Aggressor rows may be detected by comparing access count values of word lines to a threshold value. Based on the comparison, a word line may be determined to be an aggressor row. The threshold value may be dynamically generated, such as a random number generated by a random number generator. In some examples, a random number may be generated each time an activation command is received. Responsive to detecting an aggressor row, a targeted refresh operation may be performed.

A memory device includes an array of memory cells configured on a die or chip and coupled to sense lines and access lines of the die or chip and a respective sense amplifier configured on the die or chip coupled to each of the sense lines. Each of a plurality of subsets of the sense lines is coupled to a respective local input/output (I/O) line on the die or chip for communication of data on the die or chip and a respective transceiver associated with the respective local I/O line, the respective transceiver configured to enable communication of the data to one or more device off the die or chip.

A memory performs a sequence of ECS operations to read a codeword, detect and correct any errors, and write the corrected codeword back to the memory array. An ECS circuit counts errors which are detected, and sets a value of one or more ECS registers in a mode register if the count exceeds a threshold filter at the end of the ECS cycle. The memory also includes a forced ECS readout circuit, which responsive to a command, for example from a controller, sets the value(s) in the ECS register(s).

Memory with partial bank refresh is disclosed herein. In one embodiment, a memory system includes a memory controller and a memory device operably connected to the memory controller. The memory device includes (i) a memory array having a memory bank with a plurality of memory cells arranged in a plurality of memory rows and (ii) circuitry. In some embodiments, the circuitry is configured to disable at least one memory row of the memory bank from receiving refresh commands such that memory cells of the at least one memory row are not refreshed during refresh operations of the memory device. In some embodiments, the memory controller is configured to track memory rows that include utilized memory cells and/or to write data to the memory rows in accordance with a programming sequence of the memory device.

A sub-sense amplifier includes a semiconductor substrate, a first pair of complementary transistors, a second pair of complementary transistors, and at least one ground transistor. The first pair and second pair of complementary transistors and the ground transistor are formed on the semiconductor substrate. The first pair of complementary transistors are disposed in line symmetry with a center line of the sub-sense amplifier as a symmetry axis, and gates of the first pair of complementary transistors are coupled to a node. The second pair of complementary transistors are also disposed in line symmetry with the center line, wherein the current directions of the second pair of complementary transistors are the same. Sources and drains of the first pair of complementary transistors are coupled to gates and sources of the second pair of complementary transistors, respectively. The ground transistor connects in series with the second pair of complementary transistors.

A memory device includes memory cells connected to a first word-line, wherein the memory cells include a data region in which data is stored and a counting value backup region in which the number of times the first word-line is activated is backed up, a counting table for storing a first row address corresponding to the first word-line and a first counting value as a counting result of the number of times the first word-line is activated, and a comparator configured to compare the first counting value with a first backed-up counting value stored in the counting value backup region; and when the first counting value is greater than the first backed-up counting value, back up the first counting value in the counting value backup region, or when the first backed-up counting value is greater than the first counting value, overwrite the first backed-up counting value into the counting table.

An input sampling method includes the following operations. A first pulse signal and a second pulse signal are received. Logical operation is performed on the first pulse signal and the second pulse signal to determine a to-be-sampled signal. The to-be-sampled signal is obtained by shielding an invalid part of the second pulse signal according to a logical operation result. Sampling process is performed on the to-be-sampled signal to obtain a target sampled signal.

Apparatus and methods for soft post package repair are disclosed. One such apparatus can include memory cells in a package, volatile memory configured to store defective address data responsive to entering a soft post-package repair mode, a match logic circuit and a decoder. The match logic circuit can generate a match signal indicating whether address data corresponding to an address to be accessed matches the defective address data stored in the volatile memory. The decoder can select a first group of the memory cells to be accessed instead of a second group of the memory cells responsive to the match signal indicating that the address data corresponding to the address to be accessed matches the defective address data stored in the volatile memory. The second group of the memory cells can correspond to a replacement address associated with other defective address data stored in non-volatile memory of the apparatus.

An operating method for a dynamic random access memory (DRAM) obtains a plurality of first sub-commands of a first activate command via a command bus, and obtaining a plurality of first address information regarding a plurality of first portions of a first row address of a specific bank via an address bus. Each of the first sub-commands corresponds to an individual first portion of the first row address of the specific bank. The method further combines the first portions of the first row address of the specific bank in response to a specific sub-command of the first sub-commands, so as to obtain a first complete row address; and obtains an access command via the command bus.

A sense amplifier includes a sense amplifying unit, first and second isolation units, and first and second offset cancellation unit. The sense amplifying unit includes a first P-type metal-oxide-semiconductor (PMOS) transistor, a second PMOS transistor, a first N-type metal-oxide-semiconductor (NMOS) transistor, and a second NMOS transistor. In a layout of the sense amplifier, the first and second PMOS transistors are disposed in a central region of the sense amplifier, the first and second NMOS transistors are disposed at opposite sides of the sense amplifier from each other, the first isolation unit and the first offset cancellation unit are disposed between the first PMOS transistor and the first NMOS transistor, and the second isolation unit and the second offset cancellation unit are disposed between the second PMOS transistor and the second NMOS transistor. In other layouts, the locations of the PMOS transistors and NMOS transistors may be reversed.