Keywords
Nvidia Jetson
AGX Orin
Digital analog converter
Oscilloscope
How to Cite
Abstract
Digital implementation of chaotic systems has many advantages. Chaotic systems realized on digital platforms offer higher flexibility and computational accuracy compared to traditional analog systems. This flexibility and accuracy are of great importance for engineering applications. Furthermore, digital solutions are usually more cost-effective, which is a great economic advantage. In this study, Nvidia Jetson AGX Orin board and 16-bit converter board are used for digital realization of chaotic systems. The Nvidia Jetson AGX Orin is a platform that stands out with its high processing power and energy efficiency. The 16-bit converter card stands out with its sensitive data processing capacity. Thanks to this technological infrastructure, chaotic system equations can be successfully solved in a digital environment and more advanced, flexible, reliable and cost-effective solutions are obtained. These solutions provide significant advantages in various applications in engineering. In particular, the use of digital chaotic systems in areas such as modeling, simulation and control of complex systems offers more efficient and effective results than traditional methods. Digital platforms also facilitate parametric investigations and optimization processes of chaotic systems, enabling more in-depth analysis.
References
Charalampidis, N., A. Iatropoulos, and C. Volos, 2024 Chaos based speech encryption using microcontroller. Integration 95: 102128.
Chiu, R., D. López-Mancilla, C. E. Castañeda, O. Orozco-López, E. Villafaña-Rauda, et al., 2019 Design and implementation of a jerk circuit using a hybrid analog–digital system. Chaos, Solitons Fractals 119: 255–262.
Dong, C. and M. Yang, 2024 A novel 4D memristor-based hyperchaotic system with hidden attractors: Dynamics, periodic orbits analysis, and DSP realization. Chinese Journal of Physics 89: 930–942.
Emin, B. and Z. Musayev, 2023 Chaos-based Image Encryption in Embedded Systems using Lorenz-Rossler System. Chaos Theory and Applications 5: 153–159.
Fan, C. and Q. Ding, 2023 Design and geometric control of polynomial chaotic maps with any desired positive Lyapunov exponents. Chaos, Solitons Fractals 169: 113258.
Janakiraman, S., K. Thenmozhi, J. B. B. Rayappan, and R. Amirtharajan, 2018 Lightweight chaotic image encryption algorithm for real-time embedded system: Implementation and analysis on 32-bit microcontroller. Microprocessors and Microsystems 56: 1–12.
Khaled, B., R. Moghrabi, A. Sambas, S. Kacar, S. Uzun, et al., 2024 A novel four-wing chaotic system with multiple equilibriums: Dynamical analysis, multistability, circuit simulation and pseudo random number generator (PRNG) based on the voice encryption. International Journal of Data and Network Science 8: 989–1000.
Köse, E. and A. Mühürcü, 2017 Realization of a digital chaotic oscillator by using a low cost microcontroller. Engineering Review 37: 341–348.
Méndez-Ramírez, R. D., A. Arellano-Delgado, M. A. Murillo-Escobar, and C. Cruz-Hernández, 2021 A new 4d hyperchaotic system and its analog and digital implementation. Electronics (Switzerland) 10: 1–18.
Murillo-Escobar, D., C. Cruz-Hernández, R. M. López-Gutiérrez, and M. A. Murillo-Escobar, 2023 Chaotic encryption of real-time ECG signal in embedded system for secure telemedicine. Integration 89: 261–270.
Murillo-Escobar, D., K. Vega-Pérez, M. A. Murillo-Escobar, A. Arellano-Delgado, and R. M. López-Gutiérrez, 2024 Comparison of two new chaos-based pseudorandom number generators implemented in microcontroller. Integration 96: 102130.
Pande, A. and J. Zambreno, 2013 A chaotic encryption scheme for real-time embedded systems: Design and implementation. Telecommunication Systems 52: 551–561.
Wang, J., L. Xiao, K. Rajagopal, A. Akgul, S. Cicek, et al., 2021 Fractional-Order Analysis of Modified Chua’s Circuit System with the Smooth Degree of 3 and Its Microcontroller-Based Implementation with Analog Circuit Design.
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.