Abstract: Apparatus and methods are disclosed, such as those involving array/port consolidation and/or swapping. One such apparatus includes a plurality of port pads including a plurality of contacts; a plurality of memory arrays; and a plurality of master data lines. Each of the master data lines extends in a space between one of the port pads and a respective one of the memory arrays. Each of the master data lines is electrically connectable to the contacts of a respective one of the port pads. The apparatus further includes a plurality of local data lines, each of which extends over a respective one of the memory arrays. Each of the local data lines is electrically connectable to a respective one of the master data lines. At least one of the local data lines extends over at least two of the memory arrays. This configuration allows memory array consolidation and/or swapping without increasing die space for additional routing and adversely affecting performance of the apparatus.

Abstract: Apparatus and methods are disclosed, such as those involving array/port consolidation and/or swapping. One such apparatus includes a plurality of port pads including a plurality of contacts; a plurality of memory arrays; and a plurality of master data lines. Each of the master data lines extends in a space between one of the port pads and a respective one of the memory arrays. Each of the master data lines is electrically connectable to the contacts of a respective one of the port pads. The apparatus further includes a plurality of local data lines, each of which extends over a respective one of the memory arrays. Each of the local data lines is electrically connectable to a respective one of the master data lines. At least one of the local data lines extends over at least two of the memory arrays. This configuration allows memory array consolidation and/or swapping without increasing die space for additional routing and adversely affecting performance of the apparatus.

Abstract: Apparatus and methods are disclosed, such as those involving array/port consolidation and/or swapping. One such apparatus includes a plurality of port pads including a plurality of contacts; a plurality of memory arrays; and a plurality of master data lines. Each of the master data lines extends in a space between one of the port pads and a respective one of the memory arrays. Each of the master data lines is electrically connectable to the contacts of a respective one of the port pads. The apparatus further includes a plurality of local data lines, each of which extends over a respective one of the memory arrays. Each of the local data lines is electrically connectable to a respective one of the master data lines. At least one of the local data lines extends over at least two of the memory arrays. This configuration allows memory array consolidation and/or swapping without increasing die space for additional routing and adversely affecting performance of the apparatus.

Abstract: Apparatus and methods are disclosed, such as those involving array/port consolidation and/or swapping. One such apparatus includes a plurality of port pads including a plurality of contacts; a plurality of memory arrays; and a plurality of master data lines. Each of the master data lines extends in a space between one of the port pads and a respective one of the memory arrays. Each of the master data lines is electrically connectable to the contacts of a respective one of the port pads. The apparatus further includes a plurality of local data lines, each of which extends over a respective one of the memory arrays. Each of the local data lines is electrically connectable to a respective one of the master data lines. At least one of the local data lines extends over at least two of the memory arrays. This configuration allows memory array consolidation and/or swapping without increasing die space for additional routing and adversely affecting performance of the apparatus.

Abstract: A memory device includes an ECC and test circuit. In a normal mode, the circuit performs ECC conventional functions. In a test mode, the least significant bit of received data is used to generate test data. If the received bit is “0,” the test data bits are all “0,” and if the received bit is “1,” the test data bits are all “1.” The test data bits are applied to the ECC encoder that is used in normal operation. The ECC encoder is designed so that it generates ECC bits that have the same logic level as the test data bits. The test data bits and ECC bits are then written to a memory array and subsequently read. During the test mode, a logic circuit determines if the read data and check bits are all either “0” or “1” and outputs a corresponding test result bit from the memory device.

Abstract: A memory device includes an ECC and test circuit. In a normal mode, the circuit performs ECC conventional functions. In a test mode, the least significant bit of received data is used to generate test data. If the received bit is “0,” the test data bits are all “0,” and if the received bit is “1,” the test data bits are all “1.” The test data bits are applied to the ECC encoder that is used in normal operation. The ECC encoder is designed so that it generates ECC bits that have the same logic level as the test data bits. The test data bits and ECC bits are then written to a memory array and subsequently read. During the test mode, a logic circuit determines if the read data and check bits are all either “0” or “1” and outputs a corresponding test result bit from the memory device.

Abstract: A method and corresponding architecture are disclosed for sharing redundant rows between banks of a memory array. The architecture is such that sub-arrays associated with different banks are alternated and coupled via a sense amp. In addition, sub-arrays belonging to the same bank are coupled via a single row decoder. This architecture allows for adjacent sub-arrays belonging to different banks to share redundant rows, thereby effectively doubling the number of redundant rows available for use in a given bank.