Application of Memristors in Hardware Security: A Current State‐of‐the‐Art Technology

Lv, Shiya; Liu, Jian; Geng, Zhaoxin

doi:10.1002/aisy.202000127

Cited by 28 publications

(54 citation statements)

References 93 publications

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“…35−38 Hybrid memristor-CMOS circuits have been used to demonstrate PUFs with higher attack resilience, lower hardware overhead, and lower energy consumption. 39,40 Similarly, hybrid memristor-CMOS circuit models have been proposed to obfuscate IC layouts using polymorphic gates and cyclic-locking schemes. 41 Models of chaotic memristive systems using Chua circuits have also been demonstrated for encryption and secure communication.…”

Section: Resultsmentioning

confidence: 99%

“…Note that several demonstrations on memristor-based crossbar arrays have utilized the process variations and inherent stochasticity for device authentication and random number generation. − Hybrid memristor-CMOS circuits have been used to demonstrate PUFs with higher attack resilience, lower hardware overhead, and lower energy consumption. , Similarly, hybrid memristor-CMOS circuit models have been proposed to obfuscate IC layouts using polymorphic gates and cyclic-locking schemes . Models of chaotic memristive systems using Chua circuits have also been demonstrated for encryption and secure communication. , While promising, two-terminal memristor-based non-von Neumann platforms are limited in computational capability and require CMOS peripherals and sensors, which increases area and energy overhead.…”

Section: Resultsmentioning

confidence: 99%

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Secure Electronics Enabled by Atomically Thin and Photosensitive Two-Dimensional Memtransistors

Oberoi

Dodda

et al. 2021

ACS Nano

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The rapid proliferation of security compromised hardware in today’s integrated circuit (IC) supply chain poses a global threat to the reliability of communication, computing, and control systems. While there have been significant advancements in detection and avoidance of security breaches, current top-down approaches are mostly inadequate, inefficient, often inconclusive, and resource extensive in time, energy, and cost, offering tremendous scope for innovation in this field. Here, we introduce an energy and area efficient non-von Neumann hardware platform providing comprehensive and bottom-up security solutions by exploiting inherent device-to-device variation, electrical programmability, and persistent photoconductivity demonstrated by atomically thin two-dimensional memtransistors. We realize diverse security primitives including physically unclonable function, anticounterfeit measures, intellectual property (IP) watermarking, and IC camouflaging to prevent false authentication, detect recycled and remarked ICs, protect IP theft, and stop reverse engineering of ICs.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Secure Electronics Enabled by Atomically Thin and Photosensitive Two-Dimensional Memtransistors

Oberoi

Dodda

et al. 2021

ACS Nano

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“…Over the last decade, the unpredictable behavior of RSMs has been demonstrated to be an efficient way to create true random number generators (Shen et al, 2021;Gaba et al, 2013;Yang et al, 2020b;Hu et al, 2016;Faria et al, 2018;Bao et al, 2020) that can be used for security purposes (Khan et al, 2021;Pang et al, 2019;Lv et al, 2020). For machine learning applications, the Gaussian nature of the stochastic distribution turns out to be an efficient way to implement probabilistic computing in hardware (Table 1).…”

Section: Rsm-based Methodsmentioning

confidence: 99%

Exploiting Non-idealities of Resistive Switching Memories for Efficient Machine Learning

et al. 2022

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Novel computing architectures based on resistive switching memories (also known as memristors or RRAMs) have been shown to be promising approaches for tackling the energy inefficiency of deep learning and spiking neural networks. However, resistive switch technology is immature and suffers from numerous imperfections, which are often considered limitations on implementations of artificial neural networks. Nevertheless, a reasonable amount of variability can be harnessed to implement efficient probabilistic or approximate computing. This approach turns out to improve robustness, decrease overfitting and reduce energy consumption for specific applications, such as Bayesian and spiking neural networks. Thus, certain non-idealities could become opportunities if we adapt machine learning methods to the intrinsic characteristics of resistive switching memories. In this short review, we introduce some key considerations for circuit design and the most common non-idealities. We illustrate the possible benefits of stochasticity and compression with examples of well-established software methods. We then present an overview of recent neural network implementations that exploit the imperfections of resistive switching memory, and discuss the potential and limitations of these approaches.

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“…[9] This provides several advantages in suppressing leakage-currents and increased mechanical flexibility. [8] Recently, 2D transition-metal dichalcogenides, [10] transition-metal oxide (such as MoO 3 ), [8] hexagonal boron nitride (h-BN), [11] and elemental black phosphorus (BP) [12] have been used in vertically stacked resistive memory devices. These results are significant, however there remain quite a few areas that need further investigation in the domain of 2D material-based resistive memory technologies.…”

mentioning

confidence: 99%

“…These results are significant, however there remain quite a few areas that need further investigation in the domain of 2D material-based resistive memory technologies. [5,8,[11][12][13][14][15] These include investigations into charge transport mechanisms in vertically stacked van der Waals structures and understanding the role of energy barrier of the van der Waals layers to the out-of-plane cationic and anionic diffusion.…”

mentioning

confidence: 99%

Nonvolatile Resistive Switching in Layered InSe via Electrochemical Cation Diffusion

Mazumder

Ahmed

Mayes

et al. 2021

Adv Elect Materials

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2D materials are increasingly being investigated for their nonvolatile switching properties as a step toward downscaling of core electronic elements. Here, the interplay between electrochemically active silver (Ag) cations and layered indium selenide (InSe), a 2D metal monochalcogenide, is investigated to demonstrate a nonvolatile switching device. Detailed microscopic characterization supported with density functional theory calculations reveals cationic filamentary‐based nonvolatile switching mechanism of γ‐InSe in a crossplanar architecture. This is electrically driven by diffusion of Ag ions through the layered InSe stack. The InSe‐based memory cells exhibit a switching ratio of ≈103 and a memory retention of >105 s. This work opens new opportunities to enhance resistive switching performances of 2D materials for next‐generation information storage and brain inspired computation using active metal diffusion.

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Application of Memristors in Hardware Security: A Current State‐of‐the‐Art Technology

Cited by 28 publications

References 93 publications

Secure Electronics Enabled by Atomically Thin and Photosensitive Two-Dimensional Memtransistors

Secure Electronics Enabled by Atomically Thin and Photosensitive Two-Dimensional Memtransistors

Exploiting Non-idealities of Resistive Switching Memories for Efficient Machine Learning

Nonvolatile Resistive Switching in Layered InSe via Electrochemical Cation Diffusion

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