A semiconductor memory device according to the present invention has a memory cell array, a write-driving/bias-reading circuit, a control circuit and a sense amplifier. The control circuit outputs a VSLC (Verify Sense Load Control) signal generated according to writing data. After the write-driving/bias-reading circuit applied the writing pulse and the complementary writing pulse, the sense amplifier receives the VSLC signal and detects the current difference between two currents respectively flowing through a first data line and a second data line; the first data line and the second data line respectively connecting a true memory cell and a complementary memory cell of the selected pair of memory cell. The control circuit controls to provide the additional current to at least one of the first data line and the second data line so as to make the detected current difference meet the required margin.

A resistive memory apparatus including bit lines, word lines, a memory array, bypass paths, select circuits, and a switch circuit is provided. The word lines are respectively crossed with the bit lines. The memory array includes memory elements. One end of each of the memory elements is coupled to the corresponding word line, and another end of each of the memory elements is coupled between a first node and a second node on the corresponding bit line. Each of the bypass paths is connected in parallel with the corresponding bit line between the first node point and the second node. Each of the select circuits is coupled to the corresponding bit line and bypass path, and configured to select the coupled bit line or bypass path. The switch circuit is coupled to the word lines, and configured to select one of the word lines.

Devices and methods for accessing resistive change elements in a resistive change element array to determine resistive states of the resistive change elements are disclosed. According to some aspects of the present disclosure the devices and methods access resistive change elements in a resistive change element array through a variety of operations. According to some aspects of the present disclosure the devices and methods supply an amount of current tailored for a particular operation. According to some aspects of the present disclosure the devices and methods compensate for circuit conditions of a resistive change element array by adjusting an amount of current tailored for a particular operation to compensate for circuit conditions of the resistive change element array.

System and method to localize a position of an RRAM filament of resistive memory device at very low bias voltages using a scanning laser beam. The approach is non-invasive and allows measurement of a large number of devices for creating statistics relating to the filament formation. A laser microscope system is configured to perform a biasing the RRAM cell with voltage (or current). Concurrent to the applied bias, a laser beam is generated and aimed at different positions of the RRAM cell (e.g., by a raster scanning). Changes in the current (or voltage) flowing through the cell are measured. The method creates a map of the current (or voltage) changes at the different laser positions and detects a spot in the map corresponding to higher (or lower) current (or voltage). The method determines the (x,y) position of the spot compared to the edge/center of the RRAM cell.

A variable resistance memory device includes: a memory cell including a first and second sub memory cell; and a first, second and third conductor. The first sub memory cell is above the first conductor, and includes a first variable resistance element and a first bidirectional switching element. The second sub memory cell is above the second conductor, and includes a second variable resistance element and a second bidirectional switching element. The second conductor is above the first sub memory cell. The third conductor is above the second sub memory cell. The variable resistance memory device is configured to receive first data and to write the first data to the memory cell when the first data does not match second data read from 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.

A resistive memory structure comprises at least one resistive memory element configured to store one or more bits of data and a circuit electrically connected to the resistive memory element for use in performing at least one of a read or write operation on the at least one resistive memory element. The circuit includes a resistor electrically connected in series to the resistive memory element thereby forming a voltage divider and electrical node therebetween, and an interpretation circuit electrically connected to the electrical node formed between the resistive memory element and the resistor. The interpretation circuit is configured to interpret a voltage at the electrical node and to determine a resistive state of the resistive memory element based on the voltage at the electrical node.

A set procedure of a one transistor, one memristor memory elements may comprise determining a gate voltage for the transistor based on the desired target value. Increasing set pulses may be applied to memristor while the gate is held at the determined gate voltage.

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 memory device includes a memory cell array, a read circuit, and a control logic. The memory cell array includes a memory cell having a resistance level that varies depending on data stored therein. The memory cell is connected to a first signal line and a second signal line. The read circuit is configured to read the data. The control logic is configured to precharge a sensing node, connected to the first signal line through a first switching device, and a first node, connected to the second signal line through a second switching device, to different voltage levels during a first period, and develop a voltage of the sensing node based on the resistance level of the memory cell during a second period.