A memory device includes a memory cell array including a plurality of memory cells; a voltage generator configured to generate voltages used for a program operation and a verify operation for the memory cells; and control logic configured to perform a plurality of program loops while writing data to the memory cell array, such that first to N-th (e.g., N>=1) program loops including a program operation and a verify operation are performed and at least two program loops in which the verify operation is skipped are performed when a pass/fail determination of the program operation in the N-th program loop indicates a pass.

A memory device including a plurality of memory cells, a peripheral circuit, and control logic. The peripheral circuit is configured to generate a plurality of operating voltages used in a memory operation, based on a target pump clock, and perform the memory operation by using the plurality of operating voltages. The control logic is configured to select the target pump clock among a plurality of pump clocks, based on a number of data bits which selected memory cells on which the memory operation is to be performed among the plurality of memory cells store, and control the peripheral circuit to perform the memory operation on the selected memory cells.

Numerous examples of summing circuits for a neural network are disclosed. In one example, a circuit for summing current received from a plurality of synapses in a neural network comprises a voltage source; a load coupled between the voltage source and an output node; a voltage clamp coupled to the output node for maintaining a voltage at the output node; and a plurality of synapses coupled between the output node and ground; wherein an output current flows through the output node, the output current equal to a sum of currents drawn by the plurality of synapses.

A method of controlling a memory device includes receiving a write instruction; starting a write operation to a first address in response to the write instruction; receiving a first read instruction of the first address; suspending the write operation; and applying a read voltage to a word line corresponding to the first address in a first read operation in response to the first read instruction.

An example memory sub-system includes a memory device and a processing device, operatively coupled to the memory device. The processing device is configured to detect a power-up state of the memory device following a power loss event; detect a read error with respect to data residing in a block of the memory device, wherein the block is associated with a current voltage offset bin; and perform temporal voltage shift (TVS)-oriented calibration for associating the block with a new voltage offset bin.

A nonvolatile memory device includes a memory cell array and a row decoder. The memory cell array includes a plurality of mats. A first cell string of first mat is connected to a plurality of first word-lines, a first bit-line and a first string selection line. A second cell string of second mat is connected to a plurality of second word-lines, a second bit-line and a second string selection line. Each of the first and second cell strings includes a ground selection transistor, memory cells, and a string selection transistor coupled in series. The row decoder applies a first voltage to a third word-line among the plurality of first and second word-lines for a first period of time in a single mat mode and to apply a second voltage to the third word-line for a second period of time longer than the first period of time in a multi-mat mode.

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.

A storage device performs a read operation by restoring an ON cell count (OCC) from a power loss protection (PLP) area of a nonvolatile memory. The nonvolatile memory includes a memory blocks, a buffer memory and a controller. The buffer memory stores a first ON cell count (OCC1) indicating a number of memory cells turned ON by a first read voltage and a second ON cell count (OCC2) indicating a number of memory cells turned ON by a second read voltage among the memory cells connected to a reference word line. The controller stores the OCC1 for each of the memory blocks in the PLP area when a sudden power off occurs in the storage device.

Testing circuitry and methods are disclosed for use with analog neural memory in deep learning artificial neural networks. In one example, a method is disclosed of testing a plurality of non-volatile memory cells in an array of non-volatile memory cells, wherein the array is arranged in rows and columns, wherein each row is coupled to a word line and each column is coupled to a bit line, and wherein each word line is selectively coupled to a row decoder and each bit line is selectively coupled to a column decoder, the method comprising asserting, by the row decoder, all word lines in the array; asserting, by the column decoder, all bit lines in the array; performing a deep programming operation on the array of non-volatile memory cells; and measuring a total current received from the bit lines.