Memory devices, systems including memory devices, and methods of operating memory devices in which redundancy match is disabled to permit activating more word lines in parallel during refresh operations to increase a refresh rate of memory cells in a memory array. In one embodiment, a memory device is provided, comprising a memory array including a plurality of word lines arranged in a plurality of memory banks. The memory device further comprises circuitry configured to (i) store a value indicating one or more addresses corresponding to word lines in the plurality of word lines, (ii) disable redundancy match, (iii) activate one or more first word lines in the memory array corresponding to the one or more addresses indicated by the value to refresh first data stored in the memory array, and (iv) update the value based at least in part on activating the one or more first word lines.

In some examples, a defective memory cell detection circuitry is configured to provide a failure signal indicative of a failure of a sub-group of memory cells (e.g., a row of memory cells). The failure signal is generated responsive to the failure of a sense line to transition to one of a set of reference voltages within a threshold time from a memory command. In some examples, failure signals indicative of a failure of a sub-group of memory cells is used by vehicle computer control systems to operate a vehicle.

Apparatuses, systems, and methods are disclosed for skip inconsistency correction. A skip circuit is configured to skip memory units for read operations and write operations of a memory array, based on a record of memory units identified as faulty. A skip inconsistency detection circuit is configured to detect a skip inconsistency in read data from a memory array. A correction circuit is configured to correct a skip inconsistency and output corrected read data.

An apparatus includes a first word line, a second word line and a control. The second word line is contiguous to the first word line. The control circuit includes a first defective address storing circuit and a first detection circuit. The first defective address storing circuit stores first enable information along with first defective address. The first enable information indicates whether or not the second word line is functional. The first detection circuit provides a first signal when the first word line is accessed. The first signal indicates whether or not the second word line is functional. The control circuit activates the second word line when the first signal indicates that the second word line is functional and does not activate the second word line when the first signal indicates that the second word line is not functional.

An apparatus includes a first word line, a second word line and a control. The second word line is contiguous to the first word line. The control circuit includes a first defective address storing circuit and a fast detection circuit. The first defective address storing circuit stores first enable information along with first defective address. The first enable information indicates whether or not the second word line is functional. The first detection circuit provides a first signal when the first word line is accessed. The first signal indicates whether or not the second word line is functional. The control circuit activates the second word line when the first signal indicates that the second word line is functional and does not activate the second word line when the first signal indicates that the second word line is not functional.

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.

Apparatuses, systems, and methods are disclosed for skip inconsistency correction. A skip circuit is configured to skip memory units for read operations and write operations of a memory array, based on a record of memory units identified as faulty. A skip inconsistency detection circuit is configured to detect a skip inconsistency in read data from a memory array. A correction circuit is configured to correct a skip inconsistency and output corrected read data.

A data storage device may include: a storage configured as a group of a plurality of memory blocks; and a controller configured to: control data input/output of the storage according to a request transferred from a host device; configure one or more first block groups by grouping a preset number of memory blocks which are selected at the same time among the memory blocks during an operation of the storage; configure one or more second block groups by replacing a bad memory block of the respective first block groups with a spare memory block; manage as a special block group a second block group where the spare memory block having replaced the bad memory block is not present in the same plane of the bad memory block, among the second block groups; and write data having a preset property to the special block group.

Examples of defective memory cell detection circuitry are described herein. Defective memory cell detection circuitry may provide a failure signal indicative of a failure of a sub-group of memory cells (e.g., a row of memory cells). The failure signal may be generated responsive to the failure of a sense line to transition to one of a set of reference voltages within a threshold time from a memory command. Failure signals indicative of a failure of a sub-group of memory cells may be used by vehicle computer control systems to improve performance and/or reliability of vehicle operations.

A memory subsystem includes memory devices with space dynamically allocated for improvement of reliability, availability, and serviceability (RAS) in the system. Error checking and correction (ECC) logic detects an error in all or a portion of a memory device. In response to error detection, the system can dynamically perform one or more of: allocate active memory device space for sparing to spare a failed memory segment; write a poison pattern into a failed cacheline to mark it as failed; perform permanent fault detection (PFD) and adjust application of ECC based on PFD detection; or, spare only a portion of a device and leave another portion active, including adjusting ECC based on the spared portion. The error detection can be based on bits of an ECC device, and error correction based on those bits and additional bits stored on the data devices.