The present disclosure is drawn to a magnetoresistive device including an array of memory cells arranged in rows and columns, each memory cell comprising a magnetic tunnel junction, each row comprising a word line, and each column comprising a bit line; a column select device that selects a bit line. The magnetoresistive device also includes a sense amplifier comprising a first input corresponding to a selected bit line, a second input corresponding to a reference bit line, and a data output. The plurality of columns comprise a reference column, the reference column comprising a conductive element coupled to the magnetic tunnel junctions in the reference column.

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.

Disclosed is a system including a memory device having a plurality of physical cells and a processing device, operatively coupled with the memory device. The processing device maintains association of block families with a first (second, etc.) bin of a plurality of bins, each of the plurality of bins associated with one or more read voltage offsets. The read voltage offsets are used to compensate for a temporal read voltage shift caused by a charge loss by memory cells of the block families. Responsive to an occurrence of a power event, the processing device performs diagnostics of one or more blocks of various block families and determines whether to maintain association of the block families with current bins of the respective block families or to associate the block families with different bins.

A semiconductor device that has a normal mode of operation and a test mode of operation and can include: a first circuit that generates at least one assist signal having an assist enable logic level in the normal mode of operation, the at least one assist signal alters a read operation or a write operation to a static random access memory (SRAM) cell of the semiconductor device as compared to read or write operations when the assist signal has an assist disable logic level; and the first circuit generates the at least one assist signal having the assist disable logic level in the test mode of operation

Provided is a booster circuit enabling improvement of efficiency of a stress test for a circuit to which a boosted voltage is applied. A voltage divider circuit is configured to have a voltage-dividing ratio that is variable depending on a test signal, and a limiter circuit is configured to clamp a voltage to a voltage higher than a boosted voltage in normal operation. In a test mode, the voltage divider circuit is controlled so that the boosted voltage becomes higher than that in the normal operation, and the limiter circuit clamps the boosted voltage, with the result that a booster section continuously operates.

Systems, methods, and apparatus to evaluate read margin when reading memory cells in a memory device. In one approach, a controller of a memory device applies an initial read voltage of an initial polarity to memory cells. Errors from the read are used to determine whether read retry is needed. If so, a pre-read voltage of an opposite polarity is applied, and errors determined. Based on the errors from applying the pre-read voltage, a polarity is selected for the read retry voltage. The read retry voltage of the selected polarity is then applied to the memory cells.

In an SRAM circuit mounted in a semiconductor device, power supply voltage reduction circuits generate reduction voltage obtained by reducing an external power supply voltage. A first power supply voltage selection circuit selects one of the external power supply voltage and the reduction voltage as a drive voltage supplied to a word line driver. A second power supply voltage selection circuit selects one of the external power supply voltage and the reduction voltage as a voltage of a power supply line supplying an operating voltage to a memory cell.

Methods, systems, and devices for drive strength calibration for multi-level signaling are described. A driver may be configured to have an initial drive strength and to drive an output pin of a transmitting device toward an intermediate voltage level of a multi-level modulation scheme, where the output pin is coupled with a receiving device via a channel. The receiving device may generate, and the transmitting device may receive, a feedback signal indicating a relationship between the resulting voltage of the channel and an value for the intermediate voltage level. The transmitting device may determine and configure the driver to use an adjusted drive strength for the intermediate voltage level based on the feedback signal. The driver may be calibrated (e.g., independently) for each intermediate voltage level of the multi-level modulation scheme. Further, the driver may be calibrated for the associated channel.

An apparatus includes a memory circuit that includes a plurality of sub-arrays. The memory circuit is configured to implement a retention mode according to test information indicating voltage sensitivities for the plurality of sub-arrays. The apparatus also includes a voltage control circuit coupled to a power supply node. The voltage control circuit is configured, in response to activation of the retention mode for the plurality of sub-arrays, to generate, based on the test information, at least two different retention voltage levels for different ones of the plurality of sub-arrays. The at least two different retention voltage levels are lower than a power supply voltage level of the power supply node.

Methods, systems, and devices for link evaluation for a memory device are described. A memory device may receive signaling over a channel and may identify logic values encoded into the signaling based on sampling the signaling against a reference voltage. The sampling may occur at a reference time within a sampling period. To evaluate a quality (e.g., margin of error) of the channel, the memory device may adjust the reference voltage, the reference time, or both, and either the memory device or the host device may determine whether the memory device is still able to correctly identify logic values encoded into signaling over the channel. In some cases, the channel quality may be evaluated during a refresh cycle or at another opportunistic time for the memory device.