Efficient data path architecture for flash devices requiring multi-pass programming utilizes an external memory as an intermediate buffer to store the encoded data used for a first pass programming of the flash device. The stored encoded data can be read from the external memory for subsequent passes programming instead of fetching the data from an on-chip memory, which stores the data received from a host system. Thus, the on-chip memory can be made available to speed up the next data transfer from the host system.

According to one embodiment, a memory system includes first and second memory chips. The first memory chip has a first plane with a first block and a second block and a second plane with a third block and a fourth block. The second memory chip has a third plane with a fifth block and a sixth block and a fourth plane with a seventh block and an eighth block. The memory controller sets the first and third blocks as a first block unit in a user data storage area and the fifth and seventh blocks as a second block unit in the user data storage area. The memory controller allocates the second block, the fourth block, the sixth block, and the eighth block to a management data storage area. The memory controller manages user data operations for accessing the user data storage area in block units.

A command to program data to a memory device is received. Target charge levels of a set of memory cells in the memory device for a first programming step are determined based on the data. A first set of indicators are provided to the memory device. The first set of indicators indicate the target charge levels for the first programming step. Target charge levels of the set of memory cells for a second programming step are determined based on the data. A second set of indicators are provided to the memory device. The second set of indicators indicate the target charge levels for the second programming step.

Memories and methods for programming memories with multi-step programming pulses are provided. One method includes applying a plurality of programming pulses to cells of the memory device to be programmed, with each programming pulse of the plurality of programming pulses being configured to contribute towards programming a cell of the plurality of cells to each data state of a plurality of programmed data states. A first portion of each programming pulse is used to program certain cells towards a target data state associated with a first threshold voltage level, and a later portion of each programming pulse is used to program other cells towards a target data state associated with a second threshold voltage level that is lower than the first threshold voltage level.

A semiconductor memory device includes a memory cell array including a block of memory cells, gates of which are connected to a plurality of word lines, and a control unit configured to perform a writing operation in response to a command received from the outside, the writing operation including applying a program level voltage to at least two word lines at the same time.

Aspects of a storage device including a plurality of dies and a controller are provided which allow for asymmetric die operation handling so that controller overheads associated with common resource intensive operations may be incurred in the background without delaying subsequent die operations. When the controller receives a command to perform an MLC operation such as programming a number of dies, the controller refrains from performing the MLC operation in one or more of the dies for a period of time while simultaneously performing the MLC operation in a remainder of the dies. Instead, the controller performs another operation, such as an SLC operation, another MLC operation, or a transfer operation, that involves a common resource in these dies during the period of time. Controller overheads associated with these other operations thus are incurred without creating bottlenecks when the number of dies is large, thereby improving storage device performance.

Aspects of the present disclosure are directed to magnetic tunnel junction (MTJ) structures comprising multiple MTJ bits connected in series. For example, a magnetic tunnel junction (MTJ) stack according to the present disclosure may include at least a first MTJ bit and a second MTJ bit stacked above the first MTJ bit, and a resistance state of the MTJ stack may be read by passing a single read current through both the first MTJ bit and the second MTJ bit.

The present technology includes a memory device which includes a plurality of planes in which data is stored, a peripheral circuit configured to perform operations on the plurality of planes, micro-control circuits configured to control the peripheral circuit so that the operations on the plurality of planes are independently performed, and a memory manager including a control memory in which different control codes for controlling the peripheral circuit are stored, and configured to output the control codes to the micro-control circuits, wherein the memory manager is configured to sequentially output a selected control code among the control codes to the micro-control circuits respectively corresponding to the planes.

Apparatuses, systems, and methods are disclosed for concurrently programming non-volatile storage cells, such as those of an SLC NAND array. The non-volatile storage cells may be arranged into a first block comprising a first string of storage cells that intersects with a first word line at a first storage cell, a second block comprising a second string of storage cells that intersects with a second word line at a second storage cell, a bit line electrically connectable to the first string and the second string, and controller configured to apply a programming pulse, at an elevated voltage, to the first word line and second word line to concurrently program the first and second storage cells.

A semiconductor storage device includes a first memory die. The first memory die includes a first memory plane including a plurality of first memory blocks, a second memory plane including a plurality of second memory blocks, a first sequencer, and a second sequencer. The first sequencer is configured to start a first write sequence with respect to one of the first memory blocks in response to a first command set designating the one of the first memory blocks if no write sequence is being performed by the first sequencer. The second sequencer is configured to start a second write sequence with respect to one of the second memory blocks in response to a second command set designating the one of the second memory blocks if the first sequencer is performing the first write sequence and no write sequence is being performed by the second sequencer.