A storage device includes a controller configured to control a non-volatile memory device(s) having a plurality of memory blocks therein. The controller includes secure erase control logic configured to: (i) control secure erase operations on the plurality of memory blocks in response to a secure erase request received from a host, and (ii) set flags corresponding to the plurality of memory blocks such that a first flag corresponding to a first memory block, which has undergone at least two of the secure erase operations, has a first value. Adaptive control logic is provided, which is configured to change at least one operating condition associated with a write operation and/or read operation directed at the first memory block, in response to detecting that the first flag has the first value.

A Memory management method for a storage device having a rewritable non-volatile memory module is provided. The rewritable non-volatile memory module has a plurality of physical blocks divided into a plurality of block stripes. The method includes: scanning the physical blocks to identify one or more bad physical blocks among the physical blocks; calculating a plurality of effective weight values corresponding to the block stripes according to a plurality of data accessing time parameters of the rewritable non-volatile memory module, a plurality of valid data counts, and the identified one or more bad physical blocks; and selecting a target block stripe from the block stripes according to the effective weight values to perform a garbage collection operation.

A memory device and a control method for a non-volatile memory are provided. The non-volatile memory includes a target erasing region and an unselected region. The control method includes: erasing a target memory cell in the target erasing region. The unselected region is a region, excluding the target erasing region, in the non-volatile memory. The step of erasing the target memory cell includes an erasing operation, a verification operation, and an erasing loop after failing to pass the verification operation. The number of times of performing the erasing loop is an integer greater than or equal to 0. The control method further includes: refreshing a pre-defined portion in the unselected region, wherein a capacity of the pre-defined portion is determined by the number of times of performing the erasing loop.

A controller includes an interface and a processor. The interface is configured to communicate with a nonvolatile memory including multiple memory cells organized in multiple memory blocks that each includes multiple Word Lines (WLs). The processor is configured to store first data in one or more WLs of a memory block, the first data occupies less than a maximal number of WLs available in the memory block, to calculate redundancy data over the first data and store the redundancy data in a dedicated memory, to program second data to a selected WL of the memory block that was not programmed with the first data, to check a programming status resulting from the programming of the selected WL, and in response to identifying that programming the second data to the selected WL has corrupted at least part of the first data, to recover the first data using the redundancy data.

A storage device includes storage circuitry and multiple memory cells. The memory cells are organized in multiple memory blocks of a nonvolatile memory. The storage circuitry is configured to define a partial verification scheme that specifies testing only a data portion of the data programmed to the memory blocks, to program data to a memory block, calculate redundancy data over the data, and save the calculated redundancy data in a dedicated memory, to verify that the data portion specified for the memory block in the partial verification scheme has been programmed successfully, to check a predefined condition for conditionally performing full verification to the memory block, when the predefined condition is fulfilled, to verify that data programmed to the memory block and not tested using the partial verification scheme has been programmed successfully, and to recover, using the redundancy data, at least part of the data programmed that failed verification.

The present information processing apparatus is provided with a flash memory divided into a plurality of areas based on characteristics of information to be stored therein. The present information processing apparatus detects a problem in data stored in each area using a different method for each area, and repairs the detected problem using a different method for each area.

A method of verifying the atomicity of an operation of data update in an EEPROM, includes, during a data writing operation of writing the data, the steps of: initializing at least one first flag to a first value and storing this value in the EEPROM; erasing the data from the EEPROM; writing a value of the data into the EEPROM; and writing at least one second value of the first flag into the EEPROM.

Various examples are directed to memory systems comprising a component and a processing device. The memory system may comprise a plurality of blocks. A first portion of the plurality of blocks may be retired and a second portion of the plurality of blocks may be unretired. The processing device receives a sanitize operation for the plurality of blocks. The processing device initiates a first erase cycle at a first retired block of the plurality of blocks. The processing device determines that the first erase cycle was not successful and sets an erase indicator to false.

A data storage device can detect for a failure in decoding of an x-bit row address and/or a y-bit column of an (x+y)-bit address. The data storage device decodes the x-bit row address and/or the y-bit column address to provide wordlines (WLs) and/or bitlines (BLs) to access one or more cells from among a memory array of the data storage device. The data storage device compares one or more subsets of the WLs and/or of the BLs to each other to detect for the failure. The data storage device determines the failure is present in the decoding of the x-bit row address and/or the y-bit column of the (x+y)-bit address when one or more WL and/or BL from among the one or more subsets of the WLs and/or the BLs differ.

An apparatus, such as a memory (e.g., a NAND memory), can have a controller, a volatile counter coupled to the controller, and a non-volatile memory array coupled to the controller. The controller can be configured to write information, other than a count of the counter, in the array each time the count of the counter has been incremented by a particular number of increments. Counts can be monotonic, non-volatile, and power-loss tolerant.