An electronic device includes a semiconductor memory unit, which includes resistive memory cells; an access circuit to apply, during a write operation, a write voltage across a selected one of the resistive memory cells in a first or second direction; first switching units, each of which is disposed between the access circuit and a first end of a corresponding one of the resistive memory cells and turned on in response to a first voltage having a level higher than a predetermined level when the corresponding resistive memory cell is selected during the write operation; and second switching units, each of which is disposed between the access circuit and a second end of the corresponding resistive memory cell and turned on in response to a second voltage having a level equal to or lower than the predetermined level when the corresponding resistive memory cell is selected during the write operation.

This technology provides an electronic device. An electronic device in accordance with an implementation of this document may include a semiconductor memory, and the semiconductor memory may include free layer having a variable magnetization direction; a tunnel barrier layer formed over the free layer; a pinned layer formed over the tunnel barrier layer and having a pinned magnetization direction; an exchange coupling layer formed over the pinned layer; and a magnetic correction layer formed over the exchange coupling layer, wherein the magnetic correction layer comprises a first magnetic layer, a spacer layer and a second magnetic layer that are sequentially stacked, and the first magnetic layer has a saturation magnetization smaller than a saturation magnetization of the second magnetic layer.

A memory device having a DRAM core and a register stores first data in the register before receiving first and second memory access commands via a command interface and before receiving second data via a data interface. The memory device responds to the first memory access command by writing the first data from the register to the DRAM core and responds to the second memory access command by writing the second data from the data interface to the DRAM core.

A method and system are disclosed. In one embodiment the method includes allocating several memory locations within a phase change memory and switch (PCMS) memory to be utilized as a Random Access Memory (RAM) Disk. The RAM Disk is created for use by a software application running in a computer system. The method also includes mapping at least a portion of the allocated amount of PCMS memory to the software application address space. Finally, the method also grants the software application direct access to at least a portion of the allocated amount of the PCMS memory.

Methods and systems for managing memory and stress to memory systems. A method for managing memory includes receiving from a software application memory retention requirements for application data. The memory retention requirements include storage duration length and/or criticality of data retention. The method also includes storing the application data in one of a plurality of memory regions in non-volatile memory based on the memory retention requirements and memory retention characteristics of the memory regions. Each memory region may have different memory retention characteristics.

Write operations on main memory comprise predicting a last write in a dirty cache line. The predicted last write indicates a predicted pattern of the dirty cache line before the dirty cache line is evicted from a cache memory. Further, the predicted pattern is compared with a pattern of original data bits stored in the main memory for identifying changes to be made in the original data bits. Based on the comparison, an optimization operation to be performed on the original data bits is determined. The optimization operation modifies the original data bits based on the predicted pattern of a last write cache line before the last write cache line is evicted from the cache memory.

An electronic device may include a semiconductor memory. The semiconductor memory may include a global line pair including a global bit line and a global source line; a plurality of cell matrices coupled between the global bit line and the global source line, each cell matrix including a plurality of local line pairs and a plurality of storage cells that are coupled to the plurality of local line pairs, wherein each storage cell is operable to store data and is coupled between local lines of a corresponding local line pair; and a plurality of isolation switch pairs that couple the plurality of cell matrices to the global bit line and the global source line of the global line pair, one isolation switch pair per cell matrix.

Various embodiments comprise apparatuses and methods including a method of reconfiguring partitions in a memory device as directed by a host. The method includes managing commands through a first interface controller to mapped portions of a first memory not having an attribute enhanced set, and mapping portions of a second memory having the attribute enhanced set through a second interface controller. Additional apparatuses and methods are described.

Examples of a multi-level memory with direct access are described. Examples include designating an amount of a non-volatile random access memory (NVRAM) for use as memory for a computer system. Examples also include designating a second amount of the NVRAM to for use as storage for the computing device. Examples also include re-designating at least a first portion of the first amount of NVRAM from use as memory to use as storage.

A memory access command, column address and plurality of write data values are received within an integrated-circuit memory chip via external signaling links. In response to the memory access command, the integrated-circuit memory chip (i) decodes the column address to select address-specified sense amplifiers from among a plurality of sense amplifiers that constitute a sense amplifier bank, (ii) reads first data, constituted by a plurality of read data values, out of the address-specified sense amplifiers, and (iii) overwrites the first data within the address-specified sense amplifiers with second data constituted by one or more of the write data values and by one or more of the read data values.