Methods, systems, and devices supporting an interface for refreshing non-volatile memory are described. In some examples, a host system may communicate with a memory system, where both the host system and the memory system may be included within a vehicle (e.g., an automotive system). The host system may receive an indication that the vehicle is powering down (e.g., shutting off an engine or lowering power output from a battery). The host system may switch from a first mode corresponding to a first power usage to a second mode corresponding to a second, lower power usage in response to the vehicle powering down, the second mode supporting initiation of a refresh operation at the memory device. The host system may transmit a refresh command to the memory system to refresh non-volatile memory while the vehicle is powered down if the host system is operating in the second mode of operation.

A memory system may improve the endurance and performance of a plurality of memories included in the memory system mounted on a server system or a data processing system. For example, the memory system may throttle energy of a first memory using a second memory having a different characteristic from the first memory, control accesses to a memory region according to a refresh cycle, and control accesses to memories having different temperatures according to a priority of a request for each of the memories.

A memory device includes a memory cell array having a plurality of memory cells connected to wordlines and bitlines, a target row refresh logic configured to perform a refresh operation on at least one of target rows of the memory cell array in response to a refresh management mode command, a weak pattern detector that is activated according to a register update bit value included in the refresh management mode command and that outputs a risk level for each of the target rows, and a mode register circuit that updates at least one mode register value according to the risk level.

A media management operation can be performed at a memory sub-system at a current frequency. An operating characteristic associated with the memory sub-system can be identified. The operating characteristic can reflect at least one of a write count, a bit error rate, or a read-retry trigger rate. A determination can be made as to whether the identified operating characteristic satisfies an operating characteristic criterion. In response to determining that the operating characteristic satisfies the characteristic criterion, the media management operation can be performed at a different frequency relative to the current frequency.

An electronic device includes a drive control signal generation circuit and an internal voltage drive circuit. The drive control signal generation circuit detects a level of an internal voltage to generate a drive control signal that adjusts a level of the internal voltage. The internal voltage drive circuit drives the internal voltage based on the drive control signal.

The present description relates to a method and a circuit for powering a volatile memory in which power pulses are sent to the memory, the duration between two pulses being shorter than a remanence time of said volatile memory.

A method for performing a refresh operation based on system characteristics is provided. A The method includes determining that a current operation condition of a memory component is in a first state and detecting a change in the operation condition from the first state to a second state. The method further includes determining a range of the operation condition to which the second state belongs. The method further includes determining a refresh period associated with the range of the operation condition, the refresh period corresponding to a period of time between a first time when a write operation is performed on a segment of the memory component and a second time when a refresh operation is to be performed on the segment. The method further includes performing the refresh operation on the memory component according to the refresh period.

A block of dynamic memory in a DRAM device is organized to share a common set of bitlines may be erased/destroyed/randomized by concurrently activating multiple (or all) of the wordlines of the block. The data held in the sense amplifiers and cells of an active wordline may be erased by precharging the sense amplifiers and then writing precharge voltages into the cells of the open row. Rows are selectively configured to either be refreshed or not refreshed. The rows that are not refreshed will, after a time, lose their contents thereby reducing the time interval for attack. An external signal can cause the isolation of a memory device or module and initiation of automatic erasure of the memory contents of the device or module using one of the methods disclosed herein. The trigger for the external signal may be one or more of temperature changes/conditions, loss of power, and/or external commands from a controller.

Managing a temperature of a memory element of an information handling system, the method comprising: identifying a lower temperature boundary of the memory element; determining an initial temperature of the memory element; determining whether the initial temperature is less than the lower temperature boundary; in response to determining that the initial temperature is less than the lower temperature boundary: performing a series of repeated burst refresh operations at the memory element; after performing the series of repeated burst refreshes operations, determining an updated temperature of memory element; determining whether the updated temperature is less than the lower temperature boundary; and in response to determining that the updated temperature is greater than the lower temperature boundary, performing a normal boot of the memory element.

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.