Embodiments of the present disclosure provide a memory detection method and detection apparatus, for detecting a current-leakage bitline. The method includes: a memory including a plurality of memory cells, a plurality of sense amplifiers, and the sense amplifier including a power line providing a low potential voltage and a power line providing a high potential voltage; writing first memory data to each of the memory cells; performing a reading operation after the first memory data is written; acquiring a first test result based on a difference between first real data and the first memory data; performing the reading operation again to read second real data in each of the memory cells; acquiring a second test result based on a difference between the second real data and second memory data; and acquiring a specific position of the current-leakage bitline based on the second test result and the first test result.

Systems and methods are provided for tracking read reference voltages used for reading data in a non-volatile storage device. A method may comprise collecting pre-decoding state information for a read reference voltage by reading data stored in a non-volatile storage device using the read reference voltage, collecting post-decoding state information for the read reference voltage after decoding the data, generating a comparison of probability of state errors for the read reference voltage based on the pre-decoding state information and post-decoding state information, obtaining an adjustment amount to the read reference voltage based on the comparison of probability of state errors; and adjusting the read reference voltage by applying the adjustment amount to the read reference voltage to obtain an adjusted read reference voltage.

According to one embodiment, an arithmetic device includes a first computational circuit including a first string, the first string having a first magnetoresistive effect element on a first conducting layer; a second computational circuit including a second strings, the second string having second magnetoresistive effect element on a second conducting layer; a third computational circuit executing computational processing using a first signal from the first computational circuit and a second signal from the second computational circuit; and a control circuit. The control circuit sets a condition on write operations with respect to at least one of the first and second magnetoresistive effect elements, based on information related to write error in at least one of the first and second magnetoresistive effect elements.

Devices, systems and methods for improving performance of a memory device are described. An example method includes receiving one or more parameters associated with a plurality of previous read operations on a page of the memory device, wherein the previous read operations are based on a plurality of read voltages, determining, using the one or more parameters as an input to a deep neural network comprising a plurality of layers, an updated plurality of read voltages, wherein each of the plurality of layers is a fully connected layer, and applying the updated plurality of read voltages to the memory device to retrieve information from the memory device, wherein the deep neural network uses a plurality of weights that have been processed using at least one of (a) a pruning operation, (b) a non-uniform quantization operation, or (c) a Huffman encoding operation.

A method for read reference voltage calibration of a non-volatile memory, NVM, such as flash memory, particularly of the NAND type, comprises: Reading from the NVM predetermined reference data stored therein and being encoded with an error correction code, ECC, wherein the reading is performed when a read reference voltage of the NVM, which is used as a reference voltage, such as a threshold voltage, for the reading, is set at a defined voltage level; decoding the read data and observing a number of bit errors, e.g., in a codeword, of the read data in relation to the reference data; and defining a new voltage level of the read reference voltage for a subsequent reading of data from the NVM based on the observed number of bit errors and setting the read reference voltage to the defined new voltage level.

A deterioration detection device includes a storage including a first current path and a second current path and configured such that a current is applied to the first current path and the second current path, a storage input control unit configured to compare an internal operating condition of a memory device with a target condition in a first operating mode and to select one of the first current path and the second current path of the storage based on a result of the comparison, and an output unit configured to output an output signal indicated deterioration, accumulated in one of the first current path and the second current path, in a second operating mode.

A semiconductor structure is provided. The semiconductor structure includes a transistor and a memory device. The transistor includes a source, a drain, and a gate. The memory device is disposed at a drain side of the transistor and coupled to the drain. The memory device includes a first electrode, a switch layer, a memory layer, and a second electrode disposed sequentially. The first electrode is coupled to the drain.

A system and method of storing and reading digital data, including providing a nanopore polymer memory (NPM) device having at least one memory cell comprising at least two addition chambers each arranged to add a unique chemical construct (or codes) to a polymer (or DNA) string when the polymer enters the respective addition chamber, the data comprising a series of codes; successively steering the polymer from deblock chambers through the nanopore into the addition chambers to add codes to the polymer to create the digital data pattern on the polymer; and accurately controlling the bit rate of the polymer using a servo controller. The device may have loading chamber(s) to load (or remove) the polymer into/from the deblock chambers through at least one “micro-hole”. The cell may be part of a memory system that stores and retrieves “raw” data and allows for remote retrieval and conversion. The cell may store multi-bit data having a plurality of states for the codes.

The present technology relates to a memory system and a method of operating the memory system. The memory system includes a memory device including a plurality of semiconductor memories, and a controller for controlling the memory device to perform a test program operation and a threshold voltage distribution monitoring operation on each of the plurality of semiconductor memories during an operation. The controller sets operation performance parameters of each of the semiconductor memories based on monitoring information obtained as a result of the threshold voltage distribution monitoring operation.

An Integrated Circuit (IC) includes a non-volatile memory (NVM) and secure power-up circuitry. The NVM is configured to store an operational state of the IC. The secure power-up circuitry is configured to (i) during a power-up sequence of the IC, perform a first readout of the operational state from the NVM while a supply voltage of the IC is within a first voltage range, (ii) if the operational state read from the NVM in the first readout is a state that permits access to a sensitive resource of the IC, verify that the supply voltage is within a second voltage range, more stringent than the first voltage range, and then perform a second readout of the operational state from the NVM, and (iii) initiate a responsive action in response to a discrepancy between the operational states read from the NVM in the first readout and in the second readout.