Metin Varan scite author profile

Summary It is well observed that cryptographic applications have great challenges in guaranteeing high security as well as high throughput. Artificial neural network (ANN)–based chaotic true random number generator (TRNG) structure has not been unprecedented in current literature. This paper provides a novel type of high‐speed TRNG based on chaos and ANN implemented in a Xilinx field‐programmable gate array (FPGA) chip. The paper consists of two main parts. In the first part, chaos analyses of Pehlivan‐Uyaroglu_2010 chaotic system (PUCS) have been accomplished to prove that PUCS operates in chaotic regime. So PUCS can be an efficient alternative to the entropy source for classical TRNGs. In the second part, the hardware design of the proposed TRNG has been created using VHDL in Xilinx platform. As a result, the implemented TRNG offers throughput up to 115.794 Mbps. Besides, the generated random numbers have been tested with the FIPS 140‐1 and NIST 800.22 test suites. The high quality of generated true random numbers have been confirmed by passing all randomness tests. The results have shown that the proposed system can provide not only high throughput but also high quality random bit sequences for a wide variety of embedded cryptographic applications.

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A hyperchaotic memristor oscillator with fuzzy based chaos control and LQR based chaos synchronization

Rajagopal

Jahanshahi

Varan

et al. 2018

AEU - International Journal of Electronics and Communications

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Control and synchronisation of a novel seven-dimensional hyperchaotic system with active control

Varan

Akgül

2018

Pramana - J Phys

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Dynamic analysis and synchronization control of an unusual chaotic system with exponential term and coexisting attractors

Lai

Akgül

Varan

et al. 2018

Chinese Journal of Physics

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Synchronisation and Circuit Realisation of Chaotic Hartley System

Varan

Akgül

Güleryüz

et al. 2018

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Hartley chaotic system is topologically the simplest, but its dynamical behaviours are very rich and its synchronisation has not been seen in literature. This paper aims to introduce a simple chaotic system which can be used as alternative to classical chaotic systems in synchronisation fields. Time series, phase portraits, and bifurcation diagrams reveal the dynamics of the mentioned system. Chaotic Hartley model is also supported with electronic circuit model simulations. Its exponential dynamics are hard to realise on circuit model; this paper is the first in literature that handles such a complex modelling problem. Modelling, synchronisation, and circuit realisation of the Hartley system are implemented respectively in MATLAB-Simulink and ORCAD environments. The effectiveness of the applied synchronisation method is revealed via numerical methods, and the results are discussed. Retrieved results show that this complex chaotic system can be used in secure communication fields.

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Metin Varan

A novel high speed Artificial Neural Network–based chaotic True Random Number Generator on Field Programmable Gate Array

A hyperchaotic memristor oscillator with fuzzy based chaos control and LQR based chaos synchronization

Control and synchronisation of a novel seven-dimensional hyperchaotic system with active control

Dynamic analysis and synchronization control of an unusual chaotic system with exponential term and coexisting attractors

Synchronisation and Circuit Realisation of Chaotic Hartley System

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