A Review of Artificial Spiking Neuron Devices for Neural Processing and Sensing

Han, Joon‐Kyu; Yun, Seong‐Yun; Lee, Sang‐Won; Yu, Ji‐Man; Choi, Yang‐Kyu

doi:10.1002/adfm.202204102

Cited by 76 publications

(39 citation statements)

References 98 publications

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“…In this regard, memristors have emerged as promising contenders for artificial synaptic application. [177][178][179] For memristors, the change of conductance during operation can be utilized to emulate the change of synaptic weight (ΔW), which is defined as ΔW = (G post − G pre )/G pre × 100%, where G pre and G post respectively represent the conductance of the memristor in response to the presynaptic and postsynaptic pulses. When Δt (i.e., t post − t pre ) and ΔW are both positive, the electrical potentiation of memristor occurs.…”

Section: (11 Of 23)mentioning

confidence: 99%

Emerging MXene‐Based Memristors for In‐Memory, Neuromorphic Computing, and Logic Operation

Ling

Zhang

et al. 2022

Adv Funct Materials

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Confronted by the difficulties of the von Neumann bottleneck and memory wall, traditional computing systems are gradually inadequate for satisfying the demands of future data-intensive computing applications. Recently, memristors have emerged as promising candidates for advanced in-memory and neuromorphic computing, which pave one way for breaking through the dilemma of current computing architecture. Till now, varieties of functional materials have been developed for constructing high-performance memristors. Herein, the review focuses on the emerging 2D MXene materials-based memristors. First, the mainstream synthetic strategies and characterization methods of MXenes are introduced. Second, the different types of MXenebased memristive materials and their widely adopted switching mechanisms are overviewed. Third, the recent progress of MXene-based memristors for data storage, artificial synapses, neuromorphic computing, and logic circuits is comprehensively summarized. Finally, the challenges, development trends, and perspectives are discussed, aiming to provide guidelines for the preparation of novel MXene-based memristors and more engaging information technology applications.

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Section: (11 Of 23)mentioning

confidence: 99%

Emerging MXene‐Based Memristors for In‐Memory, Neuromorphic Computing, and Logic Operation

Ling

Zhang

et al. 2022

Adv Funct Materials

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“…For example, the postsynaptic potential is accumulated by repetitive presynaptic potentials, and the neurons fire the action potential once the postsynaptic potential exceeds the threshold. Such properties can be realized by using external electronic circuits (e.g., comparators and reset circuits) or by integrating two or more optoelectronic components; 131 however, they are not ideal in terms of power consumption and hardware complexity. 132 In this regard, the realization of such properties at the single-device level would be beneficial for energy-efficient machine vision as well as module miniaturization.…”

Section: Conclusion and Prospectsmentioning

confidence: 99%

Nanomaterial-Based Synaptic Optoelectronic Devices for In-Sensor Preprocessing of Image Data

et al. 2023

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With the advance in information technologies involving machine vision applications, the demand for energy- and time-efficient acquisition, transfer, and processing of a large amount of image data has rapidly increased. However, current architectures of the machine vision system have inherent limitations in terms of power consumption and data latency owing to the physical isolation of image sensors and processors. Meanwhile, synaptic optoelectronic devices that exhibit photoresponse similar to the behaviors of the human synapse enable in-sensor preprocessing, which makes the front-end part of the image recognition process more efficient. Herein, we review recent progress in the development of synaptic optoelectronic devices using functional nanomaterials and their unique interfacial characteristics. First, we provide an overview of representative functional nanomaterials and device configurations for the synaptic optoelectronic devices. Then, we discuss the underlying physics of each nanomaterial in the synaptic optoelectronic device and explain related device characteristics that allow for the in-sensor preprocessing. We also discuss advantages achieved by the application of the synaptic optoelectronic devices to image preprocessing, such as contrast enhancement and image filtering. Finally, we conclude this review and present a short prospect.

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“…Inspired by the biological sensory processing paradigm, the artificial spiking receptor (ASR) has aroused extensive interesting recently [2], [3], [5], [6], [7], [8], [9], [10], [11]. For example, a spiking photoreceptor based on indium gallium zinc oxide (IGZO) has been proposed with the capability to convert UV light into a spike train at a rate dependent on the light wavelength.…”

Section: Introductionmentioning

confidence: 99%

An Oxide Based Spiking Thermoreceptor for Low-Power Thermography Edge Detection

Shi

Heng

Wang

et al. 2022

IEEE Electron Device Lett.

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Thermoreceptors can encode thermal stimuli into spikes that are processed by the neural network to endow human with thermal perception. Such energy-efficiency and robust interaction with real-world have inspired the rise of the artificial spiking thermoreceptor (AST). However, monolithic spiking thermoreceptor is still rarely reported, which may due to the lack of device that can simultaneously implement temperature-sensing and spikeencoding functions. Here, we demonstrate an artificial spiking thermoreceptor based on Ag/TaO X /AlO X /ITO threshold switching memristor to achieve human-like thermal perception. The device is able to encode thermal information into spikes at a low power consumption (<240 nW). These advantages consequently facilitate the demonstration of power efficient and accurate thermography edge detection based on the array of such AST and a pulse coupled neural network (PCNN).

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A Review of Artificial Spiking Neuron Devices for Neural Processing and Sensing

Cited by 76 publications

References 98 publications

Emerging MXene‐Based Memristors for In‐Memory, Neuromorphic Computing, and Logic Operation

Emerging MXene‐Based Memristors for In‐Memory, Neuromorphic Computing, and Logic Operation

Nanomaterial-Based Synaptic Optoelectronic Devices for In-Sensor Preprocessing of Image Data

An Oxide Based Spiking Thermoreceptor for Low-Power Thermography Edge Detection

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