A memory device comprises a memory bank comprising a plurality of addressable memory cells, wherein the memory bank is divided into a plurality of segments. Further, the device comprises a cache memory operable for storing a second plurality of data words, wherein each data word of the second plurality of data words is either awaiting write verification associated with the memory bank or is to be re-written into the memory bank. The cache memory is divided into a plurality of primary segments, wherein each primary segment of the cache memory is direct mapped to a corresponding segment of the plurality of segments, wherein each primary segment is sub-divided into a plurality of secondary segments, and wherein each of the plurality of secondary segments comprises at least one counter for tracking a number of entries stored therein.

A memory includes an array of resistive memory cells and circuitry for setting a write parameter for improving write effectiveness to the cells of the memory array. The circuitry performs a write parameter setting routine that determines a midpoint resistance of a memory state of cells of the array and determines a write efficiency of a weak write operation to cells of the array. Based on the determined midpoint resistance and the determined write efficiency, the circuit sets a write parameter level for subsequent writes to cells of the array.

According to various embodiments, there is provided a memory device including at least one sense amplifier having a first side and a second side, wherein the second side opposes the first side; a first array including a plurality of memory cells arranged at the first side; a second array including a plurality of memory cells arranged at the second side; a first row including a plurality of mid-point reference units arranged at the first side; and a second row including a plurality of mid-point reference units arranged at the second side, wherein each mid-point reference unit of the first row is configured to generate a first reference voltage, and wherein each mid-point reference unit of the second row is configured to generate a second reference voltage; wherein the sense amplifier is configured to determine a resistance state of a memory cell of the first array based on the second reference voltage; wherein the sense amplifier is configured to determine a resistance state of a memory cell of the second array based on the first reference voltage.

According to one embodiment, a semiconductor storage device includes a memory cell, a bit line connected to the memory cell, and a sense circuit connected to the bit line, wherein the sense circuit includes a first transistor with a first end connected to the bit line, a second transistor with a first end connected to a second end of the first transistor, a third transistor with a first end connected to the bit line, a fourth transistor with a first end connected to a second end of the third transistor, and an amplifier connected to a second end of the second transistor and to a second end of the fourth transistor.

The present disclosure includes apparatuses, methods, and systems for programming codewords for error correction operations to memory. An embodiment includes a memory having a plurality of groups of memory cells, wherein each respective one of the plurality of groups includes a plurality of sub-groups of memory cells, and circuitry configured to program a portion of a codeword for an error correction operation to one of the plurality of groups of memory cells by determining an address in that group of memory cells by performing an XOR operation on an address of one of the plurality of sub-groups of that group of memory cells, and programming the portion of the codeword to the determined address.

A neuromorphic device includes a plurality of cell tiles including a cell array including a plurality of memory cells storing a weight of a neural network, a row driver connected to the plurality of memory cells, and cell analog-digital converters connected to the plurality of memory cells and converting cell currents into a plurality of pieces of digital cell data, a reference tile including a plurality of reference cells, a reference row driver connected to the plurality of reference cells, and reference analog-digital converters connected to the plurality of reference cells and converting reference currents read via the plurality of reference column lines into a plurality of pieces of digital reference data, and a comparator circuit configured to compare the plurality of pieces of digital cell data with the plurality of pieces of digital reference data, respectively.

A hybrid memory system provides rapid, persistent byte-addressable and block-addressable memory access to a host computer system by providing direct access to a both a volatile byte-addressable memory and a volatile block-addressable memory via the same parallel memory interface. The hybrid memory system also has at least a non-volatile block-addressable memory that allows the system to persist data even through a power-loss state. The hybrid memory system can copy and move data between any of the memories using local memory controllers to free up host system resources for other tasks.

In various embodiments, a memory cell arrangement is provided including a memory cell driver and one or more memory cells, wherein one or more control nodes of each of the one or more memory cells are electrically conductively connected to one or more output nodes of the memory cell driver. The memory cell driver may include: a first supply node to receive a first supply voltage and a second supply node to receive a second supply voltage, a plurality of input nodes to receive a plurality of input voltages, one or more output nodes, and a logic circuit connected to the first supply node, the second supply node, the plurality of input nodes, and the one or more output nodes, wherein the logic circuit includes one or more logic gates and is configured to connect via the one or more logic gates either the first supply node or the second supply node to the one or more output nodes in response to the plurality of input voltages.

A method of correcting bias temperature instability in memory arrays may include applying a first bias to a memory cell, where the memory cell may include a memory element and a select element, and the first bias may causes a value to be stored in the memory element. The first bias causes a bias temperature instability (BTI) associated with the memory cell to increase. The method may also include applying a second bias to the memory cell, where the second bias may have a polarity that is opposite of the first bias, and the value stored in the memory element remains in the memory element after the second bias is applied. The second bias may also cause the BTI associated with the memory cell to decrease while maintaining any value stored in the memory cell.

A magnetoresistive memory device according to one embodiment includes: first and second layer stacks, each of which includes: a first ferromagnetic layer having a magnetization directed in a first direction; a non-magnetic first conductive layer above the first ferromagnetic layer, a second ferromagnetic layer provided above the first conductive layer and having a magnetization directed in a second direction different from the first direction, a first insulating layer on an upper surface of the second ferromagnetic layer, and a third ferromagnetic layer above the first insulating layer. The second ferromagnetic layer of the second layer stack is thicker than the second ferromagnetic layer of the first layer stack.