The invention relates to a method for operating a memory assembly. A physical address is received. The physical address is associated with a first memory segment of a memory assembly. The physical address is modified to a modified physical address. The modified physical address is associated with a second memory segment of the memory assembly.

A logical-to-physical (L2P) data structure and a physical-to-logical (P2L) data structure are maintained. The L2P data structure comprises table entries that map a logical address to a physical address. The P2L data structure comprises data entries that map a physical address to a logical address. The P2L data entries also comprise a data move status, a base address, and a boundary indicator. A move operation is detected, wherein the move operation indicates that data referenced by a logical address is to be moved from a source physical address to a destination physical address. Responsive to detecting the move operation, the data move status associated with the source physical address in the P2L data structure is updated.

A non-volatile memory includes a plurality of physical blocks each including a respective plurality of cells, where each cell is individually capable of storing multiple bits of data. A controller for the non-volatile memory maintains dynamically resizable pools of physical blocks, including at least a low-density pool of physical blocks in which cells are configured to store a fewer number of bits and a high-density pool of physical blocks in which cells are configured to store a greater number of bits. The controller detects an imbalance in utilization between the low-density and high-density pools and, based on detection of the pool imbalance, restricts data placement in the low-density pool, enables garbage collection from the low-density pool back into the low-density pool to compact the low-density pool, and re-enables data placement to the low-density pool based on availability of a threshold number of free physical blocks in the low-density pool.

A storage device includes a non-volatile memory device including a first memory region and a second memory region, memory cells of the first memory region being at different levels from memory cells of the second memory region and a controller configured to control a base data protection operation against a rework for a reflow process by including a first operation of migrating base data stored in the first memory region to the second memory region before the rework for a first reflow process and a second operation of restoring the base data from the second memory region to the first memory region after completing the rework for the reflow process. The controller is configured to provide, to a host, management information including at least one of first information on a current state in a base data protection operation against the rework, second information on the first memory region, and third information on the second memory region.

Memory devices and methods of operating memory devices in which maintenance operations can be scheduled on an as-needed basis for those memory portions where activity (e.g., operations in excess of a predetermined threshold) warrants a maintenance operation are disclosed. In one embodiment, an apparatus comprises a memory including a memory location, and circuitry configured to determine a count corresponding to a number of operations at the memory location, to schedule a maintenance operation for the memory location in response to the count exceeding a first predetermined threshold, and to decrease the count by an amount corresponding to the first predetermined threshold in response to executing the scheduled maintenance operation. The circuitry may be further configured to disallow, in response to determining that the count has reached a maximum permitted value, further operations at the memory location until after the count has been decreased.

Methods, systems, and devices associated with techniques for secure writes by non-privileged users are described. A memory device may be configured with one or more blocks of memory operating in a secure write mode. The memory device may receive an append command from a non-privileged user. The append command may indicate data to write to the block of memory at an address determined by the memory device. The memory device may identify a pointer to the address for storing the data within the block of memory. The memory device may write the data to a portion of the block of memory based on identifying the pointer and may update the pointer associated with the block of memory based on writing the data.

A memory device includes: a memory array used for implementing neural networks (NN); and a controller coupled to the memory array. The controller is configured for: in updating and writing unrewritable data into the memory array in a training phase, marching the unrewritable data into a buffer zone of the memory array; and in updating and writing rewritable data into the memory array in the training phase, marching the rewritable data by skipping the buffer zone.

Disclosed is a system including a memory device having a plurality of physical memory blocks and associated with a logical address space that comprises a plurality of zones, wherein each zone comprises a plurality of logical block addresses (LBAs), and a processing device, operatively coupled with the memory device, to perform operations of receiving a request to store data referenced by an LBA associated with a first zone of the plurality of zones, obtaining a version identifier of the first zone, obtaining erase values for a plurality of available physical memory blocks of the memory device, selecting, in view of the version identifier of the first zone and the erase values, a first physical memory block of the plurality of available physical memory blocks, mapping a next available LBA within the first zone to the first physical memory block, and storing the data in the first physical memory block.

Methods, systems, and devices related to domain-based access in a memory device are described. In one example, a memory device in accordance with the described techniques may include a memory array, a sense amplifier array, and a signal development cache configured to store signals (e.g., cache signals, signal states) associated with logic states (e.g., memory states) that may be stored at the memory array (e.g., according to various read or write operations). The memory array may be organized according to domains, which may refer to various configurations or collections of access lines, and selections thereof, of different portions of the memory array. In various examples, a memory device may determine a plurality of domains for a received access command, or an order for accessing a plurality of domains for a received access command, or combinations thereof, based on an availability of the signal development cache.

Systems and methods for adapting garbage collection (GC) operations in a memory device to an estimated device age are discussed. An exemplary memory device includes a memory controller to track an actual device age, determine a device wear metric using a physical write count and total writes over an expected lifetime of the memory device, estimate a wear-indicated device age, and adjust an amount of memory space to be freed by a GC operation according to the wear-indicated device age relative to the actual device age. The memory controller can also dynamically reallocate a portion of the memory cells between a single level cell (SLC) cache and a multi-level cell (MLC) storage according to the wear-indicated device age relative to the actual device age.