Multimode Synaptic Operation of a HfAlO<i><sub>x</sub></i>-Based Memristor as a Metaplastic Device for Neuromorphic Applications

Shin, Hyung Seok; Song, Hanchan; Kim, Do Hoon; Martinez, Alba; Cheong, Woon Hyung; Kim, Kyung Min

doi:10.1021/acsaelm.2c00320

Cited by 5 publications

(4 citation statements)

References 49 publications

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“…In turn, in case of the emulation of the dynamics of individual network units, like single neuron or synapse with its own dynamics, the superimposition principle does not hold any more and use of volatile RRAMs for each network units provides a scaling advantage compared to the use of capacitors. In particular, volatile devices can be used to implement biological properties of individual synapses, like paired pulse facilitation and depression [57,62,145], metaplasticity [146] or short-to-long term memory [145] transition in case the same RRAM device shows both volatile to nonvolatile retention [92,93,147]. These functions, which cannot be efficiently implemented in conventional CMOS technology, have not been demonstrated neither with large statistics nor at array level, yet.…”

Section: Challenges Solutions and Perspectivesmentioning

confidence: 99%

HfO₂-based resistive switching memory devices for neuromorphic computing

Brivio

Spiga

Ielmini

2022

Neuromorph. Comput. Eng.

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HfO2-based resistive switching memory (RRAM) combines several outstanding properties, such as high scalability, fast switching speed, low power, compatibility with complementary metal-oxide-semiconductor technology, with possible high-density or three-dimensional integration. Therefore, today, HfO2 RRAMs have attracted a strong interest for applications in neuromorphic engineering, in particular for the development of artificial synapses in neural networks. This review provides an overview of the structure, the properties and the applications of HfO2-based RRAM in neuromorphic computing. Both widely investigated applications of nonvolatile devices and pioneering works about volatile devices are reviewed. The RRAM device is first introduced, describing the switching mechanisms associated to filamentary path of HfO2 defects such as oxygen vacancies. The RRAM programming algorithms are described for high-precision multilevel operation, analog weight update in synaptic applications and for exploiting the resistance dynamics of volatile devices. Finally, the neuromorphic applications are presented, illustrating both artificial neural networks with supervised training and with multilevel, binary or stochastic weights. Spiking neural networks are then presented for applications ranging from unsupervised training to spatio-temporal recognition. From this overview, HfO2-based RRAM appears as a mature technology for a broad range of neuromorphic computing systems.

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Section: Challenges Solutions and Perspectivesmentioning

confidence: 99%

HfO₂-based resistive switching memory devices for neuromorphic computing

Brivio

Spiga

Ielmini

2022

Neuromorph. Comput. Eng.

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“…[15,16] The MVM function is known to be achievable using memristor crossbar arrays with multilevel resistance state programmable characteristics. [17][18][19][20][21] In addition, the signal integration function can be implemented using the conductance integration characteristics. [22][23][24] While Figure 1.…”

Section: Introductionmentioning

confidence: 99%

Memristive Explainable Artificial Intelligence Hardware

Song,

Park,

Kim

et al. 2024

Advanced Materials

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Artificial intelligence (AI) is often considered a black box because it provides optimal answers without clear insight into its decision‐making process. To address this black box problem, explainable artificial intelligence (XAI) has emerged, which provides an explanation and interpretation of its decisions, thereby promoting the trustworthiness of AI systems. Here, a memristive XAI hardware framework is presented. This framework incorporates three distinct types of memristors (Mott memristor, valence change memristor, and charge trap memristor), each responsible for performing three essential functions (perturbation, analog multiplication, and integration) required for the XAI hardware implementation. Three memristor arrays with high robustness are fabricated and the image recognition of 3 × 3 testing patterns and their explanation map generation are experimentally demonstrated. Then, a software‐based extended system based on the characteristics of this hardware is built, simulating a large‐scale image recognition task. The proposed system can perform the XAI operations with only 4.32% of the energy compared to conventional digital systems, enlightening its strong potential for the XAI accelerator.

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“… Memristor: RS materials, structure design, performances, and applications. Reproduced with permission from [ 15 , 16 ] copyright 2021, Wiley, [ 17 ] copyright 2021, American Chemical Society, [ 18 ] copyright 2021, Springer Nature, [ 19 ] copyright 2021, American Chemical Society, [ 20 ] copyright 2018, Royal Society of Chemistry, [ 21 ] copyright 2022, Elsevier, [ 22 ] copyright 2020, Springer Nature, [ 23 ] copyright 2020, American Chemical Society, [ 24 ] copyright 2019, Wiley, [ 25 ] copyright 2022, American Chemical Society, [ 26 ] copyright 2022, Wiley. …”

Section: Introductionmentioning

confidence: 99%

A review of memristor: material and structure design, device performance, applications and prospects

Xiao

Jiang

Chen

et al. 2023

Science and Technology of Advanced Materials

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With the booming growth of artificial intelligence (AI), the traditional von Neumann computing architecture based on complementary metal oxide semiconductor devices are facing memory wall and power wall. Memristor based in-memory computing can potentially overcome the current bottleneck of computer and achieve hardware breakthrough. In this review, the recent progress of memory devices in material and structure design, device performance and applications are summarized. Various resistive switching materials, including electrodes, binary oxides, perovskites, organics, and two-dimensional materials, are presented and their role in the memristor are discussed. Subsequently, the construction of shaped electrodes, the design of functional layer and other factors influencing the device performance are analyzed. We focus on the modulation of the resistances and the effective methods to enhance the performance. Furthermore, synaptic plasticity, optical-electrical properties, the fashionable applications in logic operation and analog calculation are introduced. Finally, some critical issues such as the resistive switching mechanism, multi-sensory fusion, system-level optimization are discussed.

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Multimode Synaptic Operation of a HfAlO_x-Based Memristor as a Metaplastic Device for Neuromorphic Applications

Cited by 5 publications

References 49 publications

HfO₂-based resistive switching memory devices for neuromorphic computing

HfO₂-based resistive switching memory devices for neuromorphic computing

Memristive Explainable Artificial Intelligence Hardware

A review of memristor: material and structure design, device performance, applications and prospects

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Multimode Synaptic Operation of a HfAlOx-Based Memristor as a Metaplastic Device for Neuromorphic Applications

Cited by 5 publications

References 49 publications

HfO2-based resistive switching memory devices for neuromorphic computing

HfO2-based resistive switching memory devices for neuromorphic computing

Memristive Explainable Artificial Intelligence Hardware

A review of memristor: material and structure design, device performance, applications and prospects

Contact Info

Product

Resources

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Multimode Synaptic Operation of a HfAlO_x-Based Memristor as a Metaplastic Device for Neuromorphic Applications

HfO₂-based resistive switching memory devices for neuromorphic computing

HfO₂-based resistive switching memory devices for neuromorphic computing