A method for performing a sudden power-off recovery operation of a controller controlling a memory device, the method includes: obtaining open block information for open blocks of the memory device and read counts for the open blocks; updating each of the read counts by adding a set value to each of the read counts; storing the updated read counts in the memory device; sequentially reading pages in each of the open blocks without updating the read counts for the open blocks, based on the open block information, to detect a boundary page after the storing of the updated read counts in the memory device; and controlling the memory device to program dummy data in the detected boundary page.

A solid state storage includes a non-volatile memory and a controlling circuit. The non-volatile memory includes a first block. The controlling circuit is connected with the non-volatile memory. The controlling circuit includes a function storage circuit. The function storage circuit stores plural prediction functions. According to plural state parameters corresponding to the first block and a first prediction function of the plural prediction functions, the controlling circuit predicts a read voltage shift of the first block.

A memory system and method for storing data in one or more storage chips includes: one or more memory cards each having a plurality of storage chips, and each chip having a plurality of dies having a plurality of memory cells; a memory controller comprising a translation module, the translation module further comprising: a logical to virtual translation table (LVT) having a plurality of entries, each entry in the LVT configured to map a logical address to a virtual block address (VBA), where the VBA corresponds to a group of the memory cells on the one or more memory cards, wherein each entry in the LVT further includes a write wear level count to track the number of writing operations to the VBA, and a read wear level count to track the number of read operations for the VBA mapped to that LVT entry.

An operating method of a nonvolatile memory device for programming multi-page data, the operating method including: receiving the multi-page data from a memory controller; programming first page data among the multi-page data to first memory cells connected to a word line adjacent to a selected word line; reading previous page data previously stored in second memory cells connected to the selected word line based on a first sensing value and a second sensing value after programming the first page data, calculating a first fail bit number by comparing first bits of the previous page data read based on the first sensing value to second bits of the previous page data read based on the second sensing value; and programming the previous page data read from the second memory cells and second page data among the multi-page data to the second memory cells based on the first fail bit number.

The present disclosure relates to a method for improving the reading and/or writing phase in storage devices including a plurality of non-volatile memory portions managed by a memory controller, comprising: providing at least a faster memory portion having a lower latency and higher throughput with respect to said non-volatile memory portions and being by-directionally connected to said controller; using said faster memory portion as a read and/or write cache memory for copying the content of memory regions including more frequently read or written logical blocks of said plurality of non-volatile memory portions.
A specific read cache architecture for a managed storage device is also disclosed to implement the above method.

An operating method of a nonvolatile memory device for programming multi-page data, the operating method including: receiving the multi-page data from a memory controller; programming first page data among the multi-page data to first memory cells connected to a word line adjacent to a selected word line; reading previous page data previously stored in second memory cells connected to the selected word line based on a first sensing value and a second sensing value after programming the first page data, calculating a first fail bit number by comparing first bits of the previous page data read based on the first sensing value to second bits of the previous page data read based on the second sensing value; and programming the previous page data read from the second memory cells and second page data among the multi-page data to the second memory cells based on the first fail bit number.

One or more of multiple metrics for multiple logical page types of the memory device are determined. Each of the metrics is indicative of a number of bit errors associated with a particular logical page type of the multiple logical page types. A current page margin associated with a first logical page type of the multiple logical page types is modified to determine a modified page margin based at least in part on a ratio using one or more of the multiple metrics. The current page margin associated with the first logical page type is adjusted in accordance with the modified page margin.

According to one embodiment, a memory controller of a memory system includes a command issuing unit, a decoder, a counter, and a statistical processor. The command issuing unit issues a first command for single read of first data from a nonvolatile memory. The decoder performs first error correction on the read first data. The counter counts a number of times of multiple reads. The statistical processor performs statistical processing of results of the multiple reads, and outputs second data obtained by the statistical processing. When the decoder is unable to perform the first error correction on the read first data, the command issuing unit issues a second command for multiple reads of the first data.

A method includes performing a quantity of write cycles on memory components. The method can further include monitoring codewords, and, for each of the codewords including a first error parameter value, determining a second error parameter value. The method can further include determining a probability that each of the codewords is associated with a particular one of the second error parameter values at the first error parameter value and determining a quantity of each of the codewords that are associated with each of the determined probabilities. The method can further include determining a statistical boundary of the quantity of each of the codewords and determining a correlation between the quantity of write cycles performed and the corresponding determined statistical boundary of the quantity of each of the codewords.

Devices and techniques for initiating and controlling preemptive idle time read scans in a flash based storage system are disclosed. In an example, a memory device includes a NAND memory array and a memory controller to schedule and initiate read scans among multiple locations of the memory array, with such read scans being preemptively triggered during an idle (background) state of the memory device, thus reducing host latency during read and write operations in an active (foreground) state of the memory device. In an example, the optimization technique includes scheduling a read scan operation, monitoring an active or idle state of host IO operations, and preemptively initiating the read scan operation when entering an idle state, before the read scan operation is scheduled to occur. In further examples, the read scan may preemptively occur based on time-based scheduling, frequency-based conditions, or event-driven conditions triggering the read scan.