Stochastic Computing Implementation of Chaotic Systems

Camps, Oscar; Stavrinides, Stavros G.; Picos, R.

doi:10.20944/preprints202101.0202.v1

2021

DOI: 10.20944/preprints202101.0202.v1

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Stochastic Computing Implementation of Chaotic Systems

Oscar Camps¹,

Stavros G. Stavrinides²,

R. Picos³

Abstract: An exploding demand for processing capabilities related to the emergence of the IoT, AI and big data, has led to the quest for increasingly efficient ways to expeditiously process the rapidly increasing amount of data. These ways include different approaches like improved devices capable of going further in the more Moore path, but also new devices and architectures capable of going beyond Moore and getting more than Moore. Among the solutions being proposed, Stochastic Computing has positioned itself as a ver… Show more

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Cited by 6 publications

References 35 publications

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Empirical Characterization of ReRAM Devices Using Memory Maps and a Dynamic Route Map

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Memristors were proposed in the early 1970s by Leon Chua as a new electrical element linking charge to flux. Since that first introduction, these devices have positioned themselves to be considered as possible fundamental ones for the generations of electronic devices to come. In this paper, we propose a new way to investigate the effects of the electrical variables on the memristance of a device, and we successfully apply this technique to model the behavior of a TiN/Ti/HfO2/W ReRAM structure. To do so, we initially apply the Dynamic Route Map technique in the general case to obtain an approximation to the differential equation that determines the behaviour of the device. This is performed by choosing a variable of interest and observing the evolution of its own temporal derivative versus both its value and the applied voltage. Then, according to this technique, it is possible to obtain an approach to the governing equations with no need to make any assumption about the underlying physical mechanisms, by fitting a function to this. We have used a polynomial function, which allows accurate reproduction of the observed electrical behavior of the measured devices, by integrating the resulting differential equation system.

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Implementation of the Hindmarsh–Rose Model Using Stochastic Computing

et al. 2022

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The Hindmarsh–Rose model is one of the most used models to reproduce spiking behaviour in biological neurons. However, since it is defined as a system of three coupled differential equations, its implementation can be burdensome and impractical for a large number of elements. In this paper, we present a successful implementation of this model within a stochastic computing environment. The merits of the proposed approach are design simplicity, due to stochastic computing, and the ease of implementation. Simulation results demonstrated that the approximation achieved is equivalent to introducing a noise source into the original model, in order to reproduce the actual observed behaviour of the biological systems. A study for the level of noise introduced, according to the number of bits in the stochastic sequence, has been performed. Additionally, we demonstrate that such an approach, even though it is noisy, reproduces the behaviour of biological systems, which are intrinsically noisy. It is also demonstrated that using some 18–19 bits are enough to provide a speedup of x2 compared to biological systems, with a very small number of gates, thus paving the road for the in silico implementation of large neuron networks.

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Stochastic Computing Implementation of Chaotic Systems

Cited by 6 publications

References 35 publications

Spiking Neuron Mathematical Models: A Compact Overview

Spiking Neuron Mathematical Models: A Compact Overview

Empirical Characterization of ReRAM Devices Using Memory Maps and a Dynamic Route Map

Implementation of the Hindmarsh–Rose Model Using Stochastic Computing

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