The present invention provides a method for accessing a flash memory module is disclosed, wherein the flash memory module includes at least one flash memory chip, each flash memory chip includes a plurality of block, each block is implemented by a plurality of word lines, each word line corresponds to K pages, and each word line includes a plurality of memory cells supporting a plurality of states, and the method includes the steps of: receiving data from a host device; generating dummy data; and writing the data with the dummy data to a plurality of specific blocks, wherein for each of a portion of the word lines of the specific blocks, the dummy data is written into at least one of the K pages, and the data from the host device is written into the other page(s) of the K pages.

A solid state drive management solution is provided, and includes: detecting that a usage status of a first storage space of an SSD meets a preset condition, where the first storage space works in a first mode; and enabling, based on the detection result, the first storage space to work in a second mode to obtain a second storage space, where a quantity of bits that can be stored in a cell in the first storage space is greater than a quantity of bits that can be stored in a cell in the second storage space.

Disclosed is a system that comprises a memory device and a processing device, operatively coupled with the memory device, to perform operations that include, identifying a block family comprising a plurality of blocks of the memory device. The operations performed by the processing device further include associating the block family with a threshold voltage offset. The operations performed by the processing device further include computing an adjustment value of the threshold voltage offset, wherein the adjustment value reflects a time period that has elapsed since a triggering event and a temperature of a memory component carrying one or more blocks of the plurality of blocks.

A memory device includes a memory array and control logic, operatively coupled with the memory array, to perform operations including causing a first current to be obtained with respect to cells of a wordline maintained at a first voltage, determining that the cells are at a second voltage lower than the first voltage, in response to determining that the cells are the second voltage, causing a voltage ramp down process to be initiated, causing a second current to be sampled with respect to the cells during the voltage ramp down process, and detecting an existence of charge loss by determining whether the second current satisfies a threshold condition in view of the first current.

Apparatuses and techniques are described for modifying program and erase parameters in a memory device in which memory cells can be operated in a single bit per cell (SLC) mode or a multiple bits per cell mode. In one approach, the stress on a set of memory cells in an SLC mode is reduced during programming and erasing when the number of program-erase cycles for the block in the SLC mode is below a threshold. For example, during programming, the program-verify voltage and program voltages can be reduced to provide a shallower than normal programming. During erasing, the erase-verify voltage can be increased while the erase voltages can be reduced to provide a shallower than normal erase. When the number of program-erase cycles for the block in the SLC mode is above the threshold, the program and erase parameters revert to a default levels.

An example method includes maintaining a first data structure comprising logical address to physical address mappings for managed units corresponding to a memory, and maintaining a second data structure whose entries correspond to respective physical managed unit addresses. Each entry of the second data structure comprises an activity counter field corresponding to the respective physical managed unit address and a number of additional fields indicating whether the respective physical managed unit address is in one or more of a number of additional data structures. The one or more additional data structures are accessed in association with performing at least one of a wear leveling operation on the respective physical managed unit address, and a neighbor disturb mitigation operation on physical managed unit addresses corresponding to neighbors of the respective physical managed unit address.

A memory device can dynamically select a voltage step size for programming (i.e., charging) memory cells. The memory device can increase the voltage step size to reduce programming time or decrease the voltage step size to reduce errors. The memory device can identify device conditions, such as temperature or amount of use (e.g., a count of program/erase cycles). The memory device can increase the voltage step size when the device conditions are less likely to cause errors (e.g., in a middle temperature range or below a threshold number of program/erase cycles) or can decrease the voltage step size when the device conditions are more likely to cause errors (e.g., in a high or low temperature range or above a threshold number of program/erase cycles).

The memory device includes a plurality of memory cells arranged in a plurality of blocks, which are arranged in at least one plane. A controller is in electrical communication with the plurality of memory cells. The controller is configured to define a multi-block group that includes at least two blocks to be erased. The controller is further configured to simultaneously apply at least one erase pulse to the multi-block group. The controller is further configured to individually and sequentially apply a verify pulse to the blocks. In response to all blocks passing verify, the controller is configured to complete the erase operation. In response to at least one of the blocks not passing verify, the controller is configured to individually and sequentially apply an erase pulse and then a verify pulse to the at least one block that did not pass verify.

Systems, apparatuses, and methods related to media management, including “garbage collection,” in memory or storage systems or sub-systems, such as solid state drives, are described. For example, a criticality value can be determined and used as a basis for managing a garbage collection operation on a data block. A controller or the system or sub-system may determine that a criticality value associated with performing a garbage collection operation satisfies a condition. Based on determining that the condition is satisfied, a parameter associated with performing the garbage collection operation can be adjusted. The garbage collection operation is performed on the data block stored on the memory component using the adjusted parameter.

An operating method of a storage device includes reading a wear-out pattern of a memory block when a controller determines the memory block is a re-use memory block of a non-volatile memory device; selecting an operation mode corresponding to the read wear-out pattern using the controller; and transmitting the selected operation mode to the non-volatile memory device using the controller.