A memory apparatus and method of operation are provided. The apparatus includes memory cells connected to one of a plurality of word lines and arranged in strings and configured to retain a threshold voltage corresponding to one of a plurality of memory states. A control circuit is coupled to the plurality of word lines and strings and is configured to erase the memory cells using a stripe erase operation in response to determining a cycle count is less than a predetermined cycle count maximum threshold. The control circuit is also configured to perform a dummy cycle operation in response to determining the cycle count is not less than the predetermined cycle count maximum threshold.

A non-volatile storage apparatus is configured to perform erase verify during an erase process in order to account for differences in erase speed. In order to reduce the time used to perform the erase process (which includes the erase verify), the erase verify operation is skipped for certain memory cells based on a system parameter. For example, when erasing a block of memory cells, a series of erase voltage pulses are applied to the NAND strings in outer sub-blocks and inner sub-blocks of the block. Erase verify is performed between erase voltage pulses for NAND strings in the outer sub-blocks while skipping erase verify for NAND strings in the inner sub-blocks. Performing erase verify between erase voltage pulses for NAND strings in the inner sub-blocks is started at a predetermined number of erase voltage pulses after the NAND strings in the outer sub-blocks successfully erase verify.

A memory system includes a non-volatile memory, and a controller configured to issue a first command requesting a first operation to the non-volatile memory and a second command to the non-volatile memory. The second command may be for requesting a duration time of the first operation or for requesting an execution stage of the first operation. In accordance with the information returned by the non-volatile memory in response to the second command, the controller issues a third command requesting a completion status of the first operation to the non-volatile memory. The first operation may be a data read operation, a data write operation, or a data erase operation.

In an embodiment a non-volatile memory device includes a memory array having a plurality of memory cells, a control unit operatively coupled to the memory array, a biasing stage controllable by the control unit and configured to apply a biasing configuration to the memory cells to perform a memory operation and a reading stage coupled to the memory array and controllable by the control unit, the reading stage configured to verify whether the memory operation has been successful based on a verify level, wherein the control unit is configured to adaptively modify a value of the verify level based on an ageing of the memory cells.

According to one embodiment, a semiconductor storage device includes strings each with a first select transistor, memory cell transistors, and a second select transistor connected in series. Word lines are provided, each connected to memory cell transistors in a same position across the strings. A bit line is connected in common to a first end of each of the strings. A source line is connected in common to a second end of each of the strings. A control circuit is configured to perform an erase operation on strings. The control circuit adjusts, for each of the strings, either an application time of a first voltage applied to a gate of the first select transistor of the respective string in the erase operation or a voltage level of the first voltage applied to the gate of the first select transistor of the respective string in the erase operation.

A memory device includes a first block including a first memory cell and a first word line connected to the first memory cell, a second block including a second memory cell and a second word line connected to the second memory cell, and a control circuit. The control circuit applies a first voltage to each of the first and second word lines to supply a first erase pulse having a first erase intensity to each of the first and second blocks, when a first erase operation is executed, and applies the first voltage to the first word line and a second voltage higher than the first voltage to the second word line, to supply the first erase pulse to the first block and a second erase pulse having a second erase intensity less than the first erase intensity to the second block, when a second erase operation is executed.

A non-volatile storage system includes a control circuit connected to non-volatile memory cells provides for progressive writing of data. That is, existing data is overwritten by new data without performing a traditional erase operation that changes the threshold voltage of the memory cells back to the traditional or original erase state. In one example, new data is written on top of old data using shifted threshold voltage distributions. Some embodiments include writing MLC data over SLC data, using intermediate erase threshold voltage distributions and/or automatically detecting which threshold voltage distributions are currently being used to store data.

A semiconductor storage device of an embodiment includes a memory block, a resistance measurement circuit, and a control circuit. The memory block includes first to third control signal lines connected to gates of a first select gate transistor, a plurality of memory cell transistors, and a second select gate transistor. The resistance measurement circuit measures resistance of at least one control signal line among the first to third control signal lines. The control circuit performs erase, program, and read of data at the plurality of memory cell transistors included in the memory block. The control circuit determines, based on a measurement result of the resistance measurement by the resistance measurement circuit, whether to set a fail status to a result of erase verify that verifies the erase.

A nonvolatile memory device includes a memory cell array having cell strings that each includes memory cells stacked on a substrate in a direction perpendicular to the substrate. A row decoder is connected with the memory cells through word lines. The row decoder applies a setting voltage to at least one word line of the word lines and floats the at least one word line during a floating time. A page buffer circuit is connected with the cell strings through bit lines. The page buffer senses voltage changes of the bit lines after the at least one word line is floated during the floating time and outputs a page buffer signal as a sensing result. A counter counts a number of off-cells in response to the page buffer signal. A detecting circuit outputs a detection signal associated with a defect cell based on the number of off-cells.

A memory apparatus and method of operation are provided. The apparatus includes memory cells connected to one of a plurality of word lines and arranged in strings and configured to retain a threshold voltage. A control means is coupled to the plurality of word lines and the strings. The control means is configured to apply a primary predetermined voltage to a primary location of the memory apparatus following an erase operation of the memory cells while simultaneously applying a secondary predetermined voltage being lower than the primary predetermined voltage to a secondary location of the memory apparatus and measuring a leak current at the primary location. The control means then determines the erase operation passed in response to the leak current measured not being greater than a predetermined leak threshold.