first coherency group. Each core transfers data in packets. The cores are directly coupled serially to form a serial path. The data packets are transferred along the serial path. The serial path is coupled at one end to a packet switch. The packet switch is coupled to a memory. The first plurality of cores and the packet switch are on an integrated circuit. The memory may or may not be on the integrated circuit. In another aspect a second plurality of cores in a second coherency group is coupled to the packet switch. The cores of the first and second pluralities may be reconfigured to form or become part of coherency groups different from the first and second coherency groups.

Abstract: A method for refreshing a Dynamic Random Access Memory (DRAM) includes performing a refresh on at least a portion of the DRAM at a first refresh rate, and performing a refresh on a second portion of the DRAM at a second refresh rate. The second portion includes one or more rows of the DRAM which do not meet a data retention criteria at the first refresh rate, and the second refresh rate is greater than the first refresh rate.

Abstract: A method is provided for error correction of a memory. The method includes: providing a first memory and a second memory; initiating a read operation of the first memory to retrieve data; performing an error correction code (ECC) processing on the data, wherein the ECC processing for determining that at least a portion of the data is erroneous and for providing corrected data; and determining if an address of the erroneous data is stored in the second memory, if the address of the erroneous data is stored in the second memory, storing the corrected data in the second memory, and if the address of the erroneous data is not stored in the second memory, storing the address in the second memory.

Abstract: A memory includes a bit cell array including a plurality of word lines and address decode circuitry having an output to provide a predecode value. The address decode circuitry includes a first plurality of transistors having a first gate oxide thickness. The memory further includes word line driver circuitry having an input coupled to the output of the address decode circuitry and a plurality of outputs, each output coupled to a corresponding word line of the plurality of word lines. The word line driver includes a second plurality of transistors having a second gate oxide thickness greater than the first gate oxide thickness. A method of operating the memory also is provided.

Abstract: In one form a memory and method thereof has a memory array having a plurality of memory cells. A bit line precharge operation is based on a clock edge of an external clock signal. A word line is selected after the beginning of the precharge operation. A sense operation is begun after enabling the word line, where the sense operation is for sensing a logic state of a memory cell. A data bit is output from the memory array corresponding to the sensed logic state of the memory cell. In one form the bit line precharge operation further comprises the bit line precharge operation having a predetermined duration that is independent of the clock signal, and the sense operation begins a predetermined delay time after enabling the word line, the sense operation having a variable duration.

Abstract: An integrated circuit comprising a plurality of circuits is provided. The integrated circuit further comprises a plurality of power circuits, wherein each of the plurality of power circuits can supply a selected voltage to at least one of the plurality of circuits.

Abstract: A testing system includes a tester probe and a plurality of integrated circuits. Tests are broadcast to the plurality of integrated circuits using carrierless ultra wideband (UWB) radio frequency (RF). All of the plurality of integrated circuits receive, at the same time, test input signals by way of carrierless UWB RF and all of the plurality of integrated circuits run tests and provide results based on the test input signals. Thus, the plurality of integrated circuits are tested simultaneously which significantly reduces test time. Also the tests are not inhibited by physical contact with the integrated circuits.

Abstract: An integrated circuit has a group of cores that communicate with a packet switch using carrierless ultra wideband (UWB) radio frequency (RF) signaling. The packet switch communicates outside the integrated circuit using optical signaling. The carrierless UWB provides for high frequency communication and processing without requiring additional space for interconnects. No special paths are necessary because the signals used by the cores for communicating with the packet switch are RF signals therefore they can be broadcast by the packet switch and be received by a plurality of cores. No conductor line or waveguide is required. Because the signals are carrierless, they can be transmitted with low power. With multiple cores providing information to the switch, the total information being received may exceed the capacity of the RF bandwidth so an external optical interface is provided to multiplex information provided via carrierless UWB RF signals by a plurality of cores.

Abstract: A system has a first plurality of cores in a first coherency group. Each core transfers data in packets. The cores are directly coupled serially to form a serial path. The data packets are transferred along the serial path. The serial path is coupled at one end to a packet switch. The packet switch is coupled to a memory. The first plurality of cores and the packet switch are on an integrated circuit. The memory may or may not be on the integrated circuit. In another aspect a second plurality of cores in a second coherency group is coupled to the packet switch. The cores of the first and second pluralities may be reconfigured to form or become part of coherency groups different from the first and second coherency groups.

Abstract: A semiconductor topography (10) is provided which includes a semiconductor-on-insulator (SOI) substrate having a conductive line (16) arranged within an insulating layer (22) of the SOI substrate. A method for forming an SOI substrate with such a configuration includes forming a first conductive line (16) within an insulating layer (22) arranged above a wafer substrate (12) and forming a silicon layer (24) upon surfaces of the first conductive line and the insulating layer. A further method is provided which includes the formation of a transistor gate (28) upon an SOI substrate having a conductive line (16) embedded therein and implanting dopants within the semiconductor topography to form source and drain regions (30) within an upper semiconductor layer (24) of the SOI substrate such that an underside of one of the source and drain regions is in contact with the conductive line.

Abstract: A double-rate memory has an array of single word line memory cells arranged in rows and columns. The single word line memory cells provide and store data via a first port. Addressing and control circuitry is coupled to the array of single word line memory cells. The addressing and control circuitry receives an address enable signal to initiate an access of the array whereby an address is received, decoded, and corresponding data retrieved or stored. Edge detection circuitry receives a memory clock and provides the address enable signal upon each rising edge and each falling edge of the memory clock to perform two memory operations in a single cycle of the memory clock. A memory operation includes addressing the memory and storing data in the memory or retrieving and latching data from the memory. In another form a double-rate dual port memory permits two independent read/write memory accesses in a single memory cycle.

Abstract: A memory includes a bit cell array including a plurality of word lines and address decode circuitry having an output to provide a predecode value. The address decode circuitry includes a first plurality of transistors having a first gate oxide thickness. The memory further includes word line driver circuitry having an input coupled to the output of the address decode circuitry and a plurality of outputs, each output coupled to a corresponding word line of the plurality of word lines. The word line driver includes a second plurality of transistors having a second gate oxide thickness greater than the first gate oxide thickness. A method of operating the memory also is provided.