S.A. Shchanikov scite author profile

Here we provide a perspective concept of neurohybrid memristive chip based on the combination of living neural networks cultivated in microfluidic/microelectrode system, metal-oxide memristive devices or arrays integrated with mixed-signal CMOS layer to control the analog memristive circuits, process the decoded information, and arrange a feedback stimulation of biological culture as parts of a bidirectional neurointerface. Our main focus is on the state-of-the-art approaches for cultivation and spatial ordering of the network of dissociated hippocampal neuron cells, fabrication of a large-scale crossbar array of memristive devices tailored using device engineering, resistive state programming, or non-linear dynamics, as well as hardware implementation of spiking neural networks (SNNs) based on the arrays of memristive devices and integrated CMOS electronics. The concept represents an example of a brain-on-chip system belonging to a more general class of memristive neurohybrid systems for a newgeneration robotics, artificial intelligence, and personalized medicine, discussed in the framework of the proposed roadmap for the next decade period.

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Designing a bidirectional, adaptive neural interface incorporating machine learning capabilities and memristor-enhanced hardware

Shchanikov

Zuev

Bordanov

et al. 2021

Chaos, Solitons & Fractals

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Noise-assisted persistence and recovery of memory state in a memristive spiking neuromorphic network

Surazhevsky

Демин

Ilyasov

et al. 2021

Chaos, Solitons & Fractals

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The research of memristor-based neural network components operation accuracy in control and communication systems

Danilin

Shchanikov

Galushkin

2015

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Toward Reflective Spiking Neural Networks Exploiting Memristive Devices

Makarov

Lobov

Shchanikov

et al. 2022

Front. Comput. Neurosci.

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The design of modern convolutional artificial neural networks (ANNs) composed of formal neurons copies the architecture of the visual cortex. Signals proceed through a hierarchy, where receptive fields become increasingly more complex and coding sparse. Nowadays, ANNs outperform humans in controlled pattern recognition tasks yet remain far behind in cognition. In part, it happens due to limited knowledge about the higher echelons of the brain hierarchy, where neurons actively generate predictions about what will happen next, i.e., the information processing jumps from reflex to reflection. In this study, we forecast that spiking neural networks (SNNs) can achieve the next qualitative leap. Reflective SNNs may take advantage of their intrinsic dynamics and mimic complex, not reflex-based, brain actions. They also enable a significant reduction in energy consumption. However, the training of SNNs is a challenging problem, strongly limiting their deployment. We then briefly overview new insights provided by the concept of a high-dimensional brain, which has been put forward to explain the potential power of single neurons in higher brain stations and deep SNN layers. Finally, we discuss the prospect of implementing neural networks in memristive systems. Such systems can densely pack on a chip 2D or 3D arrays of plastic synaptic contacts directly processing analog information. Thus, memristive devices are a good candidate for implementing in-memory and in-sensor computing. Then, memristive SNNs can diverge from the development of ANNs and build their niche, cognitive, or reflective computations.

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Silicon-Compatible Memristive Devices Tailored by Laser and Thermal Treatments

Koryazhkina

Филатов

Тихов

et al. 2022

JLPEA

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Nowadays, memristors are of considerable interest to researchers and engineers due to the promise they hold for the creation of power-efficient memristor-based information or computing systems. In particular, this refers to memristive devices based on the resistive switching phenomenon, which in most cases are fabricated in the form of metal–insulator–metal structures. At the same time, the demand for compatibility with the standard fabrication process of complementary metal–oxide semiconductors makes it relevant from a practical point of view to fabricate memristive devices directly on a silicon or SOI (silicon on insulator) substrate. Here we have investigated the electrical characteristics and resistive switching of SiOx- and SiNx-based memristors fabricated on SOI substrates and subjected to additional laser treatment and thermal treatment. The investigated memristors do not require electroforming and demonstrate a synaptic type of resistive switching. It is found that the parameters of resistive switching of SiOx- and SiNx-based memristors on SOI substrates are remarkably improved. In particular, the laser treatment gives rise to a significant increase in the hysteresis loop in I–V curves of SiNx-based memristors. Moreover, for SiOx-based memristors, the thermal treatment used after the laser treatment produces a notable decrease in the resistive switching voltage.

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Determining Operation Tolerances of Memristor-Based Artificial Neural Networks

Danilin

Shchanikov

Пантелеев

2016

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The development of a neuronetwork component for technical systems of mechanical engineering

Danilin

Makarov

Shchanikov

2014

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S.A. Shchanikov

Neurohybrid Memristive CMOS-Integrated Systems for Biosensors and Neuroprosthetics

Designing a bidirectional, adaptive neural interface incorporating machine learning capabilities and memristor-enhanced hardware

Noise-assisted persistence and recovery of memory state in a memristive spiking neuromorphic network

The research of memristor-based neural network components operation accuracy in control and communication systems

Toward Reflective Spiking Neural Networks Exploiting Memristive Devices

Silicon-Compatible Memristive Devices Tailored by Laser and Thermal Treatments

Determining Operation Tolerances of Memristor-Based Artificial Neural Networks

The development of a neuronetwork component for technical systems of mechanical engineering

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