Memory devices and systems with configurable die refresh stagger, and associated methods, are disclosed herein. In one embodiment, a memory system includes two or more memory dies. At least one memory die includes a fuse array storing refresh information that specifies a refresh group of the memory die. In these and other embodiments, at least one memory die includes a refresh group terminal and refresh group detect circuitry electrically connected to the refresh group terminal. The at least one memory die is configured to detect a refresh group of the memory die and to delay its refresh operation by a time delay corresponding to the refresh group. In this manner, refresh operations of the two or more memory dies can be staggered to reduce peak current demand of the memory system.

A refresh circuit includes: a signal generation module, configured to generate an inversion signal and a carry signal based on a refresh command; an adjustment unit, configured to generate, if a first refresh signal and a second refresh signal are generated based on the refresh command, an inversion adjustment signal according to the inversion signal, and generate, if only the first refresh signal is generated based on the refresh command, the inversion adjustment signal according to an inversion signal corresponding to a first refresh signal generated based on a current refresh command, and generate the inversion adjustment signal only according to an inversion signal corresponding to a second refresh signal generated based on a next refresh command; and a counting module, configured to generate a first output signal and a second output signal, and invert the first output signal based on the inversion adjustment signal.

A memory device may include: a memory bank comprising a plurality of memory blocks, each divided into a normal area and a row hammer area, a command control circuit suitable for performing an access operation on the normal area in response to an active command, an internal command generation circuit suitable for generating an internal command in response to a precharge command, a target address generation circuit suitable for saving a count for each logic level combination of a received address in the row hammer area by performing an access operation on the row hammer area in response to the internal command, and setting an address corresponding to the count as a target address when the count satisfies a preset condition, and a refresh control circuit suitable for controlling a smart refresh operation on the target address.

A semiconductor memory device having a flexible refresh skip area includes a memory cell array including a plurality of rows to store data, a row decoder connected to the memory cell array, a refresh area storage unit to store a beginning address and an end address of a memory area that is to be refreshed in which the memory area that is to be refreshed does not include a refresh skip area having a size is selectively and/or adaptively changed, and a refresh control circuit connected to the row decoder and the refresh area storage unit. The refresh control circuit controls a refresh operation for the area that is to be refreshed and not for the refresh skip area.

In a conventional memory subsystem, a memory controller issues explicit refresh commands to a DRAM memory device to maintain integrity of the data stored in the memory device when the memory device is in an auto-refresh mode. A significant amount of power may be consumed to carry out the refresh. To address this and other issues, it is proposed to allow a partial refresh in the auto-refresh mode in which the refreshing operation may be skipped for a subset of the memory cells. Through such selective refresh skipping, the power consumed for auto-refreshes may be reduced. Operating system kernels and memory drivers may be configured to determine areas of memory for which the refreshing operation can be skipped.

A data storage device may include a storage including a plurality of storage regions each composed of a plurality of pages; and a controller. The controller is configured to select a plurality of target open regions from open regions among the storage regions on the basis of health information of the open regions, in each of which a programmed page and an unprogrammed page coexist, and perform control so that refresh operations for the respective target open regions are performed in a time-distributed manner.

A memory device includes a memory cell array, a row select circuit, a refresh controller and a memory control logic. The memory cell array includes memory cells arranged in rows and columns. The row select circuit is connected to the rows. The refresh controller controls the row select circuit to apply a refresh operating voltage to one or more rows. The memory control logic decodes a command received from a memory controller and outputs a refresh command and external refresh address information. The refresh controller controls the row select circuit to perform one of an external refresh operation and an internal refresh operation, based on the refresh command that is output from the memory controller and based on whether a first row-hammering row address of the internal refresh operation is identical with a second row-hammering row address of the external refresh operation.

A memory device according to some aspects of the inventive concepts includes a memory cell array including a plurality of banks, at least one Processing Element (PE) connected to at least one bank selected from the plurality of banks, and a control logic configured to control an active operation in which wordlines included in each of the plurality of banks is activated, and configured to control a refresh operation in which at least one bank is refreshed, based on a PE enable signal configured to selectively enable the at least one PE.

Apparatuses, systems, and methods for reset of row hammer detector circuits. A row hammer detector circuit includes a hash circuit configured to store a hash key and provide a first count value based on a hash between the hash key and a row address corresponding to a row of memory cells of a memory array. The row hammer detector circuit is configured to provide a match signal in response to the count value exceeding a threshold to cause a targeted refresh of a victim row adjacent the row of memory cells. In response to exit from a self-refresh mode, the hash circuit is configured to update the stored hash key with a new hash key.

Apparatuses and methods for pure-time, self-adopt sampling for RHR refresh. An example apparatus includes a memory bank comprising a plurality of rows each associated with a respective row address, and a sampling timing generator circuit configured to provide a timing signal having a plurality of pulses. Each of the plurality of pulses is configured to initiate sampling of a respective row address associated with a row of the plurality of rows to detect a row hammer attack. The sampling timing generator includes first circuitry configured to provide a first subset of pulses of the plurality of pulses during a first time period and includes second circuitry configured to initiate provision of a second subset of pulses of the plurality of pulses during a second time period after the first time period.