Embodiments of the present disclosure relate to physical secure erase (PSE) of solid state drives (SSDs). One embodiment of a method of PSE of a SSD includes receiving a PSE command, erasing the memory cells of the blocks, programming the memory cells, and programming the select gates to a portion of the blocks. One embodiment of a SSD includes a controller and a plurality of blocks having a plurality of NAND strings. Each NAND string includes connected in series a select gate drain, memory cells, and a select gate source. The SSD includes a memory erasing instruction that cause the controller to erase the memory cells of the block, program the memory cells, and increase the threshold voltage to the select gate drain and/or the select gate source of some of the NAND strings from the blocks.

A memory device and a memory peripheral circuit are provided. The memory peripheral circuit includes a redundancy column data circuit and a column selection control circuit. The redundancy column data circuit is configured to provide a redundancy test mode data signal and a column address signal. The column address signal includes a redundancy column address signal. The column selection control circuit includes a column decoder and a redundancy column decoder. The column decoder disables a bad column address of a main memory block according to the redundancy test mode data signal and the redundancy column address signal. The redundancy column decoder latches the redundancy column address signal, compares the column address signal with the latched redundancy column address to obtain a comparison result, and enables a redundancy column address of a redundancy memory block according to the comparison result.

A memory system includes: a memory device including a plurality of pages; and a controller suitable for generating a read descriptor in response to an entered command, reading and outputting read data stored in at least one page in response to the read descriptor, determining whether each per-page data of the read data includes an error, storing indicators for showing whether each per-page data includes the error, re-reading some of the read data on per-page basis, based on the indicators, without generating another read descriptor, and updating the indicators based on an error check result after the re-reading.

The present disclosure includes methods and apparatuses for read cache memory. One apparatus includes a read cache memory apparatus comprising a first DRAM array, a first and a second NAND array, and a controller configured to manage movement of data between the DRAM array and the first NAND array, and between the first NAND array and the second NAND array.

A data writing method, a memory control circuit unit, and a memory storage device are provided. The method includes: determining whether to use a first programming mode or a second programming mode to program memory cells according to a first data amount and a second data amount; when the first data amount is greater than the second data amount, programming the memory cells by using the first programming mode; and when the first data amount is not greater than the second data amount, programming the memory cells by using the second programming mode.

This disclosure relates to testing of integrated artificial intelligence (AI) circuit with embedded memory to improve effective chip yield and to mapping addressable memory segments of the embedded memory to multilayer AI networks at the network level, layer level, parameter level, and bit level based on bit error rate (BER) of the addressable memory segments. The disclosed methods and systems allows for deployment of one or more multilayer AI networks in an AI circuit with sufficient model accuracy even when the embedded memory has an overall BER higher than a preferred overall threshold.

A data writing method, a memory control circuit unit and a memory storage device are provided. The method includes: executing a first programming operation to data according to a first RAID ECC rate, programming the data into at least a portion of a plurality of first physical programming units, and generating a first RAID ECC; and executing a second programming operation to the data programmed into at least the portion of the first physical programming units according to a second RAID ECC rate, programming the data into at least a portion of a plurality of second physical programming units, and generating a second RAID ECC, wherein the first RAID ECC rate is different from the second RAID ECC rate.

A memory system and a data processing system including the memory system may manage a plurality of memory devices. For example, the data processing system may categorize and analyze error information from the memory devices, acquire characteristic data from the memory devices and set operation modes of the memory devices based on the characteristic data, allocate the memory devices to a host workload, detect a defective memory device among the memory devices and efficiently recover the defective memory device.

Memory devices and methods of repairing a memory are provided. A first array includes normal memory cells, and a second array includes repair memory cells. The repair memory cells are configured to be used in place of the normal memory cells. A look-up table comprises memory bitcells configured to store a set of entries including addresses of defective memory cells of the normal memory cells. A match circuit is configured to evaluate whether an input memory address is stored as a defective address in the memory bitcells. The match circuit is also configured to generate a selection signal for selecting the normal memory cells or the repair memory cells based on the evaluation.

Preparing a key block in a memory system. Various methods include: selecting a candidate key block of memory; checking a quality of the candidate key block using a word line of the candidate key block; altering operating parameters of the candidate key memory block; and registering the candidate key memory block as the key block. Where altering the operating parameters includes replacing a first set of parameters associated with the first memory block with a second set of parameters, where the first set of parameters includes a first erase parameter, a first program parameter, and a first read parameter, where the memory block operating in a normal block mode is accessed using the first set of parameters, and the second set of parameters includes a second erase parameter, a second program parameter, and a second read parameter, where the first memory block is accessed using the second set of parameters.