Methods, systems, and devices for memory array operation are described. A series of pulses may be applied to a fatigued memory cell to improve performance of memory cell. For example, a ferroelectric memory cell may enter a fatigue state after a number of access operations are performed at an access rate. After the number of access operations have been performed at the access rate, a fatigue state of the ferroelectric memory cell may be identified and the series of pulses may be applied to the ferroelectric capacitor at a different (e.g., higher) rate. For instance, a delay between pulses of the series of pulses may be shorter than the delay between access operations of the ferroelectric memory cell.

Methods, systems, and devices for operating a ferroelectric memory cell or cells are described. A ferroelectric memory cell may be used to store a logic state. The capacitance of a digit line of the ferroelectric memory cell may be dynamically increased prior to, and during a portion of, a read operation used to determine a stored logic state of the cell. The capacitance may be increased by leveraging intrinsic capacitance of digit lines of the array—e.g., by shorting one digit line to another digit line. Increasing the capacitance of the digit line may increase the signal on the digit line that is sensed during the read operation.

Disclosed embodiments include a memory device having a memory array that includes a first memory cell coupled to a first bit line and a second memory cell coupled to a second bit line and a sense amplifier that includes first and second transistors arranged in a cross-coupled configuration with third and fourth transistors, the first and second transistors being of a first conductivity type and the third and fourth transistors being of a second conductivity type, a first inverter having an input coupled to a first common drain terminal of the first and third transistors and an output coupled to the first bit line, and a second inverter having an input coupled to a second common drain terminal of the second and fourth transistors and an output coupled to the second bit line.

Systems and methods for detecting the presence of a body in a network without fiducial elements, using signal absorption, and signal forward and reflected backscatter of radio frequency (RF) waves caused by the presence of a biological mass in a communications network.

Some embodiments include a ferroelectric transistor having a conductive gate structure, a first ring extending around the conductive gate structure and a second ring extending around the first ring. The first ring includes ferroelectric material. The second ring includes insulative material. A mass of channel material is outward of the second ring. Some embodiments include integrated assemblies and methods of forming integrated assemblies.

Systems and methods for detecting the presence of a body in a network without fiducial elements, using signal absorption, and signal forward and reflected backscatter of RF waves caused by the presence of a biological mass in a communications network.

Methods, systems, and devices for storing and reading data at a memory device are described. A memory device may utilize one or more storage states to store data within a data word. The memory device may exhibit higher data leakage or more power consumption when storing or reading a first storage state compared to storing or reading one or more other storage states. In some cases, the memory device may generate a second data word corresponding to a first data word by modifying each symbol type of the first data word to generate a different symbol type for the second data word. A memory device may reduce the occurrence of a storage state associated with large data leakage, or high-power consumption, or both. Further, the memory device may generate and store an indicator indicating the transformation of a corresponding data word.

Methods, systems, and devices for a source follower-based sensing architecture and sensing scheme are described. In one example, a memory device may include a sense circuit that includes two source followers that are coupled to each other and to a sense amplifier. A method of operating the memory device may include transferring a digit line voltage to one of the source followers and transferring a reference voltage to the other source follower. After transferring the digit line voltage and the reference voltage, the source followers may be enabled so that signals representative of the digit line voltage and the reference voltage are transferred from the outputs of the source followers to the sense amplifier for sensing.

A memory cell includes a write bit line, a write transistor and a read transistor. The write transistor is coupled between the write bit line and a first node. The read transistor is coupled to the write transistor by the first node. The read transistor includes a ferroelectric layer. The write transistor is configured to set a stored data value of the memory cell by a write bit line signal that adjusts a polarization state of the read transistor. The polarization state corresponds to the stored data value.

In some embodiments, an integrated circuit (IC) device includes an active semiconductor layer, a circuitry formed within the active semiconductor layer, a region including conductive layers formed above the active semiconductor layer, and a memory module formed in the region. The memory device includes a three-dimensional array of memory cells, each adapted to store a weight value, and adapted to generate at each memory cell a signal indicative of a product between the stored weight value and an input signal applied to the memory cell. The memory module is further adapted to transmit the product signals from the memory cell simultaneously in the direction of the active semiconductor layer.