Apparatuses and techniques for operating devices with multiple differential write clock signals having different phases are described. For example, a memory controller (e.g., of a host device) can provide two differential write clock signals to a memory device over an interconnect. The two differential write clock signals may have a phase offset of approximately ninety degrees. Instead of generating its own phase-delayed write clock signals using a component (e.g., a clock divider circuit) that can enter the metastable state, the memory device can use the multiple differential write clocks signals provided by the memory controller to process memory requests.

An integrated circuit for storing data comprises a memory cell array comprising a plurality of bit cells (BC1, . . . , BCn) comprising a first and a second one of the bit cells (BC1, BC2) having a static random access memory architecture. The first and the second bit cells (BC1, BC2) are coupled to a common wordline (WL_TOP) and are arranged in different columns (C1, C2) of the memory cell array (100). During a write access to the first bit cell (BC1), the first bit cell (BC1) undergoes a write operation, whereas the second bit cell (BC2) is a half-selected bit cell which undergoes a pseudo read operation. The integrated circuit uses a two-phase write scheme to improve the write-ability in low operating voltage environment.

Techniques herein may allow a row of a subarray in a bank of a memory device to be activated before a precharge operation has been completed for a previously opened row of memory cells in the same bank. Each subarray within the bank may be associated with a respective local latching circuit, which may be used to maintain phases at the subarray independent of subsequent commands to the same bank. For example, the latching circuit may internalize timing signals triggered by a precharge command for a first row such that if an activation command is received for a different subarray in the same bank at a time before the precharge operation of the first row is complete, the precharge operation may continue until the first row is closed, as the timing signals triggered by the precharge command may be maintained locally at the subarray using the latching circuit.

A data writing control device includes a control signal generator, a data strobe enable signal generator and a data strobe index generator. The control signal generator receives a write command, a preamble setting value and a latency setting value, and generates an internal write pulse and preamble information according to the write command, the preamble setting value and the latency setting value. The data strobe enable signal generator is coupled to the control signal generator and generates a data strobe pipeline enable signal according to the internal write pulse and the preamble setting value. The data strobe index generator is coupled to the data strobe enable signal generator, and generates a plurality of data strobe indexes according to the data strobe pipeline enable signal and the preamble information.

Methods, systems, and devices for detection of illegal commands are described. A memory device, such as a dynamic random access memory (DRAM), may receive a command from a device, such as a host device, to perform an access operation on at least one memory cell of a memory device. The memory device may determine, using a detection component, that a timing threshold associated with an operation of the memory device would be violated by performing the access operation. The memory device may refrain from executing the access operation based on determining that performing the access operation included in the command would violate the timing threshold. The memory device may transmit, to the device, an indication that performing the command would violate the timing threshold.

Systems and methods for processing commands at a random access memory. A series of commands are received to read data from the random access memory or to write data to the random access memory. The random access memory can process commands at a first rate when the series of commands matches a pattern, and at a second, slower, rate when the series of commands does not match the pattern. A determination is made as to whether the series of commands matches the pattern based on at least a current command and a prior command in the series of commands. A ready signal is asserted when said determining determines that the series of commands matches the pattern, where the random access memory is configured to receive and process commands faster than the second rate when the pattern is matched and the ready signal is asserted over a period of multiple commands.

A determination that a first programming operation has been performed on a particular memory cell can be made. A determination can be made, based on one or more threshold criteria, whether the particular memory cell has transitioned from a state associated with a decreased error rate to another state associated with an increased error rate. In response to determining that the particular memory cell has transitioned from the state associated with the decreased error rate to the another state associated with the increased error rate, an operation can be performed on the particular memory cell to transition the particular memory cell from the another state associated with the increased error rate to the state associated with the decreased error rate.

Apparatuses, systems, and methods for error correction. A memory device may have a number of memory cells each of which stores a bit of information. A first latch may hold the encoded bit and provide it as a write parity bit to the memory array as part of a write operation. A second latch may hold a parity bit read from the memory array and the ECC circuit may generate a command signal based on that parity bit. A multiplexer latch may hold the encoded bit and provide a syndrome bit based on the command signal and the encoded bit. The syndrome bit may indicate if there is mismatch between the parity bit and the encoded bit. The logic which handles generating the syndrome bit may be separated from the logic tree.

An access method for a DRAM is provided. A plurality of portions of a row address of a bank corresponding to a activate command is provided. A plurality of sub-commands of the activate command are provided via a command bus, and a plurality of portions of address information regarding the portions of the row address are provided via an address bus. Each portion of the address information includes an individual portion of the row address of the bank. Each first sub-command corresponds to an individual address information. A specific sub-command of the activate command is provided via the command bus, and address information regarding a specific portion of the row address is provided. An access command corresponding to the bank is provided via the command bus after the sub-commands are provided.

A method for writing to electrically erasable and programmable non-volatile memory and a corresponding integrated circuit are disclosed. In an embodiment a method includes operatively connecting a filter circuit belonging to a communication interface to an oscillator circuit, wherein the communication interface is physically connected to a bus, generating, by the oscillator circuit, an oscillation signal and regulating the oscillation signal by the filter circuit so as to generate a clock signal for timing a write cycle.