Memory devices have an array of elements in two or more dimensions. The memory devices use multiple access lines arranged in a grid to access the memory devices. Memory cells are located at intersections of the access lines in the grid. Drivers are used for each access line and configured to transmit a corresponding signal to respective memory cells of the plurality of memory cells via a corresponding access line. The memory devices also include compensation circuitry configured to determine which driving access lines driving a target memory cell of the plurality of memory cells has the most distance between the target memory cell and a respective driver. The plurality of access lines comprise the driving access lines. The compensation circuitry also is configured to output compensation values to adjust the voltages of the driving access lines based on a polarity of the voltage of the longer driving access line.

A decoder in an integrated circuit memory device having: a positive section having a first input line; a negative section having a second input line; and an output line connected from both the positive section and the negative section to a voltage driver connected to a memory cell. The positive section and the negative section are controlled by a polarity control signal. When the polarity control signal indicates positive polarity, the positive section drives the output line according to signals received in the first input line; and when the polarity control signal indicates negative polarity, the negative section drives the output line according to signals received in the second input line.

The application relates to an architecture that allows for less precision of demarcation read voltages by combining two physical memory cells into a single logical bit. Reciprocal binary values may be written into the two memory cells that make up a memory pair. When activated using bias circuitry and address decoders the memory cell pair creates current paths having currents that may be compared to detect a differential signal. The application is also directed to writing and reading memory cell pairs.

The present disclosure relates to a logic operation circuit for computation in memory, which comprises an equivalent circuit input terminal, a reference circuit input terminal, a reset input terminal and an output terminal; wherein the equivalent circuit input terminal is configured to input the equivalent voltage of a memory computing array, the reset input terminal is configured to input a reset voltage, and the reference circuit input terminal is configured to input a reference voltage; the logic operation circuit for computation in memory outputs different output voltages according to the difference between the equivalent voltage and the reference voltage, and the output voltage is output through the output terminal; the logic operation circuit of the present disclosure has a simple structure, reduced complexity and effectively saved resources.

Disclosed are embodiments of an integrated circuit structure (e.g., a processing chip), which includes an array of integrated pixel and memory cells configured for deep in-sensor, in-memory computing (e.g., of neural networks). Each cell incorporates a memory structure (e.g., DRAM structure or a ROM structure) with a storage node, which stores a first data value (e.g., a binary weight value), and a sensor connected to a sense node, which outputs a second data value (e.g., an analog input value). Each cell is selectively operable in a functional computing mode during which the voltage level on a bit line is adjusted as a function of both the first data value and the second data value. Each cell is further selectively operable in a storage node read mode. Furthermore, depending upon the type of memory structure (e.g., a DRAM structure), each cell is selectively operable in a storage node write mode.

A synapse system is provided which includes three transistors and a resistance-switching element arranged between two neurons. The resistance-switching element has a resistance value and it is arranged between two neurons. A first transistor is connected between the resistance-switching element and one of the neurons. A second transistor and a third transistor are arranged between the two neurons, and are connected in series which interconnects with the gate of the first transistor. A first input signal is transmitted from one of the neurons to the other neuron through the first transistor. A second input signal is transmitted from one of the neurons to the other neuron through the second transistor and the third transistor. The resistance value of the resistance-switching element is changed based on the time difference between the first input signal and the second input signal.

A memory device includes metal interconnect structures embedded within dielectric material layers that overlie a top surface of a substrate, a thin film transistor embedded in a first dielectric material layer selected from the dielectric material layers, and is vertically spaced from the top surface of the substrate, and a ferroelectric memory cell embedded within the dielectric material layers. A first node of the ferroelectric memory cell is electrically connected to a node of the thin film transistor through a subset of the metal interconnect structures that is located above, and vertically spaced from, the top surface of the substrate.

Provided is an electronic device including a first electrode part including a conductive material, a second electrode part spaced apart from the first electrode part and including a conductive material, an active layer disposed between the first electrode part and the second electrode part, including a spontaneously polarizable material, and formed to optionally have a first mode having a first electrical resistance and a second mode having a value smaller than the first electrical resistance, and an electric field controller connected to the first electrode part and the second electrode part to apply an electric field.

A 3D device, the device including: a first level including logic circuits; a second level including a plurality of memory circuits, where the first level is bonded to the second level, where the bonded includes oxide to oxide bonds, and where the first level includes at least one voltage regulator circuit.

A memory cell includes a first resistive memory element, a second resistive memory element electrically coupled with the first resistive memory element at a common node, and a switching element comprising an input terminal electrically coupled with the common node, the switching element comprising a driver configured to float during one or more operations.