Abstract: Stochastic or near-stochastic physical characteristics of resistive switching devices are utilized for generating data distinct to those resistive switching devices. The distinct data can be utilized for applications related to electronic identification. As one example, data generated from physical characteristics of resistive switching devices on a semiconductor chip can be utilized to form a distinct identifier sequence for that semiconductor chip, utilized for verification applications for communications with the semiconductor chip or utilized for generating cryptographic keys or the like for cryptographic applications.

Abstract: Stochastic or near-stochastic physical characteristics of resistive switching devices are utilized for generating data distinct to those resistive switching devices. The distinct data can be utilized for applications related to electronic identification. As one example, data generated from physical characteristics of resistive switching devices on a semiconductor chip can be utilized to form a distinct identifier sequence for that semiconductor chip, utilized for verification applications for communications with the semiconductor chip or utilized for generating cryptographic keys or the like for cryptographic applications.

Abstract: A method for erasing a memory cell includes applying a first erase to memory cells to erase the memory cells, wherein first memory cells are in a weakly erased state in response to the first erase, and wherein second memory cells are in a normally erased state in response to the first erase, thereafter applying a first weak program to the memory cells, wherein the second memory cells enter a programmed state and the third memory cells remain in the erased state in response to the first weak program, and thereafter applying a read to the memory cells to identify the second memory cells, and applying a second erase to the second memory cells to thereby erase the second memory cells.

Abstract: Stochastic or near-stochastic physical characteristics of resistive switching devices are utilized for generating data distinct to those resistive switching devices. The distinct data can be utilized for applications related to electronic identification. As one example, data generated from physical characteristics of resistive switching devices on a semiconductor chip can be utilized to form a distinct identifier sequence for that semiconductor chip, utilized for verification applications for communications with the semiconductor chip or utilized for generating cryptographic keys or the like for cryptographic applications.

Abstract: Provided herein resistive random access memory matrix multiplication structures and methods. A non-volatile memory logic system can comprise a bit line and at a set of wordlines. Also included can be a set of resistive switching memory cells at respective intersections between the bit line and the set of wordlines. The set of resistive switching memory cells are programmed with a value of an input data bit of a first data matrix and receive respective currents on the set of wordlines. The respective currents comprise respective values of an activation data bit of a second data matrix. A resulting value based on a matrix multiplication corresponds to an output value of the bit line.

Abstract: A method for erasing a memory cell includes applying a first erase to memory cells to erase the memory cells, wherein first memory cells are in a weakly erased state in response to the first erase, and wherein second memory cells are in a normally erased state in response to the first erase, thereafter applying a first weak program to the memory cells, wherein the second memory cells enter a programmed state and the third memory cells remain in the erased state in response to the first weak program, and thereafter applying a read to the memory cells to identify the second memory cells, and applying a second erase to the second memory cells to thereby erase the second memory cells.

Abstract: A method for facilitating erase or program operations on two-terminal memory devices includes substantially simultaneously initiating erase cycle or program cycle for two-terminal memory devices from a first plurality of two-terminal memory devices, monitoring erase detect or program detect conditions for each of the two-terminal memory devices, and before detecting erase detect or program detect conditions for all of the two-terminal memory devices, the method includes detecting an erase detect or a program detect condition for the first two-terminal memory device from the first plurality of two-terminal memory devices, and initiating an erase cycle or a program for a second two-terminal memory device for a second plurality of two-terminal memory devices, in response to detecting the erase detect or program detect condition for the first two-terminal memory device.

Abstract: A semiconductor device includes memory devices respectively comprising a selector transistor in series with a control transistor and a memory cell, wherein the control transistor is connected to the memory cell. Control lines of the semiconductor device extend along a first direction, and a first control line is connected to a first memory device control transistor and a second memory device control transistor. Word lines extend in the first direction, and a first word line is connected to a first memory device selector transistor and a second memory device selector transistor. Bitlines extend in a second direction, with a first bitline connected to a first memory device memory cell and a second bitline is connected to a second memory device memory cell. Source lines extend in the second direction, and a first source line is connected to the first memory device selector transistor and the second memory device selector transistor.

Abstract: A logical NAND memory architecture comprising two-terminal, non-volatile resistive memory is disclosed. By way of example, disclosed logical NAND architectures can comprise non-volatile memory cells having approximately 4 F2 area. This facilitates very high memory densities, even for advanced technology nodes. Further, the disclosed architectures are CMOS compatible, and can be constructed among back-end-of-line (BEOL) metal layers of an integrated chip. In some embodiments, subsets of two-terminal memory cells in a NAND array can be constructed between different pairs of BEOL metal layers. In other embodiments, the two-terminal memory cells can be constructed between a single pair of BEOL metal layers.

Abstract: A detection circuit that can detect a two-terminal memory cell changing state. For example, in response to electrical stimuli, a memory cell will change state, e.g., to a defined higher resistance state or a defined lower resistance state. Other, techniques do not detect this state change until after the stimuli is completed and a subsequent sensing operation (e.g., read pulse) is performed. The detection circuit can detect the state change during application of the electrical stimuli that cause the state change and can do so by comparing the magnitudes or values of two particular current parameters.

Abstract: Provided herein is a computing memory architecture. The non-volatile memory architecture can comprise a resistive random access memory array comprising multiple sets of bitlines and multiple wordlines, a first data interface for receiving data from an external device and for outputting data to the external device, and a second data interface for outputting data to the external device. The non-volatile memory architecture can also comprise programmable processing elements connected to respective sets of the multiple sets of bitlines of the resistive random access memory array, and connected to the data interface. The programmable processing elements are configured to receive stored data from the resistive random access memory array via the respective sets of bitlines or to receive external data from the external device via the data interface, and execute a logical or mathematical algorithm on the external data or the stored data and generate processed data.

Abstract: A non-volatile memory device is provided that uses one or more volatile elements. In some embodiments, the non-volatile memory device can include a resistive two-terminal selector that can be in a low resistive state or a high resistive state depending on the voltage being applied. A MOS (“metal-oxide-semiconductor”) transistor in addition to a capacitor or transistor acting as a capacitor can also be included. A first terminal of the capacitor can be connected to a voltage source, and the second terminal of the capacitor can be connected to the selector device. A floating gate of an NMOS transistor can be connected to the other side of the selector device, and a second NMOS transistor can be connected in series with the first NMOS transistor.

Abstract: A non-volatile memory device is provided that uses one or more volatile elements. In some embodiments, the non-volatile memory device can include a resistive two-terminal selector that can be in a low resistive state or a high resistive state depending on the voltage being applied. A MOS (“metal-oxide-semiconductor”) transistor in addition to a capacitor or transistor acting as a capacitor can also be included. A first terminal of the capacitor can be connected to a voltage source, and the second terminal of the capacitor can be connected to the selector device. A floating gate of an NMOS transistor can be connected to the other side of the selector device, and a second NMOS transistor can be connected in series with the first NMOS transistor.

Abstract: A configuration bit for a switching block routing array comprising a non-volatile memory cell is provided. By way of example, the configuration bit and switching block routing array can be utilized for a field programmable gate array, or other suitable circuit(s), integrated circuit(s), application specific integrated circuit(s), electronic device or the like. The configuration bit can comprise a switch that selectively connects or disconnects a node of the switching block routing array. A non-volatile memory cell connected to the switch can be utilized to activate or deactivate the switch. In one or more embodiments, the non-volatile memory cell can comprise a volatile resistance switching device connected in serial to a gate node of the switch, configured to trap charge at the gate node to activate the switch, or release the charge at the gate node to deactivate the switch.

Abstract: Various embodiments disclosed herein provide for a neuromorphic logic system, comprising a bitline and a set of wordlines. The neuromorphic logic system also includes a set of resistive switching memory cells, respectively comprising a two-terminal volatile switching device and a two-terminal non-volatile memory device, at each intersection between the bit line and the set of wordlines, wherein the set of resistive switching memory cells are programmed to a set of resistive states and receive a voltage on the bitline above an activation threshold and wherein the magnitude of the voltage applied to the bitline corresponds to a magnitude of a sensory input, resulting in a current that corresponds to the magnitude of the sensor input and the set of resistive states.

Abstract: Two-terminal memory can be formed into a memory array that contains many discrete memory cells in a physical and a logical arrangement. Where each memory cell is isolated from surrounding circuitry by a single transistor, the resulting array is referred to as a 1T1R memory array. In contrast, where a group of memory cells are isolated from surrounding circuitry by a single transistor, the result is a 1TnR memory array. Because memory cells of a group are not isolated among themselves in the 1TnR case, bit disturb effects are theoretically possible when operating on a single memory cell. Read operations are disclosed for two-terminal memory devices configured to mitigate bit disturb effects, despite a lack of isolation transistors among memory cells of an array. Disclosed operations can facilitate reduced bit disturb effects even for high density two-terminal memory cell arrays.

Abstract: A logical NAND memory architecture comprising two-terminal, non-volatile resistive memory is disclosed. By way of example, disclosed logical NAND architectures can comprise non-volatile memory cells having approximately 4F2 area. This facilitates very high memory densities, even for advanced technology nodes. Further, the disclosed architectures are CMOS compatible, and can be constructed among back-end-of-line (BEOL) metal layers of an integrated chip. In some embodiments, subsets of two-terminal memory cells in a NAND array can be constructed between different pairs of BEOL metal layers. In other embodiments, the two-terminal memory cells can be constructed between a single pair of BEOL metal layers.

Abstract: A method for erasing a memory cell includes applying a first erase to memory cells to erase the memory cells, wherein first memory cells are in a weakly erased state in response to the first erase, and wherein second memory cells are in a normally erased state in response to the first erase, thereafter applying a first weak program to the memory cells, wherein the second memory cells enter a programmed state and the third memory cells remain in the erased state in response to the first weak program, and thereafter applying a read to the memory cells to identify the second memory cells, and applying a second erase to the second memory cells to thereby erase the second memory cells.

Abstract: A non-volatile programmable circuit configurable to perform logic functions, is provided. The programmable circuit can employ two-terminal non-volatile memory devices to store information, thereby mitigating or avoiding disturbance of programmed data in the absence of external power. Two-terminal resistive switching memory devices having high current on/off ratios and fast switching times can also be employed for high performance, and facilitating a high density array. For look-up table applications, input/output response times can be several nanoseconds or less, facilitating much faster response times than a memory array access for retrieving stored data.

Abstract: A non-volatile programmable circuit configurable to perform logic functions, is provided. The programmable circuit can employ two-terminal non-volatile memory devices to store information, thereby mitigating or avoiding disturbance of programmed data in the absence of external power. Two-terminal resistive switching memory devices having high current on/off ratios and fast switching times can also be employed for high performance, and facilitating a high density array. For look-up table applications, input/output response times can be several nanoseconds or less, facilitating much faster response times than a memory array access for retrieving stored data.