New artificial neural network design for Chua chaotic system prediction using FPGA hardware co-simulation

Al-Musawi, Wisal Adnan; Wali, Wasan A.; Al-Ibadi, Mohammed A.

doi:10.11591/ijece.v12i2.pp1955-1964

Cited by 2 publications

(2 citation statements)

References 26 publications

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“…In addendum, a novel model for pulsed oscillations is offered. Compared with numerical emulations the Van Der Pol equation displays perfect accuracy [16]. Jin and Jie proposed a novel process to suppress a nonlinear chaotic Van Der Pol oscillator with dynamic uncertainties that is sophisticated.…”

Section: Literature Reviewmentioning

confidence: 99%

Chaotic dynamics model based on field-programmable analog array technology

Salih

2022

IJAAS

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Engineering applications in secure communications and encryption based on chaotic signals have attracted a lot of attention in the past decade. This paper presents an extensive study of the chaotic dynamics model of the Van Der Pol oscillator via MATLAB/Simulink simulation and its practical implementation using field-programmable analog matrix techniques. The obtained results show the ease of changing the frequency of the oscillator signal once it is retrieved, creating the required changes, and loading it again according to the required changes. An unlimited number of signals can be generated, allowing them to be used as a chaotic signal oscillator used in many transceiver systems, which require the generation of an unlimited number of such a signal. These research results confirmed that the AN231E04 field-programmable analog array (FPAA) device could be an interesting choice for analog circuit designers, it has the advantage of the ease of use in introducing design changes and testing many critical design solutions.

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Section: Literature Reviewmentioning

confidence: 99%

Chaotic dynamics model based on field-programmable analog array technology

Salih

2022

IJAAS

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“…Artificial Neural Networks (ANNs) have revolutionized varios fields [20] especially modeling chaotic systems through training on chaotic-generated data [21]- [23]. This capability to mimic chaotic behavior opens new encryption avenues [24], [25], allowing ANNs to replicate chaotic dynamics for secure encryption key generation and algorithm development.…”

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confidence: 99%

NeuroChaosCrypt: Revolutionizing Chaotic-Based Cryptosystem With Artificial Neural Networks—A Comparison With Traditional Cryptosystems

Bonny,

Al Nassan

2024

IEEE Access

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Encryption systems play a vital role in the transfer of sensitive data, and the integration of chaotic systems into this domain has garnered significant attention. However, these systems often grapple with complexity and insufficient security, posing challenges for real-world implementation. Researchers introduced the synchronization techniques to fix these problems, which means making sure that the chaotic systems in bothe the transmitter and receiver systems behave in a way that can be understood so that accurate signal recovery can happen. Chaotic system synchronisation presents challenges and security risks besides the limited of the encryption keys make them subjected to attacks. Because of their advantages over traditional chaotic systems in terms of flexibility, adaptability, and computational efficiency, artificial neural networks, or ANNs, are being used more and more to study chaotic systems. This paper presents NeuroChaosCrypt, a novel cryptographic framework employing unique methodologies for secure data transmission. It utilizes an Artificial Neural Network (ANN)-based chaotic system at both transmitter and receiver, eliminating the need for synchronization. A comprehensive case study, including audio signal transmission, underscores NeuroChaosCrypt's efficacy. Comparison with a traditional encryption system integrating a Linear Quadratic Regulator (LQR) controller reveals comparable security levels, correlation coefficient (cc), Signal-to-Noise Ratio (SNR), Peak-to-Root Mean Square Distortion (PRD), and encryption time. NeuroChaosCrypt, enhanced by ANNs, excels in decryption speed, key-space coverage, and hardware implementation using field-programmable gate arrays (FPGAs). This methodology achieves a higher maximum frequency while requiring fewer logic units. The comparison offers valuable insights into audio encryption methods, aiding informed decision-making for selecting the most suitable solution based on specific application requirements. Finally, we introduce an application of the proposed NeuroChaosCrypt for image encryption to ensure that thr study can exploit other data types for broader applicability.

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New artificial neural network design for Chua chaotic system prediction using FPGA hardware co-simulation

Cited by 2 publications

References 26 publications

Chaotic dynamics model based on field-programmable analog array technology

Chaotic dynamics model based on field-programmable analog array technology

NeuroChaosCrypt: Revolutionizing Chaotic-Based Cryptosystem With Artificial Neural Networks—A Comparison With Traditional Cryptosystems

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