Fractional Chaotic System Solutions and Their Impact on Chaotic Behaviour

Yang, Chunxiao; Taralova, Ina; Loiseau, Jean Jacques

doi:10.1007/978-3-030-96964-6_36

Cited by 3 publications

(2 citation statements)

References 21 publications

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“…These kinds of fractional (DEs) succeed in describing hereditary and memorial properties of a variety of processes and materials, unlike the conventional integer-order DEs, which fails to capture relevant phenomena and do not accurately predict the PV performance. The field of fractional calculus plays a crucial role in many numbers of applications in signal and image processing, probability theory, biology, chemistry, communication, and control engineering, especially in heat transfer modeling (Abro et al 2019;Yang et al 2022;Abdalla, Abbas, and Sapoor 2022;Sweilam et al 2021;Shah and Irfan 2020;Shukla and Sapra 2019;Saqib, Khan, and Shafie 2019;Sun et al 2019;Evans, Katugampola, and Edwards 2017). For instance, Kashif et al (Abro et al 2019) suggested a fractional model improve the process of heat transfer for some devices related to solar energy and show the influence of adding multi-wall carbon nanotubes (MWCNTs) on the rate of heat transfer.…”

Section: Introductionmentioning

confidence: 99%

A new fractional Cattaneo model for enhancing the thermal performance of Photovoltaic panels using heat spreader: Energy, exergy, economic and enviroeconomic (4E) analysis

El-Gazar

Hassan

Rabia

et al. 2023

Preprint

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A new fractional non-Fourier (Cattaneo) photovoltaic (PV) model is developed to improve the thermal performance of a PV system combined with a heat spreader (HS). In contrast to the traditional Fourier model, which is unable to reliably predict system performance, the fractional Cattaneo model proves its efficiency in looking at transient processes throughout the entire PV system. It can also accurately expect PV performance even at short temporal scales. Consequently, a comparison is conducted between the classical Fourier model with the fractional Fourier and fractional Cattaneo models for the PV system. Real experimental data are used to validate the fractional Cattaneo model. The findings show that it perfectly matches the measured data, with an error percentage in PV power and exergy efficiency of only 0.628% and 3.84%, respectively, compared to 5.72% and 13.13% resulted from the classical model. An assessment of the effect of using rectangular and trapezoidal spreaders on output power, electrical efficiency, exergy efficiency, economic, exergoeconomic, and enviroeconomic parameters is introduced and discussed. The outcomes revealed that the electrical production costs of the rectangular and trapezoidal HS systems are 0.272 and 0.214 $/kWh, respectively, while about 0.286 $/kWh for the conventional PV panel. Finally, the findings show that the modified PV systems with the spreader are liked to be greener than the conventional ones.

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Section: Introductionmentioning

confidence: 99%

A new fractional Cattaneo model for enhancing the thermal performance of Photovoltaic panels using heat spreader: Energy, exergy, economic and enviroeconomic (4E) analysis

El-Gazar

Hassan

Rabia

et al. 2023

Preprint

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show abstract

“…The obstacles that hinder the broader implementation of fractional systems, especially for the use of fractional chaotic systems for cryptosystem security enhancement, arise from the intrinsic complexity of fractional calculus and the aspects of its digital implementation. In addition, our recent research works [10] [11] have revealed that applying different numerical calculation methods and adopting different fractional calculus characterizations may strongly impact the (short or long term) chaotic behavior of the resulting system. This renders the design of efficient FCPRNG a very challenging problem.…”

Section: Introductionmentioning

confidence: 99%

Image encryption based on fractional chaotic pseudo-random number generator and DNA encryption method

et al. 2022

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Nonlinear dynamic systems and chaotic systems have been quite exhaustively researched in the domain of cryptography. However, the possibility of using the fractional chaotic system in the cryptosystem design has been much less explored while it bears advantages such as enlarged keyspace, compared to classical nonlinear systems.This paper, therefore, proposes a novel structure for the pseudo-random number generator based on fractional chaotic systems which consists of 3 different fractional chaotic systems, namely fractional Chen's system, Lu's system, and fractional generalized double-humped logistic map(FGDHL). Then, the outputs of this fractional chaotic pseudo-random number generator(FCPRNG) are used as a keystream for an image encryption scheme. The confusion layer of the scheme is conducted by a dynamic DNA encoding and decoding method combined with a 2D cat map for the permutation in the DNA-bases level. The diffusion layer is performed through the adoption of a 32 bits discrete logistic map. The performance and security analysis have been conducted for the above-designed cryptosystem, proving that the proposed cryptosystem is practical and secure in image encryption.

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A new fractional Cattaneo model for enhancing the thermal performance of photovoltaic panels using heat spreader: energy, exergy, economic and enviroeconomic (4E) analysis

El-Gazar,

Hassan,

Rabia

et al. 2023

Environ Sci Pollut Res

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A new fractional non-Fourier (Cattaneo) photovoltaic (PV) model is presented to enhance the thermal performance of a PV system combined with a heat spreader (HS). The fractional Cattaneo model is shown to be effective in examining transient processes across the entirety of a PV system, in contrast to the conventional Fourier model’s inability to predict system performance. Consequently, a comparison is conducted between the classical Fourier model with the fractional Fourier and fractional Cattaneo models for the PV system. The impact of using an aluminum heat spreader, with rectangular and trapezoidal shapes, has been developed under hot and cold climate conditions. The findings show that adding a trapezoidal heat spreader reduced the cell temperature by 20 K in summer and 12 K in winter. The reduction in the PV temperature led to an enhancement in daily average power by approximately 28% and 37% in hot and cold weather, respectively. Moreover, economic, exergoeconomic, and enviroeconomic assessment is introduced. The outcomes revealed that the electrical production costs of the rectangular and trapezoidal HS systems are 0.272 and 0.214 $/kWh, respectively, while about 0.286 $/kWh for the conventional PV panel. Based on the environmental study, the estimated CO2 reduction for PV, PV with rectangular HS, and PV with trapezoidal spreader is 0.5504, 0.7704, and 0.8012 tons, respectively. Finally, real experimental data are used to validate the fractional Cattaneo model. The results demonstrate that there is a great fitting with the measured data, with errors in PV power and exergy efficiency of just 0.628% and 3.84%, respectively, whereas their corresponding values for the classical model are 5.72 and 13.13%.

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Fractional Chaotic System Solutions and Their Impact on Chaotic Behaviour

Cited by 3 publications

References 21 publications

A new fractional Cattaneo model for enhancing the thermal performance of Photovoltaic panels using heat spreader: Energy, exergy, economic and enviroeconomic (4E) analysis

A new fractional Cattaneo model for enhancing the thermal performance of Photovoltaic panels using heat spreader: Energy, exergy, economic and enviroeconomic (4E) analysis

Image encryption based on fractional chaotic pseudo-random number generator and DNA encryption method

A new fractional Cattaneo model for enhancing the thermal performance of photovoltaic panels using heat spreader: energy, exergy, economic and enviroeconomic (4E) analysis

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