Methods for providing redundancy in a memory include mapping a portion of first data associated with an address of the memory determined to indicate a defective memory cell to an address of a redundant area of the memory array, and writing second data to the memory array, wherein a portion of the second data is written to a column of the memory array associated with the address of the memory determined to indicate a defective memory cell for the first data.

Methods, systems, and devices for modifiable repair solutions for a memory array are described to support storing repair information for a memory array within the memory array itself. A memory device may include the memory array and an on-die microprocessor, where the microprocessor may retrieve the repair information from the memory array and write the repair information to repair circuitry used for identifying defective memory addresses. The microprocessor may support techniques for identifying additional defects and updating the repair information during operation of the memory array. For example, the microprocessor may identify additional defects based on errors associated with one or more memory cells of the memory array or based on testing performed on one or more memory cells of the memory array. In some cases, a host device may identify additional defects and may notify the microprocessor of the additional defects.

Methods, systems, and devices for modifiable repair solutions for a memory array are described to support storing repair information for a memory array within the memory array itself. A memory device may include the memory array and an on-die microprocessor, where the microprocessor may retrieve the repair information from the memory array and write the repair information to repair circuitry used for identifying defective memory addresses. The microprocessor may support techniques for identifying additional defects and updating the repair information during operation of the memory array. For example, the microprocessor may identify additional defects based on errors associated with one or more memory cells of the memory array or based on testing performed on one or more memory cells of the memory array. In some cases, a host device may identify additional defects and may notify the microprocessor of the additional defects.

A DRAM device with embedded flash memory for redundancy is disclosed. The DRAM device includes a substrate having a DRAM array area and a peripheral area. The peripheral area includes an embedded flash forming region and a first transistor forming region. DRAM cells are disposed within the DRAM array area. Flash memory is disposed in the embedded flash forming region. The flash memory includes an ONO storage structure and a flash memory gate structure. A first transistor is disposed in the first transistor forming region.

Methods for providing redundancy in a memory include mapping a portion of first data associated with an address of the memory determined to indicate a defective memory cell to an address of a redundant area of the memory array, and writing second data to the memory array, wherein a portion of the second data is written to a column of the memory array associated with the address of the memory determined to indicate a defective memory cell for the first data. Apparatus include memory control circuitry configured to select a portion of data for mapping to a different address in response to an address indicating a defective memory cell, and further configured to select a different portion of data for a particular row than for a different row, wherein the particular row and the different row are associated with the same columns of the memory array.

A DRAM device with embedded flash memory for redundancy is disclosed. The DRAM device includes a substrate having a DRAM array area and a peripheral area. The peripheral area includes an embedded flash forming region and a first transistor forming region. DRAM cells are disposed within the DRAM array area. Flash memory is disposed in the embedded flash forming region. The flash memory includes an ONO storage structure and a flash memory gate structure. A first transistor is disposed in the first transistor forming region.

A DRAM device with embedded flash memory for redundancy is disclosed. The DRAM device includes a substrate having a DRAM array area and a peripheral area. The peripheral area includes an embedded flash forming region and a first transistor forming region. DRAM cells are disposed within the DRAM array area. Flash memory is disposed in the embedded flash forming region. The flash memory includes an ONO storage structure and a flash memory gate structure. A first transistor is disposed in the first transistor forming region.

A DRAM device with embedded flash memory for redundancy is disclosed. The DRAM device includes a substrate having a DRAM array area and a peripheral area. The peripheral area includes an embedded flash forming region and a first transistor forming region. DRAM cells are disposed within the DRAM array area. Flash memory is disposed in the embedded flash forming region. The flash memory includes an ONO storage structure and a flash memory gate structure. A first transistor is disposed in the first transistor forming region.

Methods for providing redundancy in a memory include mapping a portion of first data associated with an address of the memory determined to indicate a defective memory cell to an address of a redundant area of the memory array, and writing second data to the memory array, wherein a portion of the second data is written to a column of the memory array associated with the address of the memory determined to indicate a defective memory cell for the first data. Apparatus include memory control circuitry configured to select a portion of data for mapping to a different address in response to an address indicating a defective memory cell, and further configured to select a different portion of data for a particular row than for a different row, wherein the particular row and the different row are associated with the same columns of the memory array.

The semiconductor memory device includes a memory cell array including a first plurality of normal memory cells and a second plurality of dummy memory cells in a stacked configuration over a substrate, a first plurality of normal word lines electrically coupled to the first plurality of normal memory cells, and a second plurality of dummy word lines electrically coupled to the second plurality of dummy memory cells, wherein the first plurality of normal memory cells includes at least one bad memory cell and each of the at least one bad memory cells are is replaced with a dummy memory cell from among the second plurality of dummy memory cells.