Memory device data-access schemes are disclosed. Various embodiments may include a memory device including a first column plane, a second column plane, and a data-steering circuit. The first column plane may include a first edge, a second edge, and a first number of digit lines arranged between the first edge and the second edge. The second column plane may include a third edge positioned adjacent to the second edge, a fourth edge, and a second number of digit lines arranged between the third edge and the fourth edge. The data-steering circuit may be configured to logically relate a first digit line of the first number of digit lines to a second digit line of the second number of digit lines, the first digit line proximate to the first edge and the second digit line proximate to the fourth edge. Associated systems and methods are also disclosed.

Memory device data-access schemes are disclosed. Various embodiments may include a memory device including a first column plane, a second column plane, and a data-steering circuit. The first column plane may include a first edge, a second edge, and a first number of digit lines arranged between the first edge and the second edge. The second column plane may include a third edge positioned adjacent to the second edge, a fourth edge, and a second number of digit lines arranged between the third edge and the fourth edge. The data-steering circuit may be configured to logically relate a first digit line of the first number of digit lines to a second digit line of the second number of digit lines, the first digit line proximate to the first edge and the second digit line proximate to the fourth edge. Associated systems and methods are also disclosed.

A method for screening bad data columns in a data storage medium comprising a plurality of data columns includes: a) labeling or recording a plurality of bad data columns as bad data column group, wherein the bad data columns are selected from the data columns, and each bad data column group labels or records a position and a number of the bad data columns; b) determining whether at least one bad data column is not labeled or recorded; and c) if yes, labeling or recording any two bad data columns spaced apart by P data columns and the P data columns as one of the bad data column groups, wherein P is a positive integer.

A system, computer readable medium and a method. The method may include sending input data to a NAND flash memory unit that comprises the NAND flash memory array and instructing the NAND flash memory unit to write input data to the NAND flash memory array to provide programmed data; reading from the NAND flash memory array the programmed data to provide read data; comparing the input data and the read data to provide column errors statistics at a column resolution; and defining, by a flash memory controller, bad columns of the NAND flash memory array in response to the column error statistics.

Methods, systems, and apparatuses for redundancy in a memory array are described. A memory array may include some memory cells that are redundant to other memory cells of the array. Such redundant memory cells may be used if a another memory cell is discovered to be defective in some way; for example, after the array is fabricated and before deployment, defects in portions of the array that affect certain memory cells may be identified. Memory cells may be designated as redundant cells for numerous other memory cells of the array so that a total number of redundant cells in the array is relatively small fraction of the total number of cells of the array. A configuration of switching components may allow redundant cells to be operated in a manner that supports redundancy for numerous other cells and may limit or disturbances to neighboring cells when accessing redundancy cells.

A memory system includes a main memory array, a redundant memory array, and a content addressable memory (CAM). The CAM includes a plurality of entries, wherein each entry includes a plurality of column address bits and a plurality of maskable row address bits. When an access address for a memory operation matches an entry of the CAM, the memory system is configured to access the redundant memory array to perform the memory operation.

The present technology relates to a semiconductor memory device and a method of operating the semiconductor memory device. The semiconductor memory device includes a memory cell array including a plurality of memory blocks, which are assigned as a plurality of normal blocks, a plurality of first replacement blocks, a plurality of second replacement blocks, a first CAM block, and a second CAM block, a peripheral circuit configured to perform an erase operation and a program operation on the plurality of memory blocks, and a control logic configured to control the peripheral circuit to perform a growing bad block check operation on a target block during the program operation on a selected target block among the normal memory blocks.

A test system includes a non-volatile memory device that includes a plurality of memory blocks operating in a multi-plane mode, and a test machine that detects a bad block of the non-volatile memory device. The non-volatile memory device generates a ready/busy signal which is based on whether an erase loop for detection of the bad block progresses. When at least one normal block is detected from the plurality of memory blocks included in planes operating in the multi-plane mode, the non-volatile memory device generates the ready/busy signal having a first busy interval. When all the memory blocks included in the planes operating in the multi-plane mode are detected as bad blocks, the non-volatile memory device generates the ready/busy signal having a second busy interval shorter than the first busy interval.

A memory device includes a cell region in which memory blocks, respectively including gate electrodes and insulating layers, alternately stacked on a substrate, and channel structures, extending in a first direction, perpendicular to an upper surface of the substrate, passing through the gate electrodes and the insulating layers, and connected to the substrate, are arranged. A peripheral circuit region includes a row decoder connected to the gate electrodes and a page buffer connected to the channel structures. The memory blocks include main blocks and at least one spare block, wherein a length of the spare block is shorter than a length of each of the main blocks, in a second direction, parallel to the upper surface of the substrate.

The repair circuit is disposed in a memory including a normal memory area and a redundant memory area including a target repair unit immediately adjacent to the normal memory area, and the repair circuit being configured to control the target repair unit to repair an abnormal memory cell in the normal memory area. The repair circuit includes: a first control circuit, configured to receive signals at a target number of bits from low to high in a row address, process the received signals to obtain a control result, and output the control result, where the target number is associated with a number of Word Lines in the target repair unit; and a repair determination circuitry, connected to an output terminal of the first control circuit, and configured to receive the control result and output, in combination with the control result, a repair signal indicating whether to perform a repair operation.