Abstract: A non-volatile memory device is provided as follows. A substrate has a peripheral circuit. A first semiconductor layer is disposed on the substrate. The first semiconductor layer includes a memory cell region. A first gate structure is disposed on the first semiconductor layer. The first gate structure includes a plurality of first gate electrodes stacked in a perpendicular direction to the first semiconductor layer and a plurality of vertical channel structures penetrating the plurality of first gate electrodes. The first gate structure is arranged in the memory cell region. A second gate structure is disposed on the substrate. The second gate structure includes a plurality of second gate electrodes stacked in the perpendicular direction to the first semiconductor layer. The second gate structure is arranged outside the memory cell region.

Abstract: According to one embodiment, a memory system includes a nonvolatile semiconductor memory device, a voltage generation unit and a control unit. The nonvolatile semiconductor memory device includes a memory cell array having a plurality of blocks each including a plurality of memory cells, and a voltage generation unit configured to change a read level of the memory cell. The control unit controls write, read, and erase of the nonvolatile semiconductor memory device. The control unit changes the read level between a start of use of the nonvolatile semiconductor memory device and a timing after an elapse of a time.

Abstract: A storage device includes storage circuitry and multiple memory blocks. The multiple memory blocks are arranged in an array, and each of the memory blocks includes multiple memory cells. A maximal number of programming cycles that a memory block of the multiple memory blocks sustains depends on a distance of the memory block from an edge of the array. The storage circuitry is configured to apply to the memory blocks programming cycles so that a number of programming cycles that can be applied to a respective memory block is based on a respective distance of the respective memory block from the edge of the array.

Abstract: A data storage device and operating method for a FLASH memory are disclosed. The data storage device includes a FLASH memory and a controller. The FLASH memory includes a first block and a second block. The first and second blocks each includes a plurality of pages. The controller executes a firmware to determine whether a data segment from a host is a complete page segment. When the data segment is a complete page segment, the controller stores the data segment into the first block. When the data segment is an incomplete page segment, the controller stores the data into segment the second block.

Abstract: Methods, systems, and devices for operating a ferroelectric memory cell or cells are described. One method includes determining whether to access a first memory cell of a first memory cell array or a second memory cell of a second memory cell array, where a first digit line coupled to the first memory cell is coupled to a paging buffer register including a sense amplifier. The method further includes operating a transfer gate based at least in part on determining to read the second memory cell of the second memory cell array, where the transfer gate is configured to selectively couple a second digit line coupled to the second memory cell to the paging buffer register through the first digit line.

Abstract: According to one embodiment, a semiconductor memory device includes a substrate, a stacked body, a columnar section and an interconnection section. The stacked body includes a first insulating layer, a first electrode layer, a second insulating layer, and a second electrode layer. The first insulating layer includes a first surface facing the substrate, and a second surface facing the first electrode layer and opposite to the first surface. The second insulating layer includes a third surface facing the first electrode layer, and a fourth surface facing the second electrode layer and opposite to the third surface. A width of the interconnection section located between the first surface and the second surface in a second direction perpendicular to a stacking direction and a first direction is larger than a width of the interconnection section located between the third surface and the fourth surface in the second direction.

Abstract: A flash storage device provides direct memory access based on a first communication protocol. A host selects the first communication protocol and provides a request to the flash storage device for a direct memory access. Additionally, the host provides data blocks to the flash storage device for the direct memory access. In the first communication protocol, the host need not provide an address to the flash storage device for the direct memory access. The flash storage device stores the data blocks at sequential addresses starting at a predetermined address in the flash storage device. Another host may then select a second communication protocol and transfer the data blocks in the flash storage by using the second communication protocol.

Abstract: A trim command processing method for a memory storage apparatus having a rewritable non-volatile memory module having a plurality of physical programming units is provided. The method includes receiving a command from a host system; starting a trim operation to perform an operation corresponding to a trim command according to a record related to the trim command in a trim table if an operation corresponding the command is performed on the rewritable non-volatile memory module with a first mode; and not starting aforesaid trim operation if the operation corresponding the command is performed on the rewritable non-volatile memory module with a second mode.

Abstract: In an embodiment of a memory device including a matrix of memory cells wherein the memory cells are arranged in a plurality of memory cells strings each one including at least two serially-connected memory cells, groups of at least two memory cells strings being connected to a respective bit line, and wherein said memory cells are adapted to be programmed into at least a first programming state and a second programming state, a method of storing data comprising exploiting a single memory cell for each of the memory cells string for writing the data, wherein said exploiting includes bringing the single memory cell to the second programming state, the remaining memory cells of the string being left in the first programming state.

Abstract: A power control device and a semiconductor memory device including the same may be provided. The power control device, may include an amplifier configured to amplify an input signal having a second power-supply voltage level to a first power-supply voltage level having a voltage level different from the second power-supply voltage level. The power control device may include an output portion configured to set an output signal of the amplifier to a specific logic level upon receiving a control signal, and output the output signal having the specific logic level.

Abstract: A method for operating a memory array is disclosed. The memory array includes a first memory cell, a second memory cell and a third memory cell sharing a gate and arranged along an extending direction of the gate in order. The method includes the following steps. A first bias is applied to a channel of the first memory cell to program the first memory cell. A second bias is applied to a channel of the second memory cell to inhibit programming of the second memory cell. A third bias is applied to a channel of the third memory cell to program or inhibit programming of the third memory cell. The first bias and the third bias are different.

Abstract: A first set representing a first plurality of physical block addresses of a non-volatile memory and a second set representing a second plurality of physical block addresses of the non-volatile memory may be identified. In response to a request to perform a wear leveling operation, first data from a first physical block address of the first set may be swapped with second data from a first physical block address of the second set. A second physical block address of the first set that is adjacent to the first physical block address of the first set may be identified. Third data from the second physical block address of the first set may be swapped with fourth data from a second physical block address of the second set that is adjacent to the first physical block of the second set.

Abstract: An apparatus, system, and method for controlling data transfer to an output port of a serial data link interface in a semiconductor memory is disclosed. In one example, a flash memory device may have multiple serial data links, multiple memory banks and control input ports that enable the memory device to transfer the serial data to a serial data output port of the memory device. In another example, a flash memory device may have a single serial data link, a single memory bank, a serial data input port, a control input port for receiving output enable signals. The flash memory devices may be cascaded in a daisy-chain configuration using echo signal lines to serially communicate between memory devices.

Abstract: The present disclosure relate a method of operating a semiconductor memory device including at least two memory blocks sharing one block word line. The method including applying an erase voltage to a source line commonly coupled to the memory blocks, one of which is a selected memory block and applying a first voltage to the block word line and a third voltage to a global word line of an unselected memory block of the memory blocks when the erase voltage is applied to the source line, wherein the first voltage is higher than a turn-on voltage to turn on a pass transistor coupled to the block word line, and wherein the third voltage floats a local word line included in the unselected memory block according to a level of the first voltage.

Abstract: An apparatus, system, and method for controlling data transfer to an output port of a serial data link interface in a semiconductor memory is disclosed. In one example, a flash memory device may have multiple serial data links, multiple memory banks and control input ports that enable the memory device to transfer the serial data to a serial data output port of the memory device. In another example, a flash memory device may have a single serial data link, a single memory bank, a serial data input port, a control input port for receiving output enable signals. The flash memory devices may be cascaded in a daisy-chain configuration using echo signal lines to serially communicate between memory devices.

Abstract: A method of operating a non-volatile memory device includes selecting a first select transistor from among a plurality of select transistors included in a NAND string, and performing a check operation on a first threshold voltage of the first select transistor. The check operation includes comparing the first threshold voltage with a first lower-limit reference voltage level, and performing a program operation on the first select transistor when the first threshold voltage is lower than the first lower-limit reference voltage level. When the first threshold voltage is equal to or higher than the first lower-limit reference voltage level, the check operation on the first threshold voltage is ended.

Abstract: A nonvolatile memory device includes a memory cell array having memory cells, a row decoder circuit connected to the memory cells through word lines, a page buffer circuit connected to the memory cells through bit lines, and a control circuit controlling the row decoder circuit and the page buffer circuit to repeatedly perform an erase loop including an erase and an erase verification with respect to the memory cells. The control circuit is configured to select one of an increase and a decrease of an erase voltage according to a result of the erase verification of a current erase loop and apply the controlled erase voltage to the memory cells in the erase operation of a subsequent erase loop.

Abstract: A method of operating a non-volatile memory device includes performing an erasing operation to memory cells associated with a plurality of string selection lines (SSLs), the memory cells associated with the plurality of SSLs constituting a memory block, and verifying the erasing operation to second memory cells associated with a second SSL after verifying the erasing operation to first memory cells associated with a first SSL.

Abstract: A memory managing method, a memory control circuit unit and a memory storage apparatus are provided. The method includes: setting a read-disturb threshold for each of a plurality of physical erasing units; adjusting the read-disturb threshold of a first physical erasing unit according to state information of a rewritable non-volatile memory module; and performing a read-disturb prevention operation according to the read-disturb threshold of the first physical erasing unit.

Abstract: A method of indirection replay for a flash storage system includes writing data, in a host stream, to blocksets of the flash storage system. The host blocksets are assigned a major sequence number incremented from the most recently closed host blockset. The method includes writing an indirection journal to each host blockset which are associated with the assigned major sequence number. The method includes writing data, in a garbage collection (GC) stream, to other blocksets of the flash storage system. The GC blocksets are assigned a major sequence number, based on the most recently closed host blockset, and a minor sequence number, incremented from the most recently closed GC blockset. The method includes writing an indirection journal to each GC blockset which are associated with the assigned major and minor sequence numbers. The indirection table is constructed by replaying the journals of the blocksets in order of major sequence and minor sequence numbers.

Abstract: A memory system in accordance with an embodiment may include a memory chip and a controller. The memory chip may store data in a plurality of logical pages by performing a sensing operation on a selected page in response to commands and performing an output operation of the data. The controller may transmit the commands to the memory chip so that a part of the sensing operation and a part of the output operation are simultaneously performed.

Abstract: A three-dimensional memory device includes an alternating stack of word lines and insulating layers, vertical semiconductor channels vertically extending through the alternating stack, and a ferroelectric memory material located between each vertical semiconductor channel and the word lines.

Abstract: A method, apparatus, and manufacture for memory device startup is provided. Flash memory devices are configured such that, upon the power supply voltage reaching a pre-determined level, each flash memory is arranged to load the random access memory with instructions for the flash memory, and then execute a first portion of the instructions for the flash memory. After executing the first portion of the instructions for the flash memory, each separate subset of the flash memories waits for a separate, distinct delay period. For each flash memory, after the delay period expires for that flash memory, the flash memory executes a second portion of the instructions for the flash memory.

Abstract: A communication line is connected to first and second chips, and held at a first signal level. A monitor circuit changes a signal level of the communication line from the first signal to a second signal level while one of the first and second chips uses a current larger than a reference current. When the signal level of the communication line is the second signal level, the other of the first and second chips is controlled to a wait state that does not transfer to an operating state of using a current larger than the reference current.

Abstract: A semiconductor memory device includes a memory block, a plurality of bit lines, a plurality of select gate lines, a plurality of word lines, and a controller. The memory block includes a plurality of memory strings, each memory string including a selection transistor and a plurality of memory cells. The plurality of bit lines are arranged in the first direction and connected to the respective memory strings. The plurality of select gate lines are arranged in the second direction and connected to gates of the respective selection transistors of the memory strings. The plurality of word lines are arranged in the third direction and connected to gates of the respective memory cells of the memory strings. The controller is configured to perform an erase operation in a unit of the memory block, and perform a sequence of erase verify operations.

Abstract: A monolithic three dimensional NAND string includes a plurality of control gate electrodes extending substantially parallel to a major surface of a substrate, a memory opening extending substantially perpendicular to the major surface of the substrate and filled with a memory opening material including a memory film, and a dummy opening extending substantially perpendicular to the major surface of the substrate and filled with a dummy channel material which is different from the memory opening material. The dummy channel material has a higher Young's modulus than the memory opening material to offset warpage of the substrate due to the one of compressive and tensile stress imposed by the plurality of control gate electrodes on the substrate.

Abstract: In a data transmission system, one or more signal supply voltages for generating the signaling voltage of a signal to be transmitted are generated in a first circuit and forwarded from the first circuit to a second circuit. The second circuit may use the forwarded signal supply voltages to generate another signal to be transmitted back from the second circuit to the first circuit, thereby obviating the need to generate signal supply voltages separately in the second circuit. The first circuit may also adjust the signal supply voltages based on the signal transmitted back from the second circuit to the first circuit. The data transmission system may employ a single-ended signaling system in which the signaling voltage is referenced to a reference voltage that is a power supply voltage such as ground, shared by the first circuit and the second circuit.

Abstract: A decode switch and a method for controlling a decode switch are provided. The decode switch includes a power source providing a first voltage, a source capacitance coupled to the power source, and a target capacitance coupled to the power source. The power source charges the source capacitance to the first voltage. The source capacitance is connected to the target capacitance and the source capacitance charges the target capacitance to a second voltage. The power source charges the target capacitance from the second voltage to the first voltage.

Abstract: A system for managing storage of data units includes a data storage system configured to store multiple data blocks, at least some of the data blocks containing multiple data units, with at least a group of the data blocks being stored contiguously, thereby supporting a first read operation that retrieves data units from at least two adjacent data blocks in the group. The system is configured to perform one or more operations with respect to data units, the operations including a delete operation that replaces a first data block containing a data unit to be deleted with a second data block that does not contain the deleted data unit, with the second data block having the same size as the first data block.

Abstract: Memory systems that provide separate read and write address decoding to support simultaneous memory read and write operations are disclosed. Separating read and write address decoding can avoid circuit conflicts for a simultaneous memory read and write operation even if employing single port memory bit cells. The read and write addresses of respective read and write operations are separately decoded into read and write row and column selects driven to a memory array so that simultaneous read and write operations are not affected by each other. To avoid a circuit conflict for a simultaneous read and write operation, the memory system is configured to prioritize a write row select over a read row select to drive a row of memory bit cells in the memory array. In this manner, that write operation will always be successful regardless of whether the read and write row select are to the same row.

Abstract: Provided is a flash memory device capable of restricting power consumption in an erase operation. The invention includes a plurality of wells, a power supply device, and a coupling device. The power supply device applies erase voltages to the wells for performing an erase operation. The coupling device performs selective coupling between the wells. When performing the erase operation on the wells, the power supply device applies the erase voltage to one of the wells, and applies the erase voltage to the other one of the wells after the coupling device electrically couples the one of the wells to the other one of the wells.

Abstract: According to one embodiment, a memory device is connectable to a host, and includes a nonvolatile memory, a volatile memory which is used as a cache of the nonvolatile memory and has a higher access speed than the nonvolatile memory, and a controller which controls access to the nonvolatile memory and the volatile memory. The controller increments, when the controller receives a refresh command for the volatile memory from the host, a value of a refresh counter, and executes, when the value of the refresh counter exceeds a threshold, no refresh operation corresponding to the refresh command.

Abstract: There are provided a high voltage switch circuit and a semiconductor memory device including the same. A high voltage switch circuit may include a switching circuit including a first depletion transistor and a first high voltage transistor, which are coupled in series between an input terminal and an output terminal, and a control signal generator for applying, to the first depletion transistor, a control signal having the same potential level as an input voltage applied to the input terminal, in response to a first enable signal and a second enable signal.

Abstract: Methods and apparatus to provide dynamic window to improve NAND (Not And) memory endurance are described. In one embodiment, a program-erase window associated with a NAND memory device is dynamically varied by starting with a higher erase verify (TEV) voltage and lowering the TEV voltage with subsequent cycles over a life of the NAND memory device based on a current cycle count value. Alternatively, the program-erase window is dynamically varied by starting with a higher erase verify (PV) voltage and erase verify (TEV) voltage and lowering the PV and TEV voltages with subsequent cycles over a life of the NAND memory device based on the current cycle count value. Other embodiments are also disclosed and claimed.

Abstract: A method of forming a three-dimensional memory device, includes forming a lower stack structure of insulating and first sacrificial material layers over a substrate, forming first memory openings through the lower stack structure and filling the first memory openings with a sacrificial fill material, replacing the first sacrificial material layers with first electrically conductive layers, forming an upper stack structure of insulating and second sacrificial material layers over the lower stack structure after replacing the first sacrificial material layers, forming second memory openings through the upper stack structure in areas overlying the first memory openings, replacing the second sacrificial material layers with second electrically conductive layers, removing the sacrificial fill material from the first memory openings underneath the second memory openings to form inter-stack memory openings after replacing the second sacrificial material layers, and forming memory stack structures within the inter-st

Abstract: A memory device is provided as follows. A memory cell region includes a plurality of blocks, each block including a plurality of NAND strings. A control logic divides the plurality of blocks into a plurality of block regions based on a smaller distance of a first distance with respect to a first edge of the memory cell region and a second distance with respect to a second edge of the memory cell region and controls an operation performed on the memory cell region using a plurality of bias sets of operation parameters for the operation. Each bias set is associated with one of the block regions.

Abstract: An embodiment of a non-volatile memory device is proposed. Said memory device comprises a matrix of memory cells; each memory cell is individually programmable to at least a first logic level and individually erasable to a second logic level. The memory device further comprises partition means for logically subdividing the matrix into a plurality of subspaces; each subspace comprises at least one respective memory cell. The memory device further comprises selection means for selecting a subspace, operative means for performing an operation on all the memory cells of the selected subspace, and means for dynamically modifying the number of subspaces and/or the number of memory cells included in each subspace.

Abstract: When selectively erasing one sub-block, a control circuit applies, in a first sub-block, a first voltage to bit lines and a source line, and applies a second voltage smaller than the first voltage to the word lines. Then, the control circuit applies a third voltage lower than the first voltage by a certain value to a drain-side select gate line and a source-side select gate line, thereby performing the erase operation in the first sub-block. The control circuit applies, in a second sub-block existing in an identical memory block to the selected sub-block, a fourth voltage substantially identical to the first voltage to the drain side select gate line and the source side select gate line, thereby not performing the erase operation in the second sub-block.

Abstract: A method of operating a nonvolatile memory device includes performing a first memory operation on a first memory block of a plurality of memory blocks and a curing operation on a portion of the first memory block when a status signal indicates a ready state of the nonvolatile memory device during an interval equal to or greater than a reference interval after the first memory operation is completed. The nonvolatile memory device includes the plurality of memory blocks, each memory block including a plurality of vertical strings extending in a vertical direction with respect to a substrate.

Abstract: A memory device may include: a cell array comprising a main area and an adjacent area with a plurality of main memory cells disposed in the main area and a plurality of adjacent memory cells disposed in the adjacent area; a control circuit suitable for controlling a row operation and column operation of the cell array; and an adjacent area controller suitable for controlling adjacent memory cells so that the adjacent memory cells are operated under a different condition from the main memory cells.

Abstract: A semiconductor system includes one or more core chips including a plurality of memory banks; one or more replacement storage units; and a base chip suitable for: first detecting a memory bank having an access frequency that satisfies a first condition, second detecting whether an utilization rate of the first detected memory bank satisfies a second condition, and replacing the second detected memory bank with one among the replacement storage units.

Abstract: Provided are a non-volatile memory device, a memory system, and a method of operating the non-volatile memory device. The method includes: performing a user operation according to at least one mode selected from among a writing mode, a reading mode, and an erasing mode with respect to a memory cell array; setting up voltages of a plurality of word lines; floating at least one word line from among the plurality of word lines, the voltages of which are set up, according to the at least one selected mode; and detecting whether the at least one word line has a progressive defect, according to a result of detecting a voltage level of the at least one floated word line.

Abstract: Independent sense amplifier addressing provides separate column addresses to individual sense amplifier groups within a single bay during one column address cycle. A memory system determines whether the individual memory cells or bits of a column at a bay can be skipped. For each sense amplifier group having at least one memory cell (or bit) that needs to be programmed, the system determines for the first column address whether the memory cell can be skipped. If a bit or memory cell having a first column address from the sense amplifier group can be skipped, the system determines a next bit having a column address from the group that needs to be programmed. The system groups the next column address for programming during the first column address cycle. The system can program a different column address for different sense amplifier groups within the bay during a single column address cycle.

Abstract: A data writing method for a rewritable non-volatile memory module, and a memory control circuit unit and a memory storage apparatus using the same are provided. The method includes grouping physical erasing units of the rewritable non-volatile memory module into a temporary area and a storage area. The method also includes selecting a first physical erasing unit from the temporary area, copying a plurality of valid data of the first physical erasing unit to a second physical erasing unit of the temporary area, and performing an erasing operation on the first physical erasing unit. The method further includes selecting a third physical erasing unit from the temporary area, copying a plurality of valid data of the third physical erasing unit to a forth physical erasing unit of the storage area, and performing the erasing operation on the third physical erasing unit.

Abstract: Methods to maintain values representing data in a memory are disclosed. A method may include identifying a plurality of in-use portions of the memory currently used to store data and recording which in-use portion was a last portion of the memory to be rewritten. Responsive to a trigger signal, data is read from a selected one of the in-use portions of the memory adjacent to the last portion. The method may also include storing the read data into a buffer to form buffered data, and rewriting the buffered data into the memory.

Abstract: A semiconductor memory device has a memory block including memory strings with first and second selection transistors at opposite ends of the memory strings. A bit line is connected to the first selection transistor of each memory string and a sense amplifier is connected to the bit line. The memory block includes word lines connected to each memory cell transistor in the memory strings. The memory device also includes a controller to control an erase operation that includes applying an erase voltage to the word lines, addressing a first memory string by applying a selection voltage to a gate electrode of first and second selection transistors of the first memory string, then applying an erase verify voltage to the word lines and using the sense amplifier to read data of memory cell transistors in the first memory string, then addressing a second memory string without first discharging the word lines.

Abstract: A row decoder of the semiconductor memory device includes a decoding and precharging unit that is connected between a high voltage node and a block word line, wherein the decoding and precharging unit precharges the block word line, and wherein the decoding and precharging unit includes one or more decoding transistors that decode an address and form a transmission path for transmitting a block selection voltage. The row decoder further includes a pass transistor block that transmits one or more row driving voltages to row lines in response to the block selection voltage, wherein the block selection voltage is boosted according to a switching operation of the pass transistor block.

Abstract: According to one embodiment, a memory device includes a controller, and a nonvolatile memory in which an erase operation is controlled by the controller, the nonvolatile memory including blocks, the erase operation executing every block, the nonvolatile memory transferring a first reply showing a completion of the erase operation and a fail bit count showing a number of memory cells in which a data erase is uncompleted after the completion of the erase operation to the controller. The controller selects a target block as a target of the erase operation based on the fail bit count.

Abstract: A nonvolatile memory device may include a memory cell array, an address decoder circuit, a page buffer circuit, and a control logic circuit. An erase operation includes iteratively performing an erase loop which includes an erase section where an erase voltage is applied to the memory cells of the selected memory block and an erase verification section where the memory cells of the selected memory block are verified using an erase verification voltage. If the memory cells of the selected memory block are determined as an erase pass in the erase verification section, the control logic circuit monitors the memory cells of the selected memory block. If the monitored result indicates that the memory cells of the selected memory block are at an abnormal state, the control logic circuit applies an extra erase voltage to the memory cells of the selected memory block.

Abstract: A nonvolatile memory system includes first and second nonvolatile memory devices and a memory controller configured to control the first and second nonvolatile memory devices through one channel. During a program operation, the memory controller transmits first signals, for setting first page data up in the first nonvolatile memory device, to the first nonvolatile memory device through the channel. While the first nonvolatile memory device sets up the first page data in response to the first signals, the memory controller transmits second signals, for setting second page data up in the second nonvolatile memory device, to the second nonvolatile memory device.