Methods, systems, and devices for modifying memory bank operating parameters are described. Operating parameter(s) may be individually adjusted for memory banks or memory bank groups within a memory system based on trimming information. The local trimming information for a memory bank or memory bank group may be stored in a fuse set that also stores repair information for the particular memory bank or in a fuse set that also stores repair information for a memory bank in the particular memory bank group. The local trimming information may be applied to operating parameters for particular memory banks or memory bank groups relative to or instead of global adjustments applied to operating parameters of multiple or all of the memory banks in the memory system.

A method is described that includes determining a number of program and erase cycles associated with a block of pages of a memory device and determining a preprogram voltage based on the number of program and erase cycles to apply to the block of pages prior to an erase operation. The method further includes applying the preprogram voltage to the block of pages and performing an erase operation on the block of pages following application of the preprogram voltage to the block of pages.

A memory controller includes an interface and a control module. The interface interfaces with a memory device which includes a plurality of dies that each include a plurality of blocks. The control module groups a plurality of blocks included in different dies and manages the plurality of blocks as a super block. The control module performs scheduling to alternately perform a program on a part of an Nth super block, wherein N is a natural number, and a phased erase on an N+1st super block, and the control module completes the program on the Nth super block and the erase on the Nth super block before the program on the N+1st super block starts.

According to one embodiment, a memory system includes a semiconductor memory and a controller. The semiconductor memory includes blocks each containing memory cells. The controller is configured to instruct the semiconductor memory to execute a first operation and a second operation. In the first operation and the second operation, the semiconductor memory selects at least one of the blocks, and applies at least one voltage to all memory cells contained in said selected blocks. A number of blocks to which said voltage is applied per unit time in the second operation is larger than that in the first operation.

Apparatus might include a controller configured to cause the apparatus to program a plurality of memory cells from a first data state to a second data state higher than the first data state, determine a respective first voltage level of a control gate voltage deemed to cause each memory cell of a first and second subset of memory cells of the plurality of memory cells to reach the second data state, determine a respective second voltage level of a control gate voltage deemed sufficient to cause each memory cell of the first subset of memory cells to reach a third data state higher than the second data state, and determine a respective second voltage level of a control gate voltage deemed sufficient to cause each memory cell of the second subset of memory cells to reach a fourth data state higher than the third data state.

A memory having a plurality of blocks is coupled with control circuits having logic to execute a no-current read setup operation, the read setup operation comprising simultaneously applying a read setup bias to a plurality of memory cells of a selected block of the plurality of blocks while disabling current flow. Logic to traverse the blocks in the plurality of blocks can apply the read setup operation to the plurality of blocks. The blocks in the plurality of blocks can include, respectively, a plurality of sub-blocks. The read setup operation can traverse sub-blocks in a block to simultaneously apply the read setup bias to more than one individual sub-block of the selected block. A block status table can be used to identify stale blocks for the read setup operation. Also, the blocks can be traversed as a background operation independent of read commands addressing the blocks.

A memory device includes a string of cells having one and more top selection cells, one or more dummy memory cells, and memory cells, and a peripheral circuit coupled to the string of cells. The peripheral circuit is configured to verify a threshold voltage of at least one of the one or more top selection cells or the one or more dummy memory cells to determine whether the at least one of the one or more top selection cells or the one or more dummy memory cells has failed. In response to the at least one of the one or more top selection cells or the one or more dummy memory cells being failed, the peripheral circuit is further configured to reset the at least one of the one or more top selection cells or the one or more dummy memory cells.

A flash memory device includes a cell array and a control circuit. The cell array includes a first NAND string having first flash memory cells having control gates respectively connected to word lines, and a first bit line selection switch connecting the first flash memory cells to a first bit line according to a control of a first string selection line. The control circuit controls a first erase operation for erasing a selected flash memory cell. The control circuit controls a voltage difference between the first bit line and the first string selection line to have a first value for generating gate induced drain leakage (GIDL) at the first bit line selection switch, and controls a voltage of a control gate of the selected flash memory cell and a voltage of a control gate of an unselected flash memory cell to be different from each other.

The present technology relates to a memory system and a method of operating the same. The memory system includes a memory device including a plurality of semiconductor memories, and a controller configured to control the memory device to select a victim block based on a fail bit number of some data, among data that is programmed in each of the plurality of semiconductor memories, corresponding to a specific program state, and configured to perform a garbage collection operation on the selected victim blocks.

Systems and methods are disclosed including a memory device and a processing device operatively coupled to the memory device. The processing device can perform operations including determining a voltage distribution metric associated with a at least part of a block of the memory device; determining a threshold value for the voltage distribution metric associated with the block; and responsive to determining that the voltage distribution metric exceeds the threshold value, performing a media management operation with respect to the block.