An embodiment of the present invention provides a method for implementing Boolean functionality to create AND, OR, NAND, NOR, or NOT logic gates using a single memristor. In an embodiment, a first voltage is applied to the memristor within a predetermined range of one of the prescribed Boolean functions to be performed by the memristor. A second voltage is then applied within the predetermined range of the prescribed Boolean function. The memristor then provides an output based on the Boolean function that has been prescribed. In an embodiment, the resistance value of the memristor is then reset by a reset pulse, wherein the reset pulse is another applied voltage.

A memory device includes: a memory cell array comprising a plurality of memory cells; a temperature sensor configured to detect a temperature of the memory cell array; a write circuit configured to write data into the plurality of memory cells; and a controller coupled to the temperature sensor and the write circuit, wherein the controller is configured to determine a target write pulse width used by the write circuit based on the detected temperature of the memory device.

Disclosed is a nonvolatile memory device including a plurality of memory cells operable to store data, each memory cell structured to include a resistance change layer exhibiting different resistance states with different resistance values for representing data, a write circuit suitable for generating a write pulse in a write mode to write data in a memory cell of the plurality of memory cells, and a read circuit suitable for generating a read pulse in a read mode to read data from a memory cell of the plurality of memory cells, wherein the memory cells are each structured to be operable in writing or reading data when a range of a voltage level change of the read pulse corresponding to a pulse width change of the read pulse is within a range of a voltage level change of the write pulse corresponding to a pulse width change of the write pulse.

The present disclosure relates to a nonlinearity compensation circuit for a memristive device. The circuit according to an embodiment includes at least one power source unit to apply an input pulse; a modulation unit connected to the at least one power source unit to adjust a pulse width of an update pulse to be applied to the memristive device; and the memristive device to which the modulated update pulse is applied.

According to one embodiment, a memory device includes a memory cell including a resistance change memory portion and a switching portion, and a voltage applying circuit carrying out, at a time of writing data to the memory cell, an operation of applying a voltage of a first polarity to the memory cell and applying a first voltage to the memory cell, an operation of applying a voltage of a second polarity to the memory cell and applying a second voltage to the memory cell, an operation of applying a voltage of the first polarity to the memory cell and applying a third voltage to the memory cell, or an operation of applying a voltage of the second polarity to the memory cell and applying a fourth voltage to the memory cell.

A memory device and method comprising a metal oxide material disposed between and in electrical contact with first and second conductive electrodes, and a voltage source configured to apply a plurality of voltage pulses spaced apart in time across the first and second electrodes. For each one of the voltage pulses, an amplitude of the voltage increases during the voltage pulse.

Methods, systems, and devices for memory cells with asymmetrical electrode interfaces are described. A memory cell with asymmetrical electrode interfaces may mitigate shorts in adjacent word lines, which may be leveraged for accurately reading a stored value of the memory cell. The memory device may include a self-selecting memory component with a top surface area in contact with a top electrode and a bottom surface area in contact with a bottom electrode, where the top surface area in contact with the top electrode is a different size than the bottom surface area in contact with the bottom electrode.

Two-terminal memory can be set to a first state (e.g., conductive state) in response to a program pulse, or set a second state (e.g., resistive state) in response to an erase pulse. These pulses generally provide a voltage difference between the two terminals of the memory cell. Certain electrical characteristics associated with the pulses can be manipulated in order to enhance the efficacy of the pulse. For example, the pulse can be enhanced or improved to reduce power-consumption associated with the pulse, reduce a number of pulses used to successfully set the state of the memory cell, reduce wear or damage to the memory cell, or to improve Ion or Ioff distribution associated with changing the state of the memory cell.

A non-volatile memory device of the disclosure includes a memory cell, a writing circuit, and a current controller. The memory cell is disposed at an intersection of a first wiring and a second wiring, and includes a variable resistance element having a resistance state that is variable between a first resistance state and a second resistance state. The writing circuit varies the variable resistance element from the first resistance state to the second resistance state, and thereby performs writing of data on the memory cell. The current controller controls a current and thereby limits the current to a predetermined limit current value. The current is caused to flow through the first wiring or the second wiring by the writing circuit upon performing of the writing of the data. The current controller causes the predetermined limit current value to be a first limit current value in a period before a time at which the variable resistance element is varied to the second resistance state, and varies the predetermined limit current value from the first limit current value to a second limit current value after the time at which the variable resistance element is varied to the second resistance state.

A method for improving the stability of a resistive change cell is disclosed. The stability of a resistive change memory cell-that is, the tendency of the resistive change memory cell to retain its programmed resistive state-may, in certain applications, be compromised if the cell is programmed into an unstable or metastable state. In such applications, a programming method using bursts of sub-pulses within a pulse train is used to drive the resistive change cell material into a stable state during the programming operation, reducing resistance drift over time within the cell.