Apparatus including an array of memory cells and a controller configured to program all memory cells of a grouping of memory cells that are to be respectively programmed to different levels other than a lowest level, corresponding to a lowest data state, to an intermediate level from the lowest level, and to respectively program all the memory cells of the grouping of memory cells that are to be respectively programmed to the different levels other than the lowest level to the different levels other than the lowest level from the intermediate level.

According to one embodiment, a semiconductor storage device includes a first plane having a first plurality of memory cells, a second plane having a second plurality of memory cells, first bit lines which are connected to the first plane, second bit lines which are connected to the second plane, a plurality of first sense amplifiers which charge the plurality of first bit lines, and a plurality of second sense amplifiers which charge the plurality of second bit lines. When the first and second planes operate in parallel, a total sum of currents supplied to the plurality of first bit lines from the plurality of first sense amplifiers and currents supplied to the plurality of second bit lines from the plurality of second sense amplifiers reaches a first current value, then decreases to a second current value, and then increases to a third current value.

In a method for operating a semiconductor device, the method may include: sorting program states of a memory cell that stores multi-bit data into a plurality of groups; applying different bias voltages to bit lines corresponding to a selected group among the plurality of groups; applying a program voltage to a selected word line corresponding to the selected group; verifying whether each of selected memory cells corresponding to the selected word line is programmed to a respective target program state; applying an inhibition voltage to bit lines coupled to programmed memory cells; and selecting a next group to be programmed until the plurality of groups are programmed.

A determination is made that data has to be moved internally within a non-volatile memory from a plurality of pages of a first type of storage media to a page of a second type of storage media. A first subset of the plurality of pages is copied from the first type of storage media to the page of the second type of storage media. Concurrently with the copying of the first subset of the plurality of pages, a second subset of the plurality of pages is copied from the first type of storage media to the page of the second type of storage media. In response to completion of the copying of the first subset and the second subset of the plurality of pages, it is determined that the copying of the data from the first type of storage media to the second type of storage media has completed.

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.

A memory device includes a cell group and a control circuit. The cell group includes plural non-volatile memory cells, each capable of storing multi-bit data corresponding to plural program states and an erased state. The control circuit performs at least two partial program operations for programming the multi-bit data in at least two non-volatile memory cells. The at least two partial program operations include an ISPP operation to increase a threshold voltage of the at least two non-volatile memory cells from the erased state to a first program state among the plural program states and a single pulse program operation to increase a threshold voltage of at least one non-volatile memory cell among the at least two non-volatile memory cells from the first program state to another program state which is higher than the first program state among the plural program states.

One or more control circuits of a storage system are configured to consolidate the sensing of pre-pad and/or post-pad data for one unaligned write command with the transferring of previously sensed pre-pad and/or post-pad data for another unaligned write command. By consolidating the sensing and transferring, considerable time is saved when programming data for a set of two or more unaligned write commands. Also, in one aspect, a single programming operation is performed for multiple unaligned write commands. Some conventional solutions may need to perform a programming operation for each unaligned write command. Hence, considerable programming time is saved by the storage system. Moreover, write amplification may be reduced by the storage system.

A bad block of memory cells is quickly detected and removed from further programming during concurrent multi-block program operations, to minimize a threshold voltage upshift in a good block. A difference in program speeds between the blocks can be quickly detected by detecting when the memory cells in each block pass a verify test, such as a verify test of a lowest programmed data state. If a first block passes the verify test at a reference program loop, a determination is made as to whether a second block passes the verify test within a specified number of additional program loops. If the second block meets this criterion, the program operation can continue for both blocks. However, if the second block does not meet this criterion, the program operation is terminated for the second block by isolating it from subsequent program and verify signals.

Method of operating a memory include increasing respective threshold voltages of a first subset of memory cells of a plurality of memory cells to threshold voltage levels higher than a particular voltage level in response to applying a first plurality of programming pulses, and subsequently increasing respective threshold voltages of a second subset of memory cells of the plurality of memory cells to threshold voltage levels lower than the particular voltage level in response to applying a second plurality of programming pulses, wherein the first plurality of programming pulses have respective voltage levels within a first range of voltage levels, the second plurality of programming pulses have respective voltage levels within a second range of voltage levels, and a lowest voltage level of the first range of voltage levels is lower than or equal to a highest voltage level of the second range of voltage levels.

In a method for operating a semiconductor device, the method may include: sorting program states of a memory cell that stores multi-bit data into a plurality of groups; applying different bias voltages to bit lines corresponding to a selected group among the plurality of groups; applying a program voltage to a selected word line corresponding to the selected group; verifying whether each of selected memory cells corresponding to the selected word line is programmed to a respective target program state; applying an inhibition voltage to bit lines coupled to programmed memory cells; and selecting a next group to be programmed until the plurality of groups are programmed.