A semiconductor memory training method includes: selecting two adjacent reference voltages from a plurality of reference voltages as a first reference voltage and a second reference voltage; obtaining a first minimum margin value for the plurality of target signal lines under the first reference voltage; obtaining a second minimum margin value for the plurality of target signal lines under the second reference voltage, according to a minimum margin value for each target signal line under the second reference voltage; determining a target interval for an expected margin value according to the first minimum margin value and the second minimum margin value, the expected margin value being the maximum one among the minimum margin values for the plurality of target signal lines under the plurality of reference voltages; and searching for the expected margin value in the target interval.

A memory apparatus and an initialization method thereof are provided. The initialization method includes the following steps. A power-up operation is performed on the memory apparatus to provide an internal voltage to a memory array. After the internal voltage is stabilize, a refresh operation is performed on all storage cells.

A memory apparatus and an initialization method thereof are provided. The initialization method includes the following steps. A power-up operation is performed on the memory apparatus to provide an internal voltage to a memory array. After the internal voltage is stabilize, a refresh operation is performed on all storage cells.

An electronic device includes a semiconductor memory device configured to store process information and to output the process information to the outside; and a host configured to read the process information from the semiconductor memory device, and to select one of a plurality of operation modes depending on the process information so as to be set to an operation mode of the semiconductor memory device. The plurality of operation modes may define one or more of power consumption of the semiconductor memory device or a response characteristic of the semiconductor memory device.

A method for performing stutter of dynamic random access memory (DRAM) where a system on a chip (SOC) initiates bursts of requests to the DRAM to fill buffers to allow the DRAM to self-refresh is disclosed. The method includes issuing, by a system management unit (SMU), a ForceZQCal command to the memory controller to initiate the stutter procedure in response to receiving a timeout request, such as an SMU ZQCal timeout request, periodically issuing a power platform threshold (PPT) request, by the SMU, to the memory controller, and sending a ForceZQCal command prior to a PPT request to ensure re-training occurs after ZQ Calibration. The ForceZQCal command issued prior to PPT request may reduce the latency of the stutter. The method may further include issuing a ForceZQCal command prior to each periodic re-training.

A method for operating a memory system includes: collecting, by a memory controller, information on rows that are determined as row-hammer-attacked in a memory by the memory controller; collecting, by the memory, information on rows that are determined as row-hammer-attacked by the memory; confirming, by the memory, that the row collected by the memory controller is the same as the row collected by the memory; and resetting, by the memory, information on the row collected by the memory which is the same as the row collected by the memory controller in response to the confirmation.

Control logic in a memory device determines to initiate a string read operation on a first memory string of a plurality of memory strings in a block of a memory array of the memory device, the block comprising a plurality of wordlines, wherein each of the plurality of memory strings comprises a plurality of memory cells associated with the plurality of wordlines, and wherein the first memory string is designated as a sacrificial string. The control logic further causes a read voltage to be applied to each of the plurality of wordlines of the memory array concurrently and senses a level of current flowing through the first memory string designated as the sacrificial string while the read voltage is applied to each of the plurality of wordline. In addition, the control logic identifies, based on the level of current flowing through the first memory string designated as the sacrificial string, whether a threshold level of read disturb has occurred on the block.

Control logic in a memory device determines to initiate a string read operation on a first memory string of a plurality of memory strings in a block of a memory array of the memory device, the block comprising a plurality of wordlines, wherein each of the plurality of memory strings comprises a plurality of memory cells associated with the plurality of wordlines, and wherein the first memory string is designated as a sacrificial string. The control logic further causes a read voltage to be applied to each of the plurality of wordlines of the memory array concurrently and senses a level of current flowing through the first memory string designated as the sacrificial string while the read voltage is applied to each of the plurality of wordline. In addition, the control logic identifies, based on the level of current flowing through the first memory string designated as the sacrificial string, whether a threshold level of read disturb has occurred on the block.

An integrated circuit (IC) memory controller is disclosed. The memory controller includes a receiver to receive a strobe signal and provide an internal strobe signal. An adjustable delay circuit delays an enable signal to generate a delayed enable signal. A gate circuit generates a gated strobe signal using the delayed enable signal that masks transitions of the internal strobe signal that occur prior to a valid region of the internal strobe signal. A sample circuit samples data using the gated strobe signal.

An integrated circuit (IC) memory controller is disclosed. The memory controller includes a receiver to receive a strobe signal and provide an internal strobe signal. An adjustable delay circuit delays an enable signal to generate a delayed enable signal. A gate circuit generates a gated strobe signal using the delayed enable signal that masks transitions of the internal strobe signal that occur prior to a valid region of the internal strobe signal. A sample circuit samples data using the gated strobe signal.