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Dr. Yakov Roizin - Resistive Memories Promising for Industrial Applications - YouTube
Dr. Yakov Roizin of TowerJazz - Resistive Memories Promising for Industrial Applications - IEEE / ACRC Workshop on Memristors and Resistive Memory Devices
and Applications in Computer Architecture and Brain-Inspired Systems. March 7, 2012 Technion Faculty of Electrical Engineering.
Analytic Models for Memristor-based Crossbar Write Operation - YouTube
List of publications on this subject can be found at
https://scholar.google.com/citations?user=bvSd44cAAAAJ&hl=en.
I can be contacted via https://www.linkedin.com/in/dotrimar/
A system integrating echo state graph neural networks and analogue random resistive memory arrays - YouTube
Read more at https://techxplore.com/news/2023-03-echo-state-graph-neural-networks-1.html
In this video: The echo state layer for graph embedding. The hidden state of a node in the graph is updated with the projection of the node itself and the previous hidden state of the neighboring nodes, both are processed with the fix and random echo state layer implemented with random memristive array.
Video Credit: Wang et al.
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Control of Switching Modes and Conductance Quantization in Memristive Devices - YouTube
Control of Switching Modes and Conductance Quantization in Oxygen Engineered HfOx based Memristive Devices: Oxygen stoichiometry engineering is intrinsically achieved in hafniumoxide-based memristive devices via reactive molecular beam epitaxy in a Pt/HfOx/TiN device configuration. This allows for uncovering the nature of complex coexistence of multiple switching modes (unipolar, bipolar, complementary, threshold) and occurrence of quantum conductance states. The findings are relevant to the control of switching dynamics in all oxide-based switching devices. This is reported by Sankaramangalam Ulhas Sharath, Stefan Vogel, Leopoldo Molina-Luna, Erwin Hildebrandt, Christian Wenger, Jose Kurian, Michael Duerrschnabel, Tore Niermann, Gang Niu, Pauline Calka, Michael Lehmann, Hans-Joachim Kleebe, Thomas Schroeder, and Lambert Alff in the article https://doi.org/10.1002/adfm.201700432. To know more, please go to the Advanced Functional Materials homepage.
In-memory Computing with Memristors and Memtransistors - Daniele Ielmini - YouTube
This tutorial has been part of the Conference on Neuromorphic Materials, Devices, Circuits and Systems (NeuMatDeCas) that took place from the 23rd to the 25th.
Memristor and Memristive Systems Symposium (Part 2) - YouTube
In 1971, Leon O. Chua published a seminal paper on the missing basic circuit element. Leon O. Chua and Sung-Mo Kang published a paper, in 1976, that described a large class of devices and systems they called memristive devices and systems. Just recently, Stan Williams and his research team at HP Labs unveiled a two-terminal titanium dioxide nanoscale device in Nature magazine that exhibited memristor characteristics.
This symposium will explore the potential of memristors and memristive systems as they advance state of the art nano-electronic circuits.
Program (Part 2)
Memristors as Synapses in a Neural Computing Architecture
Greg Snider, Senior Architect, Information and Quantum Systems Laboratory, Hewlett-Packard Laboratories
Prospects and Challenges of Redox-based Memristive RRAM Concpets
Rainer Waser, RWTH Aachen University at Research Center Juelich, Germany
The event is co-sponsored by UC Merced and UC Berkeley in cooperation with the Semiconductor Industry Association (SIA). The Symposium is funded by the National Science Foundation.
Neuromorphic computing with memristors: from device to system - Professor Huaqiang Wu - YouTube
Recently, computation in memory becomes very hot due to the urgent needs of high computing efficiency in artificial intelligence applications. In contrast to von-neumann architecture, computation in memory technology avoids the data movement between CPU/GPU and memory which could greatly reduce the power consumption.Memristor is one ideal device which could not only store information with multi-bits, but also conduct computing using ohm’s law. To make the best use of the memristor in neuromorphic systems, a memristor-friendly architecture and the software-hardware collaborative design methods are essential, and the key problem is how to utilize the memristor’s analog behavior.We have designed a generic memristor crossbar based architecture for convolutional neural networks and perceptrons, which take full consideration of the analog characteristics of memristors. Furthermore, we have proposed an online learning algorithm for memristor based neuromorphic systems which overcomes the varation of memristor cells and endue the system the ability of reinforcement learning based on memristor’s analog behavior.
Full abstract and speaker details can be found here: https://nus.edu/3cSFD3e
Register for free for all our upcoming webinars at https://nus.edu/3bcN9pS.
Memristive Dynamics Based Hardware Primitives for Efficient Computing - YouTube
HKU EEE x IEEE HK ED/SSC Distinguished Speaker Series
Speaker: Prof. Yuchao Yang, Director of Center for Brain Inspired Chips, Peking University
Date: 27 August 2021
For more seminars, see https://r10.ieee.org/hk-edssc/
Redox-based memristive devices for new computing paradigm | APL Materials | AIP Publishing
Memristive devices have been a hot topic in nanoelectronics for the last two decades in both academia and industry. Originally proposed as digital (binary) nonv
Imperfection-enabled memristive switching in van der Waals materials | Nature Electronics
Nature Electronics - This Review examines switching mechanisms in memristive devices based on van der Waals materials, and explores the advantages such devices offer and the challenges that must be...
Memristive Neuromorphics: Materials, Devices, Circuits, Architectures, Algorithms and their Co-Design | Frontiers Research Topic
The confluence of Big Data, IoT and Real-Time Analytics calls for rethinking of the hardware computing paradigm, either by the bottom up or top down approach. Memristive neuromorphic systems inspired by brain functions and implemented through new materials properties, bionic memristive devices (e.g., artificial synapses and neurons) and neural network circuits, are emerging with the promise of transforming the semiconductor information processing technology.Since the experimental discovery of memristors twelve years ago, memristive neuromorphic hardware has continued to make big strides. On the level of the material, a huge number of materials of various categories have shown memristive properties and this number continues to increase rapidly. In such a growing filed, there is a crucial need to establish materials selection rules and evaluate the suitability of the corresponding devices for neuromorphic systems. Device yield testing, performance distribution analysis and circuit reliability simulations have to be performed and standardized to turn these materials research endeavors into real impact. On the device level, researchers have showcased devices with diverse physical mechanisms, primary neuromorphic functions, and intriguing performances. Highly reproducible devices with desired characteristics, and versatile devices integrating multiple neural dynamics and computational capabilities remain to be demonstrated to further boost the system performance and functionali...
Using machine intelligence to find the charge density wave phases of any 2D material
Charge density wave (CDW) is a quantum mechanical phenomenon, which induces distortion in the crystal structures of some low-dimensional (1D or 2D) metals, when the temperature is reduced. Such distorted crystal structure is known as CDW phase and its resistivity is much higher than the original symmetric phase. Since the switching between symmetric and CDW phase can also be made by the application of external electric field, these materials are technologically important and have attracted immense attention in the nanoelectronics community.