A memory system includes a first memory cell array which is a nonvolatile memory cell array, a controller configured to control read and write of data, a first data latch group used for input and output of the data between the controller and the first memory cell array, and at least one second data latch group in which stored data is maintained when the data is read from the first memory cell array by the controller. The controller is configured to store management information in the at least one second data latch group when or before executing a read process for the data from the first memory cell array, the management information being in a second memory cell array and used for read of the data.

The non-volatile memory includes a control circuitry that is communicatively coupled to an array of memory cells that are arranged in a plurality of word lines. The control circuitry is configured to program the memory cells of the plurality of word lines to a plurality of data states in a multi-pass programming operation. A later programming pass of the multi-pass programming operation includes a plurality of programming loops with incrementally increasing programming pulses. For at least one data state, the later programming pass includes maintaining a count of the programming loops of the later programming pass. The later programming pass also includes inhibiting or slowing programming of the memory cells being programmed to one of the data states during a predetermined program count verify (PCV) programming loop and a PCV−1 programming loop and skipping a verify operation for all programming loops prior to a PCV+1 programming loop.

The storage device includes a non-volatile memory with control circuitry and an array of memory cells that are arranged in a plurality of word lines. The control circuitry is configured to program the memory cells in a plurality of programming loops which include applying a programming pulse to a selected word line to program at least one memory cell of the selected word line to a programmed data state. The programming loops also include simultaneously applying a verify pulse to the selected word line to verify a data state being programmed, applying a first voltage to at least one unselected word line that has not been programmed, and applying a second voltage to at least one unselected word line that has already been programmed. The first voltage is determined as a function of the programmed data state to reduce a voltage threshold distribution across the memory cells.

A method of operating a semiconductor memory device includes performing a plurality of program loops for programming selected memory cells among a plurality of memory cells. Each of the plurality of program loops includes a program phase and a verify phase. The program phase includes setting a state of a select line connected to a selected memory block including the selected memory cells, wherein setting the state of the select line connected to the selected memory block comprises applying a voltage to the select line based on a program progress state of the selected memory cells, setting a state of a bit line connected to the selected memory block, applying a program voltage to a selected word line among word lines connected to the selected memory block and applying a pass voltage to an unselected word line.

A storage device is provided that applies pulsed biasing during power-up or read recovery. The storage device includes a memory and a controller. The memory includes a block having a word line and cells coupled to the word line. The controller applies a voltage pulse to the word line during power-up or in response to a read error. The voltage pulse may include an amplitude and a pulse width that are each a function of a number of PIE cycles of the block. The controller may also perform pulsed biasing during both power-up and read recovery by applying one or more first voltage pulses to the word line during power-up and one or more second voltage pulses to the word line in response to a read error. As a result, lower bit error rates due to wider Vt margins may occur and system power may be saved over constant biasing.

A method for detecting a “slow to erase” condition of a non-volatile memory structure, wherein the method comprises initiating an erase/verify memory operation with respect to the memory structure, wherein the erase/verify memory operation comprises applying an erase verify voltage according to an alternating word line scheme; following the erase/verify memory operation, determining if a first bit scan mode criteria is satisfied; and, if the first bit scan mode criteria is satisfied, initiating a read/verify memory operation wherein, the read/verify memory operation comprises applying a read-pass voltage according to an all word line scheme, and a magnitude of the read-pass voltage is greater than a magnitude of the erase verify voltage. Following the read/verify memory operation, the method also comprises determining if a second bit scan mode criteria is satisfied and, if the criteria is not satisfied, designating the memory structure with a fail status.

Apparatuses and techniques are described for reducing the number of latches used in sense circuits for a memory device. The number of internal user data latches in a sense circuit is reduced by using an external data transfer latch to store a bit of user data, in place of an internal user data latch. The user data in the data transfer latches identifies a subset of the data states which are not prohibited from having a verify test. The subset is shifted as the program operation proceeds, at specified program loops, to encompass higher data states. The completion of programming by a memory cell is indicated by the user data latches and another internal latch of the sense circuit in place of the external data transfer latch.

An operation method includes buffering data chunks to be programmed in the multi-level cells in a write buffer; backing up at least one backup data chunk of the data chunks to a backup memory; determining a program sequence of the data chunks, the program sequence for programming a non-backup data chunk among the data chunks to the multi-level cells through a second step program operation of the multi-step program operation; and controlling the memory device to program the data chunks in the multi-level cells, based on the program sequence, by performing first and second step program operations of the multi-step program operation in a first page of the multi-level cells, the second step program operation performed in the first page later than another first step program operation performed in a second page subsequent to the first page.

An apparatus is provided that includes a plurality of word lines that include a plurality of word line zones, a plurality of non-volatile memory cells coupled to the plurality of word lines, and a control circuit coupled to the non-volatile memory cells. The control circuit is configured to determine a corresponding initial program voltage for each of the word line zones. Each corresponding initial program voltage is determined based on a number of program erase cycles.

Apparatuses and techniques are described for programming data in memory cells while concurrently storing backup data. One or more initial pages of data are programmed into both a primary block and a first backup block in a first program pass. A power loss then occurs which can corrupt the data or otherwise prevent reading of the one or more initial pages of data from the primary block. The one or more initial pages of data are read from the first backup block and used to perform a second program pass in which one or more additional pages of data are programmed into the primary block. Single bit per cell data can be stored in a second backup block to decode the one or more initial pages of data as read from the first backup block.