A first memory cell includes a first variable resistance element and a first switching element. A control circuit is configured to execute first detection of detecting a first value of a first physical quantity related to the first memory cell, execute first write for storing first data in the first memory cell, execute second detection of detecting a second value of the first physical quantity related to the first memory cell following the first write, and read second data related to the first memory cell based on the first value and the second value. At least one of the first value and the second value is a value during a change in the first physical quantity related to the first memory cell.

A magnetic memory device includes a first interconnect, a second interconnect, a memory cell, and a write circuit. The memory cell is electrically coupled between the first interconnect and the second interconnect, and includes a variable resistance element and a switching element. The write circuit supplies a write voltage from the current source circuit or the voltage source circuit to write data into the memory cell. The write circuit supplies the write voltage to one of the first interconnect and the second interconnect using the voltage source circuit during a first period ranging from a first time to a second time. The write circuit supplies the write voltage to one of the first interconnect and the second interconnect using the current source circuit during a second period ranging from a third time to a fourth time.

The present invention is directed to a nonvolatile memory device including a plurality of memory cells arranged in rows and columns, a plurality of word lines with each connected to a respective row of the memory cells along a row direction, a plurality of bit lines with each connected to a respective column of the memory cells along a column direction; a column decoder connected to the bit lines; a plurality of sense amplifiers connected to the column decoder; and a plurality of sense amplifier control circuits. Each of the sense amplifiers is connected to a unique one of the sense amplifier control circuits. Each of the sense amplifier control circuits includes a current detector circuit for detecting a sensing current, a current booster circuit for boosting the sensing current, and a timer circuit for providing a delayed trigger for a respective one of the sense amplifiers connected thereto.

A variable resistive memory device includes a memory cell, a first circuit, and a second circuit. The memory cell is connected between a word line and a bit line. The first circuit provides the bit line with a first pulse voltage based on at least one enable signal. The second circuit provides the word line with a second pulse voltage based on the enable signal. The first circuit generates the first pulse voltage increased in steps from an initial voltage level to a target voltage level.

The disclosure is directed to spin-orbit torque MRAM structures and methods. A SOT channel of the SOT-MRAM includes multiple heavy metal layers and one or more dielectric dusting layers each sandwiched between two adjacent heavy metal layers. The dielectric dusting layers each include discrete molecules or discrete molecule clusters of a dielectric material scattered in or adjacent to an interface between two adjacent heavy metal layers.

Technologies for non-uniform random number generation are disclosed. In one embodiment, the distribution of resistance of a magnetic tunnel junction (MTJ) can be controlled by applying a mechanical strain with a piezoelectric layer and by applying a spin torque by a spin-orbit torque layer. The distribution of resistance can be approximately a Gaussian distribution. In another embodiment, an array of N probabilistic bits (p-bits) has a bias and feedback matrix that result in the array of p-bits outputting an N-bit random number with a non-uniform distribution, such as a Gaussian distribution.

A memory circuit device includes multiple memory cells that are each constituted of a resistive memory element, a write circuit unit that is configured to write data to any one of the memory cells which is designated by cell designating information, and a read circuit unit that is configured to read out, from the memory cell designated by the cell designating information, data written in the memory cell. The memory circuit device has a configuration including a selection circuit unit that is shared by both of the write circuit unit and the read circuit unit and configured to select a memory cell to be activated from the multiple memory cells based on the cell designating information, and a control circuit unit that is configured to selectively enable any one of writing of data by the write circuit unit and reading of data by the read circuit unit with respect to the memory cell selected by the selection circuit unit.

Methods and systems include memory devices with a memory array comprising a plurality of memory cells. The memory devices include a control circuit operatively coupled to the memory array and configured to receive a read request for data and to apply a first voltage to the memory array based on the read request. The control circuit is additionally configured to count a total number of the plurality of memory cells that have switched to an active read state based on the first voltage and to apply a second voltage to the memory array based on the total number. The control circuit is further configured to return the data based at least on bits stored in a first and a second set of the plurality of memory cells.

A neuron circuit and an artificial neural network chip are provided. The neuron circuit includes a memristor and an integrator. The memristor generates a pulse train having an oscillation frequency when an applied voltage exceeds a predetermined threshold. The integrator is connected in parallel to the memristor for receiving and accumulating input pulses transmitted by a previous layer network at different times, and driving the memristor to transmit the pulse train to a next layer network when a voltage of the accumulated input pulses exceeds the predetermined threshold.

Methods and systems include memory devices with a memory array comprising a plurality of memory cells. The memory devices include a control circuit operatively coupled to the memory array and configured to receive a read request for data and to apply a first voltage at a first time duration to the memory array based on the read request. The control circuit is additionally configured to count a number of the plurality of memory cells that have switched to an active read state based on the first voltage and to derive a second time duration. The control circuit is further configured to apply a second voltage at the second duration to the memory array. The control circuit is also configured to return the data based at least on bits stored in a first and a second set of the plurality of memory cells.