Abstract: Aspects of a storage device including a memory and a controller are provided. The controller may measure an error rate of one or more blocks of the memory. In certain aspects, the controller may also estimate, based at least in part on the error rate, a time shift indicative of a duration of time for which the storage device was powered off. In some examples, the controller may also set a read level for multiple blocks of the memory, wherein the read level is determined based at least in part on the time shift.

Abstract: In some situations, a leak on a wordline may be a localized problem that causes data loss in a block that contains the wordline. In other situations, such as when the leak occurs near a peripheral wordline routing area, the leak can affect the entire memory die. The storage system provided herein has a fatal wordline leak detector that determines the type of leak and, accordingly, whether just the block should be retired or whether related blocks should be retired.

Abstract: This disclosure includes back pattern counter measures for solid state drives. Embodiments described herein include setting and applying read threshold offsets according to flags set based on an amount of data stored within a memory block (e.g., an “openness” of the block). The flag is implemented during read commands to account for shifts in voltage distribution of open blocks. A value of the flag may be chosen based on a number of word lines included in the block that store data. The read threshold offsets may further be based on at least one of the set flag or an age of a respective NAND cell.

Abstract: A data storage device includes a memory device and a controller coupled to the memory device. The memory device is arranged in a plurality of logical planes and the controller is configured to write log data and user data to separate planes within the memory device, such that the log data and user data are isolated from each other on separate planes. The controller is configured to read log data from one plane and user data on another plane simultaneously, where the log data and the user data are isolated from each other on separate planes.

Abstract: Systems and methods for managing data retention in a solid-state storage system utilizing data retention flag bytes are disclosed. A data storage device includes a non-volatile memory comprising a plurality of non-volatile memory devices and a controller configured to write data to a memory unit of the non-volatile memory array and write a data retention flag value indicating a number of bits of the written data programmed in a first of a plurality of logical states. The controller is further configured to read the data and determine a number of bits having the first of the plurality of logical states in the read data, and determine a difference between the number of bits of the written data programmed in the first logical state and the number of bits having the first logical state in the read data. The difference is used to determine data retention characteristics of the non-volatile memory.

Abstract: In some embodiments of the present invention, a data storage system includes a controller and a non-volatile memory array having a plurality of memory pages. The controller performs a method that efficiently resolves the lower page corruption problem. In one embodiment, the method selects programmed lower page(s) for which paired upper page(s) have not been programmed, reads data from those selected lower page(s), corrects the read data, and reprograms the read data into those lower page(s). Since the number of lower pages in this condition is typically low (e.g., several pages in a block with hundreds or thousands of pages), this is a much more efficient method than reprogramming the entire block. In another embodiment, a similar reprogramming method is applied as a data recovery scheme in situations in which only lower pages are programmed (e.g., SLC memory, MLC memory in SLC mode, etc.).

Abstract: Systems and methods for managing data retention in a solid-state storage system utilizing data retention flag bytes are disclosed. A data storage device includes a non-volatile memory comprising a plurality of non-volatile memory devices and a controller configured to write data to a memory unit of the non-volatile memory array and write a data retention flag value indicating a number of bits of the written data programmed in a first of a plurality of logical states. The controller is further configured to read the data and determine a number of bits having the first of the plurality of logical states in the read data, and determine a difference between the number of bits of the written data programmed in the first logical state and the number of bits having the first logical state in the read data. The difference is used to determine data retention characteristics of the non-volatile memory.

Abstract: Systems and methods are disclosed for programming data in a non-volatile memory array are disclosed. A data storage device includes a non-volatile memory array including a plurality of non-volatile memory cells and a controller configured to receive a signal indicating a temperature of at least a portion of the data storage device. The controller determines a first offset program verify level associated with a first programming level based at least in part on the temperature and programs a first set of the memory cells of the non-volatile memory array using the first offset program verify level.

Abstract: Systems and methods for managing data retention in a solid-state storage system utilizing data retention flag bytes are disclosed. A data storage device includes a non-volatile memory comprising a plurality of non-volatile memory devices and a controller configured to write data to a memory unit of the non-volatile memory array and write a data retention flag value indicating a number of bits of the written data programmed in a first of a plurality of logical states. The controller is further configured to read the data and determine a number of bits having the first of the plurality of logical states in the read data, and determine a difference between the number of bits of the written data programmed in the first logical state and the number of bits having the first logical state in the read data. The difference is used to determine data retention characteristics of the non-volatile memory.

Abstract: Systems and methods for data retention manager in a solid state storage system utilizing temperature measurement mechanisms are disclosed. Background data scanning can provide an efficient way to monitor data health and can be used to determine whether data refreshing is needed or to prevent data retention from degrading beyond error correction capabilities. In certain embodiments, data scanning may be performed as a background process regularly, for example, every month. However, effects of temperature on data retention may not be adequately accounted for using such methods. Certain embodiments disclosed herein provide a numerical integral method for taking account the system temperature by using the acceleration factor for data retention. Embodiments disclosed herein may provide for accurate handling of data retention in view of complex device temperature history.

Abstract: A non-volatile storage system includes a plurality of non-volatile storage elements arranged in two dimensional or three dimensional structures. The system applies programming to the non-volatile storage elements and performs verification of the programming. The verification includes performing a multi-strobe sensing operation to test for multiple data states while applying a common word line voltage.

Abstract: A non-volatile storage system includes a plurality of non-volatile storage elements arranged in two dimensional or three dimensional structures. The system applies programming to the non-volatile storage elements and performs verification of the programming. The verification includes performing a multi-strobe sensing operation to test for multiple data states while applying a common word line voltage.

Abstract: Systems and methods are disclosed for programming data in a non-volatile memory array are disclosed. A data storage device includes a non-volatile memory array including a plurality of non-volatile memory cells and a controller configured to receive a signal indicating a temperature of at least a portion of the data storage device. The controller determines a first offset program verify level associated with a first programming level based at least in part on the temperature and programs a first set of the memory cells of the non-volatile memory array using the first offset program verify level.

Abstract: Systems and methods for managing data retention in a solid-state storage system utilizing data retention flag bytes are disclosed. A data storage device includes a non-volatile memory comprising a plurality of non-volatile memory devices and a controller configured to write data to a memory unit of the non-volatile memory array and write a data retention flag value indicating a number of bits of the written data programmed in a first of a plurality of logical states. The controller is further configured to read the data and determine a number of bits having the first of the plurality of logical states in the read data, and determine a difference between the number of bits of the written data programmed in the first logical state and the number of bits having the first logical state in the read data. The difference is used to determine data retention characteristics of the non-volatile memory.

Abstract: An erase operation for a memory cells in a block provides a consistent and sufficient erase depth regardless of the number of programmed word lines in the block. A lower erase-verify voltage is used for a first-programmed word line of a set of word lines than for remaining word lines in the set. As a result, the resistance of a memory cell of the first-programmed word line dominates during sensing of the NAND string so that the number of erase loops can be controlled in a predictable way regardless of the number of programmed word lines. The lower erase-verify voltage can be optimized so that it does not change the number of erase loops to complete an erase operation, compared to the case where a common erase-verify voltage is used on all word lines.

Abstract: Programming techniques for a three-dimensional stacked memory device provide compensation for different intrinsic programming speeds of different groups of memory cells based on the groups' locations relative to the edge of a word line layer. A larger distance from the edge is associated with a faster programming speed. In one approach, the programming speeds are equalized by elevating a bit line voltage for the faster programming memory cells. Offset verify voltages which trigger a slow programming mode by elevating the bit line voltage can also be set based on the group locations. A programming speed can be measured during programming for a row or other group of cells to set the bit line voltage and/or the offset verify voltages. The compensation for the faster programming memory cells can also be based on their speed relative to the slower programming memory cells.

Abstract: Systems and methods are disclosed for programming data in a non-volatile memory array are disclosed. A data storage device includes a non-volatile memory array including a plurality of non-volatile memory cells and a controller configured to receive a signal indicating a temperature of at least a portion of the data storage device. The controller determines a first offset program verify level associated with a first programming level based at least in part on the temperature and programs a first set of the memory cells of the non-volatile memory array using the first offset program verify level.

Abstract: Systems and methods for managing data retention in a solid-state storage system utilizing data retention flag bytes are disclosed. A data storage device includes a non-volatile memory comprising a plurality of non-volatile memory devices and a controller configured to write data to a memory unit of the non-volatile memory array and write a data retention flag value indicating a number of bits of the written data programmed in a first of a plurality of logical states. The controller is further configured to read the data and determine a number of bits having the first of the plurality of logical states in the read data, and determine a difference between the number of bits of the written data programmed in the first logical state and the number of bits having the first logical state in the read data. The difference is used to determine data retention characteristics of the non-volatile memory.

Abstract: Systems and methods for data retention manager in a solid state storage system utilizing temperature measurement mechanisms are disclosed. Background data scanning can provide an efficient way to monitor data health and can be used to determine whether data refreshing is needed or to prevent data retention from degrading beyond error correction capabilities. In certain embodiments, data scanning may be performed as a background process regularly, for example, every month. However, effects of temperature on data retention may not be adequately accounted for using such methods. Certain embodiments disclosed herein provide a numerical integral method for taking account the system temperature by using the acceleration factor for data retention. Embodiments disclosed herein may provide for accurate handling of data retention in view of complex device temperature history.

Abstract: Systems and methods for data retention manager in a solid state storage system utilizing temperature measurement mechanisms are disclosed. Background data scanning can provide an efficient way to monitor data health and can be used to determine whether data refreshing is needed or to prevent data retention from degrading beyond error correction capabilities. In certain embodiments, data scanning may be performed as a background process regularly, for example, every month. However, effects of temperature on data retention may not be adequately accounted for using such methods. Certain embodiments disclosed herein provide a numerical integral method for taking account the system temperature by using the acceleration factor for data retention. Embodiments disclosed herein may provide for accurate handling of data retention in view of complex device temperature history.