A memory device comprises a first memory area including a first memory cell array having a plurality of first memory cells each for storing N-bit data, where N is a natural number, and a first peripheral circuit for controlling the first memory cells according to an N-bit data access scheme and disposed below the first memory cell array, a second memory area including a second memory cell array having a plurality of second memory cells each for storing M-bit data, where M is a natural number greater than N, and a second peripheral circuit for controlling the second memory cells according to an M-bit data access scheme and disposed below the second memory cell array, wherein the first memory area and the second memory area are included in a single semiconductor chip and share an input and output interface, and a controller configured to generate calculation data by applying a weight stored in the first memory area to sensing data in response to receiving the sensing data obtained by an external sensor, and store the calculation data in one of the first memory area or the second memory area according to the weight, wherein the plurality of first memory cells and the plurality of second memory cells are included in a first chip having a first metal pad, the first peripheral circuit and the second peripheral circuit are included in a second chip having a second metal pad, and the first chip and the second chip are vertically connected to each other by the first metal pad and the second metal pad.

A request to perform a write operation at a memory component can be received. A destination block of the memory component to store data of the write operation can be determined. A voltage pulse can be applied to the destination block that places a memory cell of the destination block at a voltage level associated with a high voltage state. Responsive to applying the voltage pulse to the destination block, an erase operation for the destination block can be performed to change the voltage level of the memory cell from the high voltage state to a low voltage state. A write operation can be performed to write the data to the destination block that is at the low voltage state.

A nonvolatile memory device includes a memory cell region, a peripheral circuit region, a memory block in the memory cell region, a row decoder in the peripheral circuit region, and a control circuit in the peripheral circuit region. The memory cell region includes a first metal pad. The peripheral circuit region includes a second metal pad and is vertically connected to the memory cell region by the first metal pad and the second metal pad. The memory block includes memory cells stacked in a direction intersecting a substrate, and is divided into a plurality of sub-blocks configured to be erased independently. The row decoder selects the memory block by units of a sub-block. The control circuit receives a data erase command for a selected sub-block among the plurality of sub-blocks, performs a data read operation on at least one victim sub-block among the plurality of sub-blocks in response to the data erase command, selectively performs a soft program operation on the at least one victim sub-block based on a result of the data read operation, and performs a data erase operation on the selected sub-block after the data read operation is performed and the soft program operation is selectively performed.

A semiconductor memory device includes a memory cell array including first and second groups of memory strings respectively coupled to first and second groups of bit-lines, wherein the first and second groups of memory strings respectively include first and second groups of selection transistor cells; a peripheral circuit suitable for applying a program voltage, and performing program verification operation for the memory cell array; and a control logic suitable for controlling the peripheral circuit to perform a first program verification operation for the first group of selection transistor cells and a second program verification operation for the second group of selection transistor cells.

A nonvolatile memory device includes a memory cell region, a peripheral circuit region, a memory block in the memory cell region, a row decoder in the peripheral circuit region, and a control circuit in the peripheral circuit region. The memory cell region includes a first metal pad. The peripheral circuit region includes a second metal pad and is vertically connected to the memory cell region by the first metal pad and the second metal pad. The memory block includes memory cells stacked in a direction intersecting a substrate, and is divided into a plurality of sub-blocks configured to be erased independently. The row decoder selects the memory block by units of a sub-block. The control circuit receives a data erase command for a selected sub-block among the plurality of sub-blocks, performs a data read operation on at least one victim sub-block among the plurality of sub-blocks in response to the data erase command, selectively performs a soft program operation on the at least one victim sub-block based on a result of the data read operation, and performs a data erase operation on the selected sub-block after the data read operation is performed and the soft program operation is selectively performed.

A semiconductor memory device includes a memory cell array including first and second groups of memory strings respectively coupled to first and second groups of bit-lines, wherein the first and second groups of memory strings respectively include first and second groups of selection transistor cells; a peripheral circuit suitable for applying a program voltage, and performing program verification operation for the memory cell array; and a control logic suitable for controlling the peripheral circuit to perform a first program verification operation for the first group of selection transistor cells and a second program verification operation for the second group of selection transistor cells.

A method of operating a memory device includes performing a data read operation on at least one victim sub-block within a memory block containing a plurality of sub-blocks therein, in response to an erase command directed to a selected sub-block within the plurality of sub-blocks. Next, a soft program operation is performed on the at least one victim sub-block. This soft programming operation is then followed by an operation to erase the selected sub-block within the plurality of sub-blocks. This operation to erase the selected sub-block may include providing an erase voltage to a bulk region of a substrate on which the memory block extends, and the at least one victim sub-block may be disposed between the selected sub-block and the substrate.

Described herein are embodiments related to first-pass dynamic program targeting (DPT) operations on memory cells of memory systems. A processing device determines that a first programming pass of a programming operation has been performed on a memory cell of a memory component. The processing device, before a second programming pass of the programming operation is performed on the memory cell, determines information about a first programming distribution and a second programming distribution of the memory cell, the first programming distribution corresponding to a first page type and the second programming distribution corresponding to a second page type. The processing device adjusts, using the information, a placement of the first programming distribution relative to the second programming distribution that balances a bit error rate (BER) between the first page type and the second page type.

Described herein are embodiments related to first-pass continuous read level calibration (cRLC) operations on memory cells of memory systems. A processing device determines that a first programming pass of a programming operation has been performed on a memory cell of a memory component. The processing device performs a cRLC operation on the memory cell to calibrate a read level threshold between a first first-pass programming distribution and a second first-pass programming distribution before a second programming pass of the programming operation is performed on the memory cell.

A method of operating a memory device includes performing a data read operation on at least one victim sub-block within a memory block containing a plurality of sub-blocks therein, in response to an erase command directed to a selected sub-block within the plurality of sub-blocks. Next, a soft program operation is performed on the at least one victim sub-block. This soft programming operation is then followed by an operation to erase the selected sub-block within the plurality of sub-blocks. This operation to erase the selected sub-block may include providing an erase voltage to a bulk region of a substrate on which the memory block extends, and the at least one victim sub-block may be disposed between the selected sub-block and the substrate.