A memory device includes a substrate including first and second regions, the first region having first wordlines and first bitlines, and the second region having second wordlines and second bitlines, a first memory cell array including first memory cells in the first region, the first memory cell array having volatility, and each of the first memory cells including a cell switch having a first channel region adjacent to a corresponding first wordline of the first wordlines, and a capacitor connected to the cell switch, and a second memory cell array including second memory cells in the second region, the second memory cell array having non-volatility, and each of the second memory cells including a second channel region adjacent to a corresponding second wordline of the second wordlines, and a ferroelectric layer between the corresponding second wordline of the second wordlines and the second channel region.

Circuits and methods are disclosed for voltage-mode bit line precharge for random-access memory cells. A circuit includes an array of random access memory cells; a low-impedance voltage source configured to provide a precharge voltage; and a control circuit configured to precharge a bit line of one of the random access memory cells to the precharge voltage using the low-impedance voltage source prior to reading the one of the random access memory cells.

Methods, systems, and devices for parallel drift cancellation are described. In some instances, during a first duration, a first voltage may be applied to a word line to threshold one or more memory cells included in a first subset of memory cells. During a second duration, a second voltage may be applied to the word line to write a first logic state to one or more memory cells included in the first subset and to threshold one or more memory cells included in a second subset of memory cells. During a third duration, a third voltage may be applied to the word line to write a second logic state to one or more memory cells included in the second subset of memory cells.

An integrated circuit (IC) device includes a first terminal, a second terminal, a resistive memory device configured to have a first resistance level in a first state and a second resistance level in a second state, and a switching device including a control terminal and a current path. The resistive memory device and the current path are coupled in series between the first and second terminals, and the switching device is configured to, responsive to a first voltage level at the control terminal, control the current path to have a first conductance level in a first programmed state and a second conductance level in a second programmed state.

The present invention discloses a computing array based on 1T1R device, operation circuits and operating methods thereof. The computing array has 1T1R arrays and a peripheral circuit; the 1T1R array is configured to achieve operation and storage of an operation result, and the peripheral circuit is configured to transmit data and control signals to control operation and storage processes of the 1T1R arrays; the operation circuits are respectively configured to implement a 1-bit full adder, a multi-bit step-by-step carry adder and optimization design thereof, a 2-bit data selector, a multi-bit carry select adder and a multi-bit pre-calculation adder; and in the operating method corresponding to the operation circuit, initialized resistance states of the 1T1R devices, word line input signals, bit line input signals and source line input signals are controlled to complete corresponding operation and storage processes.

Methods, systems, and apparatuses for memory array bit inversion are described. A memory cell (e.g., a ferroelectric memory cell) may be written with a charge associated with a logic state that may be the inverse of the intended logic state of the cell. That is, the actual logic state of one or more memory cells may be inverted, but the intended logic state of the memory cells may remain unchanged. Different sets of transistors may be configured around a sense component of a cell to enable reading and writing of intended and inverted logic states from or to the cell. For instance, a first set of transistors may be used to read the logic state currently stored at a memory cell, while a second set of transistors may be used to read a logic state inverted from the currently stored logic state.

A memory device and a method of operating the same. The memory device includes a memory cell array including a plurality of memory cells disposed in an area where a plurality of word lines and a plurality of bit lines cross each other; a row decoder including row switches and configured to perform a selection operation on the plurality of word lines; a column decoder including column switches and configured to perform a selection operation on the plurality of bit lines; and a control logic configured to control, in a data read operation, a precharge operation to be performed on a selected word line in a word line precharge period, and to control a precharge operation to be performed on a selected bit line in a bit line precharge period; wherein a row switch connected to the selected word line is weakly turned on in the bit line precharge period.

The present disclosure includes apparatuses and methods for material implication operations in memory with reduced program voltages. An example apparatus can include an array of memory cells that further includes a first memory cell coupled to a first access line and to a first one of a plurality of second access lines and a second memory cell coupled to the first access line and to a second one of the plurality of second access lines. The circuitry can be configured to apply, across the second memory cell, a first voltage differential having a first polarity and a first magnitude. The first voltage differential reduces, if the second memory cell is programmed to a first data state, a magnitude of a drifted threshold voltage for programming the second memory cell to a second data state. The circuitry is further configured to apply, subsequent to the application of the first voltage differential, a first signal to the first access line. The circuitry is further configured to, while the first signal is being applied to the first access line, apply, subsequent to the application of the first voltage differential, a second voltage differential having a second polarity and the first magnitude across the first memory cell and apply a third voltage differential having the second polarity across the second memory cell. A material implication operation is performed as a result of the first, second, and third voltage differentials applied across the first and the second memory cells with a result of the material implication operation being stored on the second memory cell.

According to one embodiment, a magnetoresistive memory device includes: a first conductor; a layer stack; an insulator on a side surface of the layer stack; a second conductor on a second surface of the layer stack; a third conductor; and a fourth conductor on the third conductor. The layer stack includes a first ferromagnetic layer, a second ferromagnetic layer, and an insulating layer between the first ferromagnetic layer and the second ferromagnetic layer and has a first surface in contact with the first conductor. The second surface is at an opposite side of the first surface. The third conductor has a portion on the second conductor and a portion on a side surface of the insulator.

One aspect of this description relates to a memory array. The memory array includes a plurality of N-stack pass gates, a plurality of enable lines, a plurality of NMOS stacks, a plurality of word lines, and a matrix of resistive elements. Each N-stack pass gate includes a stage-1 PMOS core device and a stage-N PMOS core device in series. Each stage-1 PMOS is coupled to a voltage supply. Each enable line drives a stack pass gate. Each N-stack selector includes a plurality of NMOS stacks. Each NMOS stack includes a stage-1 NMOS core device and a stage-N NMOS core device in series. Each stage-1 NMOS core device is coupled to a ground rail. Each word line is driving a stack selector. Each resistive element is coupled between a stack pass gate and a stack selector. Each voltage supply is greater than a breakdown voltage for each of the core devices.