To provide a control circuit capable of not only suppressing an increase in power consumption with a simple configuration but also preventing erroneous writing and destruction of a memory element. Provided is a control circuit that outputs a signal for discharging charges accumulated in a source line and a bit line according to activation of a word line, and outputs a signal for making the source line and the bit line be in a floating state by a start of writing or reading, with respect to a memory cell including the source line, the bit line, a transistor that is provided between the source line and the bit line, and switches on and off by a potential of the word line, and a memory element connected to the transistor in series.

A memory device includes a cell array including cells, an address transition detector outputting a transition detection signal as to whether an address of a write command is changed, and a control logic circuit generating one of word-line-on signals for performing a write operation on the cell array in response to the write command, and terminating the write operation in accordance with the transition detection signal. The word-line-on signals include a long-kept word-line-on signal that stays active before the address is changed and a divided word-line-on signal that is, before the address is changed, divided into sub-word-line-on signals.

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 read-only memory by not implementing erase or write commands. 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 compare an address of a received command to the one or more addresses, and at least in part based on the comparison, determine not to implement the received command. The circuitry can be further configured to return an error message after determining not to implement the received command.

Methods and systems include memory devices with multiple access lines arranged in an array to form a multiple intersections. Memory cells are located at the intersections of the multiple access lines. Decoders are configured to drive the multiple memory cells via the multiple access lines. Variable biasing circuitry may bias a voltage on an access line of the multiple access lines to change a variable ramp rate of the voltage on the access line. A control circuit is configured to determine a memory cell of the multiple memory cells to be activated. Based at least in part on a distance from the memory cell to a corresponding decoder, the control circuit may set the variable ramp rate of the biasing circuitry.

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.

The present disclosure is drawn to, among other things, a method for programming a memory device comprising a plurality of memory arrays. The method may include receiving a command to program one or more of the plurality of memory arrays and programming the one or more of the plurality of memory arrays based on the command. The method may optionally include erasing the one or more of the plurality of memory arrays prior to the programming.

Embodiments disclosed herein include a semiconductor device. The semiconductor device may include a magnetoresistive random access memory (MRAM) array. The MRAM array may include defective MRAM cells, redundancy MRAM cells, and operational MRAM cells. The semiconductor device may also include an address input electrically connected to the MRAM array and a selector circuit wired to the address input and an output of the MRAM array. The selector circuit may be configured to read the defective MRAM cells to identify the MRAM array.

The present disclosure is drawn to, among other things, a method of managing a magnetoresistive memory (MRAM) device. In some aspects, the method includes receiving a configuration bit from a write mode configuration register. In response to determining the configuration bit is a first value, the MRAM device is operated in a NOR emulation mode. In response to determining the configuration bit is a second value, the MRAM device is operated in a persistent memory mode.

A memory circuit device includes multiple memory cells that are each constituted of a resistive memory element; a write circuit unit that is configured to write data to any one of the memory cells which is designated by cell designating information, and a read circuit unit that is configured to read out, from the memory cell designated by the cell designating information, data written in the memory cell. The memory circuit device has a configuration including a selection circuit unit that is shared by both of the write circuit unit and the read circuit unit and configured to select a memory cell to be activated from the multiple memory cells based on cell designating information, and a control circuit unit that is configured to selectively enable any one of writing of data by the write circuit unit and reading of data by the read circuit unit with respect to the memory cell selected by the selection circuit unit.

An adaptive memory management and control circuitry (AMMC) to provide extended test, performance, and power optimizing capabilities for a resistive memory is disclosed herein. In one embodiment, a resistive memory comprises a resistive memory array and an Adaptive Memory Management and Control circuitry (AMMC) that is coupled to the resistive memory array. The AMMC is configured with extended test, reliability, performance and power optimizing capabilities for the resistive memory.