Abstract: A neuromorphic computing system includes a synapse array, a switching circuit, a sensing circuit and a processing circuit. The synapse array includes row lines, column lines and synapses. The processing circuit is coupled to the switching circuit and the sensing circuit and is configured to connect a particular column line in the column lines to the first terminal by using the switching circuit, obtain a first voltage value from the particular column line by using the sensing circuit when the particular line is connected to the first terminal, connect the particular column line to the second terminal by using the switching circuit, obtain a second voltage value from the particular column line by using the sensing circuit when the particular line is connected to the second terminal, and estimate a sum-of-product sensing value according to a voltage difference between the first voltage value and the second voltage value.

Abstract: A contact hole structure includes a substrate, an interlayer dielectric (ILD), a conductive layer and an insulating capping layer. The ILD is disposed on the substrate and has a first opening. The conductive layer is disposed in the ILD and aligns the first opening. The insulating capping layer has a spacer disposed on a first sidewall of the first opening, wherein the spacer contacts to the conductive layer and defines a second opening in the first opening, so as to expose a portion of the conductive layer.

Abstract: An array of resistance cells has a number M of rows and a number N of columns of resistance cells. Each cell comprises a transistor having a threshold, representing a weight factor Wnm of the cell, and a resistive element in series with the transistor. Each cell has a cell resistance having a first value when the transistor is on and a second value when the transistor is off. A set of source lines is coupled to the resistance cells in respective columns. A set of bit lines is coupled to the resistance cells in respective rows, signals on the bit lines representing inputs x(m) to the respective rows. A set of word lines is coupled to gates of the transistors in the resistance cells in respective columns. Current sensed at a particular source line represents a sum of products of the inputs x(m) by respective weight factors Wnm.

Abstract: A method for treating a semiconductor structure is provided. A semiconductor structure comprising memory devices is provided. A forming process is conducted to initialize operation of the memory devices. The semiconductor structure is subjected to a forming thermal treatment, and step of saving data to the memory devices is performed after the forming thermal treatment.

Abstract: A semiconductor device includes a substrate and a memory structure disposed above the substrate. An embodied memory structure includes a bottom electrode disposed above the substrate, a barrier layer disposed at the bottom electrode, a resistance switching layer disposed on the bottom electrode and above the barrier layer, and a top electrode disposed on the resistance switching layer and covering the resistance switching layer. A bottom surface of the resistance switching layer is spaced apart from an uppermost surface of the barrier layer by a distance.

Abstract: The present invention relates to metal oxide based memory devices and methods for manufacturing such devices, and more particularly to memory devices having data storage materials based on metal oxide compounds fabricated with a biased plasma oxidation process which improves the interface between the memory element and a top electrode for a more a uniform electrical field during operation, which improves device reliability.

Abstract: A ReRAM device is provided. The ReRAM device comprises a first dielectric layer disposed on a substrate and covering a gate oxide structure on the substrate, a first conductive connecting structure disposed on the substrate and penetrating the first dielectric layer, and a ReRAM unit disposed on the first conductive connecting structure. The first dielectric layer comprises a first insulating layer disposed on the substrate, and a stop layer disposed on the first insulating layer and contacting a top surface of the gate oxide structure, wherein the stop layer is a hydrogen controlled layer.

Abstract: A method for physically unclonable function-identification (PUF-ID) generation includes: providing a PUF array having programmable resistance memory cells; performing a forming procedure followed by a programming procedure on all of the programmable resistance memory cells of the PUF array; performing an estimation process to estimate randomness of the PUF array, by comparing a reference current of a base unit to a total current passing through all of the programmable resistance memory cells for obtaining a PUF randomness; determining a setting result of randomness based on the estimation process; and generating a PUF-ID according to the setting result of randomness.

Abstract: A cover for an electronic device and methods of forming a cover is disclosed. The electronic device may include a housing, and a cover coupled to the housing. The cover may have an inner surface having at least one of an intermediate polish and a final polish, a groove formed on the inner surface, and an outer surface positioned opposite the inner surface. The outer surface may have at least one of the intermediate polish and the final polish. The cover may also have a rounded perimeter portion formed between the inner surface and the outer surface. The rounded perimeter portion may be positioned adjacent the groove. The method for forming the cover may include performing a first polishing process on the sapphire component using a polishing tool, and performing a second polishing process on the groove of the sapphire component forming the cover using blasting media.

Abstract: A cover for an electronic device and methods of forming a cover is disclosed. The electronic device may include a housing, and a cover coupled to the housing. The cover may have an inner surface having at least one of an intermediate polish and a final polish, a groove formed on the inner surface, and an outer surface positioned opposite the inner surface. The outer surface may have at least one of the intermediate polish and the final polish. The cover may also have a rounded perimeter portion formed between the inner surface and the outer surface. The rounded perimeter portion may be positioned adjacent the groove. The method for forming the cover may include performing a first polishing process on the sapphire component using a polishing tool, and performing a second polishing process on the groove of the sapphire component forming the cover using blasting media.

Abstract: A method to program a programmable resistance memory cell includes performing one or more iterations until a verifying passes. The iterations include a) applying a programming pulse to the memory cell, and, b) after applying the programming pulse, verifying if the resistance of the memory cell is in a target resistance range. After an iteration of the one or more iterations in which the verifying passes, c) a stabilizing pulse with a polarity the same as the programming pulse is applied to the memory cell. After applying the stabilizing pulse, a second verifying determines if the resistance of the programmable element is in the target resistance range. Iterations comprising steps a), b), c), and d) are performed until the second verifying passes. Methods and apparatus are described to program a plurality of such cells, including applying a stabilizing pulse of the same polarity after programming.

Abstract: A method for operating a resistance switching memory device is provided, wherein the method includes a first program process, and the first program process includes steps as follows: A programming pulse having a first polarity is firstly applied to at least one resistance switching memory cell of the NVM device. A first verifying pulse with a verifying voltage is then applied to the resistance switching memory cell. A first settling pulse is applied to the resistance switching memory cell prior to or after the verifying pulse is applied, wherein the first settling pulse includes a settling voltage having a second polarity opposite to the first polarity and an absolute value substantially less than that of the verifying voltage.

Abstract: A semiconductor memory device includes: a memory array including a plurality of memory cells, the memory cells being in any of a high resistance state (HRS) and a low resistance state (LRS); a reference array including a plurality of reference cells, the memory cells and the reference cells having the same impedance-temperature relationship, the reference cells being in a middle resistance state between HRS and LRS; an average circuit configured for averaging respective reference currents from the reference cells of the reference array into an average reference current; and a comparator configured for comparing a plurality of respective memory currents from the memory cells of the memory array with the average reference current to obtain a plurality of output data of the memory cells of the memory array and to determine respective impedance states of the memory cells of the memory array.

Abstract: A method for manufacturing a resistive memory device is disclosed and comprises following steps. Firstly, a bottom electrode is formed over a substrate. Next, an oxidation process is performed to the bottom electrode to form a metal oxide layer, wherein a hydrogen plasma and an oxygen plasma are provided during the oxidation process. Then, a top electrode is formed on the metal oxide layer.

Abstract: A semiconductor device including a memory cell structure is provided, and the memory cell structure includes an insulating layer disposed above a substrate, a bottom electrode embedded in the insulating layer, a resistance switching layer disposed on the bottom electrode, and a top electrode disposed on the resistance switching layer and covering the resistance switching layer. Also, the bottom electrode has a concave top surface lower than a flat upper surface of the insulating layer.

Abstract: A semiconductor memory device includes programmable resistance memory cells and a controller which applies a forming pulse to first and second groups of the programmable resistance memory cells for inducing a change in the first group from an initial resistance range to an intermediate resistance range, and for inducing the second group having a resistance outside the intermediate range. When a forming rate is lower than a first forming threshold rate, the controller adjusts the forming pulse until the forming rate is higher than the first forming threshold rate. When a forming rate is higher than the first forming threshold rate but lower than a second forming threshold rate, the controller adjusts the forming pulse until the forming rate is higher than the second forming threshold rate. The controller applies a programming pulse to the first and second groups and generates a chip ID of the semiconductor memory device.

Abstract: A resistance switching memory device is provided, including an insulating layer having a top surface, a bottom electrode embedded in the insulating layer, a resistance switching layer disposed on the bottom electrode, and a top electrode formed on the resistance switching layer and covering the resistance switching layer. Also, the bottom electrode has an upper portion protruding from the top surface of the insulating layer, and the upper portion has round corners at edges.

Abstract: A method for generating a data set on an integrated circuit including programmable resistance memory cells includes applying a forming pulse to all members of a set of the programmable resistance memory cells. The forming pulse has a forming pulse level characterized by inducing a change in resistance in a first subset of the set from an initial resistance range to an intermediate resistance range, while after the forming pulse a second subset of the set has a resistance outside the intermediate range. The method includes applying a programming pulse to the first and second subsets. The programming pulse has a programming pulse level characterized by inducing a change in resistance of the first subset from the intermediate range to a first final range, while after the programming pulse the second subset has a resistance in a second final range, whereby the first and second subsets store said data set.

Abstract: A memory architecture has improved controllability of operations for bipolar current directions used to write data in programmable resistance memory cells, including ReRAM cells based on metal oxide memory materials. Instead of a fixed gate voltage on a specific decoder transistor or cell selection device, and a control voltage set to values that cause the decoder transistor or cell selection device to operate in a fully-on mode for one current direction or in a current moderating mode with opposite current direction. Using this technology allows symmetrical or close to symmetrical operation in both current directions with little or no effect on the array complexity.

Abstract: A memory structure and a manufacturing method for the same are disclosed. The memory structure comprises a lower electrode, an upper insulating layer, a material layer, a dielectric film, and an upper electrode. The upper insulating layer is on the lower electrode. The material layer is on the upper insulating layer. The upper insulating layer and the material layer have a common opening to expose a portion of the lower electrode. The dielectric film is on the exposed portion of the lower electrode. The dielectric film and the material layer contain a same first transition metal. The upper electrode is on the dielectric film and fills the common opening.