Toward Reflective Spiking Neural Networks Exploiting Memristive Devices

Makarov, Valeri A.; Lobov, Sergey; Shchanikov, S.A.; Mikhaylov, A. N.; Kazantsev, Viktor

doi:10.3389/fncom.2022.859874

Cited by 24 publications

(13 citation statements)

References 207 publications

(245 reference statements)

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“…However, all these difficulties are technical and can be solved using a neurohybrid approach with memristive devices instead of internetwork axons. Memristors and memristive systems [57], which are implemented in the form of a CMOS-compatible nanostructure with a memory effect, are ideally suited for the role of such connections [44,58]. Recently, the first step in this direction has been taken: commercial memristive devices with the effect of short-term plasticity are used to arrange communication between individual subnets in vitro and provide synchronous activity of target subnets under the control of the source subnet [59].…”

Section: Discussionmentioning

confidence: 99%

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Spatial Computing in Modular Spiking Neural Networks with a Robotic Embodiment

Lobov

Mikhaylov

et al. 2023

Mathematics

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One of the challenges in modern neuroscience is creating a brain-on-a-chip. Such a semiartificial device based on neural networks grown in vitro should interact with the environment when embodied in a robot. A crucial point in this endeavor is developing a neural network architecture capable of associative learning. This work proposes a mathematical model of a midscale modular spiking neural network (SNN) to study learning mechanisms within the brain-on-a-chip context. We show that besides spike-timing-dependent plasticity (STDP), synaptic and neuronal competitions are critical factors for successful learning. Moreover, the shortest pathway rule can implement the synaptic competition responsible for processing conditional stimuli coming from the environment. This solution is ready for testing in neuronal cultures. The neuronal competition can be implemented by lateral inhibition actuating over the SNN modulus responsible for unconditional responses. Empirical testing of this approach is challenging and requires the development of a technique for growing cultures with a given ratio of excitatory and inhibitory neurons. We test the modular SNN embedded in a mobile robot and show that it can establish the association between touch (unconditional) and ultrasonic (conditional) sensors. Then, the robot can avoid obstacles without hitting them, relying on ultrasonic sensors only.

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Section: Discussionmentioning

confidence: 99%

“…Earlier, we formulated the basic principles of associative learning in SNNs [33,43,44]. They are (i) Hebbian learning (using STDP), (ii) synaptic competition or competition of SNN inputs, and (iii) neural competition or competition of SNN outputs.…”

Section: Introductionmentioning

confidence: 99%

Spatial Computing in Modular Spiking Neural Networks with a Robotic Embodiment

Lobov

Mikhaylov

et al. 2023

Mathematics

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“…33 Another way to mitigate the problem of memristive variations is to realize spiking NCSs with bio-inspired algorithms. [34][35][36][37][38] Although there is certain progress in the training of spiking NCSs, such as deep learning-inspired approaches, 39 surrogate gradient learning 40 and Python packages for spiking NCSs modelling like SpikingJelly 41 and SNNTorch, 39 efficient training algorithms for spiking NCSs are still underdeveloped, which complicates the transfer of memristor-based spiking NCSs from the current device level to a large system level. 42 Consequently, the search for new efficient memristor-based NCS architectures and training algorithms is of high interest.…”

Section: Introductionmentioning

confidence: 99%

Adapted MLP-Mixer network based on crossbar arrays of fast and multilevel switching (Co–Fe–B)_x(LiNbO₃)_100−x nanocomposite memristors

Iliasov,

Matsukatova,

Emelyanov

et al. 2024

Nanoscale Horiz.

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“…Reflective SNNs can make use of their inherent dynamics to mimic complicated, nonreflexive brain functions, such as the creation of new skills from previously learned ones. SNNs can be implemented as analog computational systems [ 13 ]. In addition to the abovementioned areas of application, SNNs are also used in the areas of cognitive processing.…”

Section: Introductionmentioning

confidence: 99%

“…As mentioned, the subject of SNNs involves many different hardware architectures and many different applications and research areas. SNNs are also the subject of many review articles [ 13 , 35 ]. In this review, we focus on the main learning approaches for SNNs in terms of their efficiency on synchronous digital hardware.…”

Section: Introductionmentioning

confidence: 99%

Overview of Spiking Neural Network Learning Approaches and Their Computational Complexities

Pietrzak

Szczęsny

Huderek

et al. 2023

Sensors

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Spiking neural networks (SNNs) are subjects of a topic that is gaining more and more interest nowadays. They more closely resemble actual neural networks in the brain than their second-generation counterparts, artificial neural networks (ANNs). SNNs have the potential to be more energy efficient than ANNs on event-driven neuromorphic hardware. This can yield drastic maintenance cost reduction for neural network models, as the energy consumption would be much lower in comparison to regular deep learning models hosted in the cloud today. However, such hardware is still not yet widely available. On standard computer architectures consisting mainly of central processing units (CPUs) and graphics processing units (GPUs) ANNs, due to simpler models of neurons and simpler models of connections between neurons, have the upper hand in terms of execution speed. In general, they also win in terms of learning algorithms, as SNNs do not reach the same levels of performance as their second-generation counterparts in typical machine learning benchmark tasks, such as classification. In this paper, we review existing learning algorithms for spiking neural networks, divide them into categories by type, and assess their computational complexity.

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Toward Reflective Spiking Neural Networks Exploiting Memristive Devices

Cited by 24 publications

References 207 publications

Spatial Computing in Modular Spiking Neural Networks with a Robotic Embodiment

Spatial Computing in Modular Spiking Neural Networks with a Robotic Embodiment

Adapted MLP-Mixer network based on crossbar arrays of fast and multilevel switching (Co–Fe–B)_x(LiNbO₃)_100−x nanocomposite memristors

Overview of Spiking Neural Network Learning Approaches and Their Computational Complexities

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Toward Reflective Spiking Neural Networks Exploiting Memristive Devices

Cited by 24 publications

References 207 publications

Spatial Computing in Modular Spiking Neural Networks with a Robotic Embodiment

Spatial Computing in Modular Spiking Neural Networks with a Robotic Embodiment

Adapted MLP-Mixer network based on crossbar arrays of fast and multilevel switching (Co–Fe–B)x(LiNbO3)100−x nanocomposite memristors

Overview of Spiking Neural Network Learning Approaches and Their Computational Complexities

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Adapted MLP-Mixer network based on crossbar arrays of fast and multilevel switching (Co–Fe–B)_x(LiNbO₃)_100−x nanocomposite memristors