Technologies for performing a quick reliability scan include, for a particular block of a set of blocks of different block types. Each block of the set of blocks includes pages of memory of a physical memory device. A subset of the pages of the block is identified. The block is scanned by scanning the subset of the plurality of pages of the block for a fold condition. A page of the subset of the plurality of pages is determined to have the fold condition. After the set of blocks has been scanned, the folding of the block that includes the page that has been determined to have the fold condition is requested.

A memory device includes a memory array comprising a plurality of wordlines, and control logic, operatively coupled with the memory array. The control logic causes a measurement programming pulse to be sequentially applied to each of the plurality of wordlines of the memory array and determines respective threshold voltages stored in a number of memory cells associated with each of the plurality of wordlines. The control logic further determines a difference in the respective threshold voltages based on a location of the number of memory cells within each wordline and determines a respective resistance-capacitance (RC) time constant for each of the plurality of wordlines in view of the difference in the respective threshold voltages.

A memory device includes a high density or 3D data memory and a 3D reference memory. The reference memory is used to generate a reference signal used to sense data in the data memory. Conversion circuitry converts signals from one memory cell or a group of memory cells in the reference memory into a reference signal. The reference signal is applied to a sense amplifier to sense data stored in a selected memory cell in the data memory.

According to one embodiment, a memory system includes a non-volatile memory and a memory controller. The non-volatile memory includes a plurality of groups, each including a plurality of memory cells. The memory controller is configured to determine whether to execute a refresh process for a first group based on whether a first temperature in a write process for the first group and a second temperature after the write process for the first group satisfy a first condition.

The present disclosure relates to a method for improving the safety of the reading phase of a non-volatile memory device including at least an array of memory cells and with associated decoding and sensing circuitry and a memory controller, the method comprising:

storing in a dummy row of said memory block at least a known pattern;

performing some reading cycles changing the read trimming parameters up to the moment wherein said known value is read correctly;

adopting the trimming parameters of the correct reading for the subsequent reading phases.

The disclosure further relates to a memory device structured for implementing the above method.

The present disclosure relates to a method for improving the safety of the reading phase of a non-volatile memory device including at least an array of memory cells and with associated decoding and sensing circuitry and a memory controller, the method comprising: storing in a dummy row of said memory block at least a known pattern; performing some reading cycles changing the read trimming parameters up to the moment wherein said known value is read correctly; adopting the trimming parameters of the correct reading for the subsequent reading phases. The disclosure further relates to a memory device structured for implementing the above method.

A memory device may include a plurality of memory cells, a peripheral circuit configured to perform a plurality of program loops on selected memory cells among the plurality of memory cells, each of the plurality of program loops including a program pulse application operation and a program verify operation, and control logic configured to control the peripheral circuit to suspend an n.sup.th program loop (n is a natural number equal to or greater than 1) among the plurality of program loops in response to a suspend command received during the n.sup.th program loop, and to resume the n.sup.th program loop with a negative verify operation in response to a resume command. The negative verify operation applies a negative voltage having a voltage less than a state voltage at the time of application of the resume command.

Provided herein may be a memory device and a method of operating the same. The memory device may include a plurality of memory cells, a program operation performer configured to perform a plurality of program loops on the plurality of memory cells, a step voltage calculator configured to calculate a step voltage, the step voltage being a difference of magnitude between program voltages that are applied in any two consecutive program loops, a reference bit determiner configured to determine a reference number of fail bits based on a magnitude of the step voltage, and a verification result generator configured to generate verification result information based on a result of a comparison between the reference number of fail bits and a number of on-cells, among the plurality of memory cells, identified in a verify operation that is included in a program loop, among the plurality of program loops.

The memory device includes a block with a plurality of memory cells arranged in a plurality of data word lines, which are arranged in sub-blocks that are not separated from one another by physical joints or by dummy word lines. A controller is configured to erase the memory cells of a selected sub-block of the plurality of sub-blocks without erasing the memory cells of the unselected sub-blocks. The controller reads data of the edge one word lines of the unselected sub-blocks adjacent the selected sub-block and stores this data in a temporary location external of the block before erasing the memory cells of the selected sub-block. The controller then re-programs the data that is being temporarily stored back into the memory cells of the edge word lines of the unselected sub-blocks after erase of the selected sub-block is completed.

A value-voltage-distribution-intersection-based read disturb information determination system includes a storage device coupled to a global read temperature identification system. The storage device identifies a value voltage distribution intersection of first and second value voltage distributions for respective first and second values in a first row in a storage subsystem in the storage device, and determines a default value voltage reference shift between a default value voltage reference level associated with the first value and the second value and the value voltage distribution intersection. Based on the default value voltage reference shift, the storage device determines read disturb information for the first row in the storage subsystem in the storage device, and uses it to generate a read temperature for a second row in the storage subsystem in the storage device that it provides to the global read temperature identification system.