According to one embodiment, a memory system includes: a controller configured to execute an error correction process on first data read from a first area at a first address of a memory device and determine a read level used for reading data at the first address according to a result of the correction process. The controller executes the correction process on first frame data of the first data. When the correction process on the first frame data has failed, the controller executes the correction process on second frame data of the first data. When the correction process on the second frame data has succeeded, the controller determines the read level based on a result of comparison between the second frame data and a result of the correction process on the second frame data.

The present technology relates to a semiconductor memory device and a method of operating the same. The semiconductor memory device includes a memory block including memory cells, a peripheral circuit configured to program the memory cells in a set program state during a test operation and perform a test erase voltage application operation on the memory cells programmed in the set program state, and control logic configured to control the peripheral circuit to count abnormal memory cells of which a threshold voltage is less than a set threshold voltage among the memory cells.

A method includes performing a first read operation involving a set of memory cells using a first voltage, determining a quantity of bits associated with the set of memory cells based on the first read operation, performing a second read operation involving the set of memory cells using a second voltage that is greater than the first voltage when the quantity of bits is above a threshold quantity of bits for the set of memory cells, and performing the second read operation involving the set of memory cells using a third voltage that is less than the first voltage when the quantity of bits is below the threshold quantity of bits for the set of memory cells.

Methods of optimizing the placement of memories in a memory device including a substrate and an electrical component, and associated devices and systems, are disclosed herein. A representative method includes first testing the memories to determine at least one parameter for each of the memories indicating an ability of the memory to process signals from the electrical component. The method can further include labeling each memory with a label based on the parameter, the labels including at least a first label and a second label. The first label can indicate that the memories with the first label are better able to process signals from the electrical component than the memories with the second label. The method can further include electrically coupling the memories to the substrate such that the memories with the second label are positioned closer to the electrical component than the memories with the first label.

Methods, systems, and devices for imprint recovery management for memory systems are described. In some cases, memory cells may become imprinted, which may refer to conditions where a cell becomes predisposed toward storing one logic state over another, resistant to being written to a different logic state, or both. Imprinted memory cells may be recovered using a recovery or repair process that may be initiated according to various conditions, detections, or inferences. In some examples, a system may be configured to perform imprint recovery operations that are scaled or selected according to a characterized severity of imprint, an operational mode, environmental conditions, and other factors. Imprint management techniques may increase the robustness, accuracy, or efficiency with which a memory system, or components thereof, can operate in the presence of conditions associated with memory cell imprinting.

Methods, systems, and devices for memory operations are described. A command may be received by a memory device and from a device. Both the device and the memory device may maintain counters of valid operations. A request for a value associated with a counter at the memory device may be received from the device. Based on receiving the request, a value of the counter may be transmitted to the device. The values of the counters may be compared to determine whether invalid data has been obtained by the device. Also, a pin associated with communicating error correction information may be coupled with a voltage source based on receiving a signal. The pin may remain coupled with the voltage source until a command is processed or an end of the signal. Whether the pin is coupled with the voltage source may indicate a validity of associated data.

A non-volatile memory device includes a plurality of wordlines, each comprising a plurality of cells, a hard decode configured to read each cell of the plurality of cells at a hard decode voltage, a left read sense configured to read voltage values of each cell to the left of the hard decode voltage at a left read sense voltage, a right read sense configured to read voltage values of each cell to the right of the hard decode voltage at a right read sense voltage, a first combiner configured to determine a difference of voltage values read by the left read sense and right read sense to produce a dispersion signal, and a second combiner configured to determine a sum of the voltage values read by the left read sense and right read sense to produce a deviation signal.

Apparatuses and techniques are presented for detecting bit line open circuits and short circuits in a memory device in which a memory die is inverted and bonded to a control die. In one approach, the control die comprises a set of bit lines which are connected to a set of bit lines of the memory die, and the set of bit lines of the control die comprise ground transistors, e.g., transistors connected to a ground node. Ground transistors of even-numbered bit lines may be commonly controlled, while ground transistors of odd-numbered bit lines are commonly controlled. The ground transistors may be controlled to detect open circuits and short circuits in the bit lines of the control die and the memory die. A laser scanning technique can also be used to determine a physical location of a defect of a bit line.

A semiconductor chip may include a memory, a power supply line, a noise generator and a switch. The power supply line may include first and second power supply line portions. The power supply line may be configured to provide a power supply signal through each of the first power supply line portion and the second power supply line portion. The noise generator may be connected to the second power supply line portion. The noise generator may be configured to receive the power supply signal from the second power supply line portion, and output a noisy power supply signal based on the power supply signal. The switch may be coupled to the memory, the first power supply line portion, and the noise generator. The switch may be configured to selectively electrically connect the memory to one of the first power supply line portion and the noise generator.

A predefined data pattern is written using a plurality of values of a memory access parameter. A corresponding value of a data state metric associated with each value of a plurality of values of the memory access operation parameter is measured. An optimal value of the memory access operation parameter is selected from the plurality of values of the memory access operation parameter.