Methods, systems, and devices for extended error detection for a memory device are described. For example, during a read operation, the memory device may perform an error detection operation capable of detecting single-bit errors, double-bit errors, and errors that impact more than two bits and indicate the detected error to a host device. The memory device may use parity information to perform an error detection procedure to detect and/or correct errors within data retrieved during the read operation. In some cases, the memory device may associate each bit of the data read during the read operation with two or more bits of parity information. For example, the memory device may use two or more sets of parity bits to detect errors within a matrix of the data. Each set of parity bits may correspond to a dimension of the matrix of data.

A memory device includes a memory, and a processor coupled to the memory and configured to hold memory information corresponding to the memory, access information corresponding to access to the memory, and storage information indicating a storage area of the access information, extract, based on the storage information, an access information code including the access information, output the memory information in response to a read request from an external, and output the extracted access information code in response to an acknowledgment received from the external corresponding to the memory information.

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.

Memory having an array of memory cells and a plurality of access lines each connected to a respective plurality of memory cells of the array of memory cells might include a controller configured to cause the memory to apply a respective programming pulse having a first target voltage level and a first pulse width to each access line of a first subset of access lines of the plurality of access lines, and apply a respective programming pulse having the first target voltage level and a second pulse width longer than the first pulse width to each access line of a second subset of access lines of the plurality of access lines, wherein each access line of the first subset of access lines is nearer a particular end of the string of series-connected memory cells than each access line of the second subset of access lines.

A memory controller is capable of issuing a first write command for writing data of a predetermined size in a DRAM, and a second write command for writing data of a size smaller than the predetermined size in the DRAM. The memory controller comprises a receiving unit configured to receive a request to the DRAM from a bus; a determining unit configured to determine whether a command that is after the second write command when a reception sequence of a request is observed is issuable in a period until the second write command is issued after a preceding command is issued; and an issuing unit configured to issue a command determined to be issuable before the second write command.

In described examples, a memory controller circuit controls accesses to an SRAM circuit. Precharge mode control circuitry outputs: a burst mode enable signal to the SRAM circuit indicating that a series of SRAM cells along a selected row of SRAM cells will be accessed; a precharge first mode signal to the SRAM circuit indicating that a first access along the selected row will occur; and a precharge last mode signal to the SRAM circuit indicating that a last access along the selected row will occur. The SRAM circuit includes an array of SRAM cells arranged in rows and columns to store data. Each SRAM cell is coupled to: a corresponding word line along a row of SRAM cells; and a corresponding pair of complementary bit lines.

A method for addressing memory device data arranged in rows and columns indexed by a first number of row address bits and a second number of column address bits, and addressed by a row command specifying a third number of row address bits followed by a column command specifying a fourth number of column address bits, the first number being greater than the third number or the second number being greater than the fourth number, includes: splitting the first number of row address bits into first and second subsets, and specifying the first subset in the row command and the second subset in a next address command when the first number is greater than the third number; otherwise splitting the second number of column address bits into third and fourth subsets, and specifying the fourth subset in the column command and the third subset in a previous address command.

Apparatuses and methods for writing data to a memory array are disclosed. When data is duplicative across multiple data lines, data may be transferred across a single line of a bus rather than driving the duplicative data across all of the data lines. The data from the single data line may be provided to the write amplifiers of the additional data lines to provide the data from all of the data lines to be written to the memory. In some examples, error correction may be performed on data from the single data line rather than all of the data lines.

A semiconductor system includes a memory controller and a memory apparatus. The memory controller provides at least first to third command address signals. The memory apparatus performs a burst read operation based on the first and second command address signals, and terminates the burst read operation by receiving the third command address signal twice. The memory apparatus continuously initializes an internal circuit that is performing the burst read operation in a section the third command address signal is received twice.

Devices and methods include a command input configured to receive a command for a memory device. Second stage wakeup circuitry configured to receive a portion of the command and output an indication of whether the command is a non-burst command based on the portion. Clock gating circuitry is configured to receive an input clock and a wake signal. The clock gating circuitry is also configured to output an internal clock based at least in part on a pulse of the received wake signal. The clock gating circuitry also is configured to maintain the output of the internal clock for a duration based on the indication with the duration being shorter when the indication indicates that the command is a non-burst command.