An X16 nonvolatile memory has 16 input/output (I/O) ports, identified as I/O ports [15:0], and adopts a conversion method, which allows the memory to operate in an X16 mode or in an X8 mode. The method includes receiving a first user command that is sent by an upper computer and belongs to a user mode; determining a disabling command for a module path of the high-bit I/O ports [15:8] according to the first user command; and executing the disabling command and disabling the module path for controlling the high-bit I/O ports [15:8] of the memory so as to operate in an X8 mode.

Apparatuses and methods for decoding addresses for memory are disclosed. An example apparatus includes a memory cell array and a row decoder. The memory cell array includes a bank of memory including a plurality of groups of memory. Each of the groups of memory includes sections of memory, and each of the sections of memory including memory cells arranged in rows and columns of memory. The row decoder decodes addresses to access a first group of memory to include rows of prime memory from a first block of memory and to include rows of prime memory from a second block of memory. The row decoder decodes the addresses to access a second group of memory to include rows of prime memory from the second block of memory and to include rows of redundant memory. The rows of redundant memory are shared with the first and second blocks of memory.

Systems and methods are provided to enhance the functionality of an integrated circuit. Such an integrated circuit may include a primary circuitry and an embedded programmable logic programmable to adjust the functionality of the primary circuitry. Specifically, the embedded programmable logic may be programmed to adjust the functionality of the primary circuitry to complement and/or support the functionality of another integrated circuit. Accordingly, the embedded programmable logic may be programmed with functions such as data/address manipulation functions, configuration/testing functions, computational functions, or the like.

Systems and methods are provided to enhance the functionality of an integrated circuit. Such an integrated circuit may include a primary circuitry and an embedded programmable logic programmable to adjust the functionality of the primary circuitry. Specifically, the embedded programmable logic may be programmed to adjust the functionality of the primary circuitry to complement and/or support the functionality of another integrated circuit. Accordingly, the embedded programmable logic may be programmed with functions such as data/address manipulation functions, configuration/testing functions, computational functions, or the like.

A memory module with multiple memory devices includes a buffer system that manages communication between a memory controller and the memory devices. The memory module additionally includes a command input port to receive command and address signals from a controller and, also in support of capacity extensions, a command relay circuit coupled to the command port to convey the commands and addresses from the memory module to another module or modules. Relaying commands and addresses introduces a delay, and the buffer system that manages communication between the memory controller and the memory devices can be configured to time data communication to account for that delay.

Disclosed are systems and methods involving memory-side write training to improve data valid window. In one implementation, a method for performing memory-side write training may comprise delaying a rising edge or a falling edge of a first data signal, delaying a rising edge or a falling edge of a second data signal, and aligning the two adjusted signals to reduce a window of time that the data signals are not valid and thereby improve or optimize the data valid window (DVW) of a memory array. According to implementations herein, various edges of data signals and clock signals may be adjusted or delayed via dedicated trim cells or circuitry present in the data paths located on the memory side of a system.

An electronic device includes a memory device including first and second ranks, and a system-on-chip that exchanges data with the memory device. The system-on-chip loads a first training code to the first rank and performs a first training operation on the second rank using the first training code loaded to the first rank, and loads the first training code to the second rank and performs a second training operation on the first rank using the first training code loaded to the second rank. The system-on-chip generates a first reference voltage for sampling output data of the first rank, and generates a second reference voltage for sampling output data of the second rank. The first and second reference voltages are generated based on a first result of performing the first training operation on the second rank, and a second result of performing the second training operation on the first rank.

An erasing method is used in a memory device. The memory device includes a string of memory cells and a controller, the string of memory cells including a plurality of special memory cells not for storing data and a plurality of main memory cells for storing data. The erasing method includes: the controller verifying if at least one special memory cell of the plurality of special memory cells has failed; the controller resetting the at least one special memory cell if the at least one special memory cell has failed; and the controller erasing the plurality of main memory cells.

A memory chip including a memory bank, an address decoder circuit and a control circuit is provided. The memory bank includes a first sub-bank coupled to a first word line and a first access line and a second sub-bank coupled to a second word line and the first access line. The first sub-bank outputs data to the first access line via a first path. The second sub-bank outputs data to the first access line via a second path. The address decoder circuit decodes an external address to generate a row address and a column address. The control circuit controls the first path and the second path according to the row address and the column address. In response to the row address indicating the first word line and the column address indicating the first access line, the control circuit turns on the first path and turns off the second path.

A semiconductor memory device includes a cell wafer including a first plane and a second plane which are disposed to be adjacent to each other in a first direction and each include a plurality of memory cells; and a peripheral wafer including a row decoder which simultaneously controls the first and second planes and first and second page buffer circuits which control the first and second planes, respectively. The cell wafer includes, on one surface thereof bonded to the peripheral wafer, a first pad which is coupled in common with the first plane and the second plane, and the peripheral wafer includes, on one surface thereof bonded to the cell wafer, a second pad which is coupled with the row decoder and is bonded to the first pad.