A memory includes virtual ground circuitry configured to generate a virtual ground voltage (greater than zero volts) at a virtual ground node, a memory array of resistive memory cells in which each resistive memory cell includes a select transistor and a resistive storage element and is coupled to a first column line of a plurality of first column lines, and a first decoder configured to select a set of first column lines for a memory read operation from a selected set of the resistive memory cells. The memory includes read circuitry, and a first column line multiplexer configured to couple each selected first column line of the set of first column lines to the read circuitry during the memory read operation, and configured to couple each unselected first column line of the plurality of first column lines to the virtual ground node during the memory read operation.

Memory devices, systems including memory devices, and methods of operating memory devices and systems are provided, in which at least a subset of a non-volatile memory array is configured to behave as a volatile memory by erasing or degrading data in the event of a changed power condition such as a power-loss event, a power-off event, or a power-on event. In one embodiment of the present technology, a memory device is provided, comprising a non-volatile memory array, and circuitry configured to store one or more addresses of the non-volatile memory array, to detect a changed power condition of the memory device, and to erase or degrade data at the one or more addresses in response to detecting the changed power condition.

A method of manufacturing an array of magnetic random access memory cells includes writing to a magnetic random access memory cell. The writing to a memory cell includes determining an optimum write current for the array of memory cells, and applying the optimum write current to a first memory cell in the array. A first read current is applied to the first memory cell to determine whether a magnetic orientation of the first memory cell has changed in response to applying the optimum write current. A second write current is applied to the first memory cell when the magnetic orientation of the first memory cell has not changed. The second write current is different from the optimum write current. A second read current is applied to the first memory cell to determine whether the magnetic orientation of the first memory cell changed in response to applying the second write current.

The present invention provides a device with low power and high performance, which can be applied to sensor nodes, a sensor node using the same, an access controller, a data transfer method, and execute a processing method in a microcontroller. The device has: an MRAM; a non-volatile CPU configured to include a nonvolatile memory; a non-volatile FPGA-ACC configured to include a nonvolatile memory and execute a part of operations on the nonvolatile CPU; and a power-gating control unit that controls power supply to each memory cell in the MRAM, the non-volatile CPU, and the non-volatile FPGA-ACC. The device is further provided with an access controller that controls accesses to the MRAM by reading data in advance and backing up the data when data is to be read from the MRAM.

A resistive memory device is provided. The resistive memory device includes a bitline, a source line, a memory cell electrically connected to the bitline and the source line by a first switch, a first transistor electrically connected to the bitline, a second transistor electrically connected to the source line, a gate voltage generator configured to generate a first gate voltage that is provided to a gate electrode of the first transistor, and configured to generate a second gate voltage that is provided to a gate electrode of the second transistor and a second switch that provides the first and second gate voltages to the gate electrodes of the first and second transistors.

Technology is disclosed for improving read margin in a cross-point memory array. Drive transistors pass a read and write currents to the cross-point memory array. The read current charges a selected word line to turn on a threshold switching selector of a selected memory cell. While the threshold switching selector is on, the current (read or write) passes through the selected memory cell. The memory system applies a smaller overdrive voltage to the drive transistor when the drive transistor is passing the read current than when the drive transistor is passing the write current. A smaller overdrive voltage increases the resistance of the drive transistor which improves read margin. Increasing the resistance of the drive transistor increases the resistance seen by the threshold switching selector in the selected memory cell, which reduces the Ihold of the threshold switching selector. Reducing Ihold of the threshold switching selector improves read margin.

An electronic biasing circuit for memory operating in a high temperature environment, comprising a first memory cell and a second memory cell, a first MOSFET transistor electrically coupled in series with the first memory cell, wherein the first MOSFET transistor is configured as a switch, a second MOSFET transistor electrically coupled in series with the second memory cell, wherein the second MOSFET transistor is configured as a switch, a DC bias current source configured to generate a negative DC bias voltage signal, a first read/word line electrically coupled to a gate of the first MOSFET transistor, and a second read/word line electrically coupled to a gate of the second MOSFET transistor, wherein in response to a read operation of the first memory cell, the second read/word line is configured to deliver the negative DC bias voltage signal to the gate of the second MOSFET transistor.

Methods, systems, and devices for operational modes for reduced power consumption in a memory system are described. A memory device may be coupled with a capacitor of a power management integrated circuit (PMIC). The memory device may operate in a first mode where a supply voltage is provided to the memory device from the PMIC. The memory device may operate in a second mode where it is isolated from the PMIC. When isolated, a node of the memory device (e.g., an internal node) may be discharged while the capacitor of the PMIC remains charged. When the memory device resumes operating in the first mode, a supply voltage may be provided to it based on the residual charge of the capacitor.

A method of manufacturing an array of magnetic random access memory cells includes writing to a magnetic random access memory cell. The writing to a memory cell includes determining an optimum write current for the array of memory cells, and applying the optimum write current to a first memory cell in the array. A first read current is applied to the first memory cell to determine whether a magnetic orientation of the first memory cell has changed in response to applying the optimum write current. A second write current is applied to the first memory cell when the magnetic orientation of the first memory cell has not changed. The second write current is different from the optimum write current. A second read current is applied to the first memory cell to determine whether the magnetic orientation of the first memory cell changed in response to applying the second write current.

A power regulation system including a reference generator, a temperature compensation circuit coupled to the reference generator, and a low-dropout (LDO) regulator circuit coupled to the temperature compensation circuit, wherein the temperature compensation circuit provides a reference voltage to the LDO regulator circuit at least based on a ratio of a first current and a second current.