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Advanced fractional calculus, differential equations and neural networks: analysis, modeling and numerical computations

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dc.contributor.author Baleanu, Dumitru
dc.contributor.author Karaca, Yeliz
dc.contributor.author Vázquez, Luis
dc.contributor.author Macías-Díaz, Jorge E.
dc.date.accessioned 2024-05-27T11:55:13Z
dc.date.available 2024-05-27T11:55:13Z
dc.date.issued 2023-11-01
dc.identifier.citation Baleanu, Dumitru...et al. (2023). "Advanced fractional calculus, differential equations and neural networks: analysis, modeling and numerical computations", Physica Scripta, Vol. 98, No. 11. tr_TR
dc.identifier.issn 0031-8949
dc.identifier.uri http://hdl.handle.net/20.500.12416/8409
dc.description.abstract Most physical systems in nature display inherently nonlinear and dynamical properties; hence, it would be difficult for nonlinear equations to be solved merely by analytical methods, which has given rise to the emerging of engrossing phenomena such as bifurcation and chaos. Conjointly, due to nonlinear systems’ exhibiting more exotic behavior than harmonic distortion, it becomes compelling to test, classify and interpret the results in an accurate way. For this reason, avoiding preconceived ideas of the way the system is likely to respond is of pivotal importance since this facet would have effect on the type of testing run and processing techniques used in nonlinear systems. Paradigms of nonlinear science may suggest that it is ‘the study of every single phenomenon’ due to its interdisciplinary nature, which is another challenge encountered and needs to be addressed by generating and designing a systematic mathematical framework where the complexity of natural phenomena hints the requirement of identifying their commonalties and classifying their various manifestations in different nonlinear systems. Studying such common properties, concepts or paradigms can enable one to gain insight into nonlinear problems, their essence and consequences in a broad range of disciplines all forthwith. Fractional differential equations associated with non-local phenomena in physics have arisen as a powerful mathematical tool within a multidisciplinary research framework. Fractional differential equations, as one extension of the fractional calculus theory, can yield the evolution of various systems properly, which reinforces its position in mathematics and science while setting stage for the description of dynamic, complicated and nonlinear events. Through the reflection of the systems’ actual properties, fractional calculus manifests unforeseeable and hidden variations, and thus, enables integration and differentiation, with the solutions to be approximated by numerical methods along with modeling and predicting the dynamics of multiphysics, multiscale and physical systems. Neural Networks (NNs), consisting of hidden layers with nonlinear functions that have vector inputs and outputs, are also considerably employed owing to their versatile and efficient characteristics in classification problems as well as their sophisticated neural network architectures, which make them capable of tackling complicated governing partial differential equation problems. Furthermore, partial differential equations are used to provide comprehensive and accurate models for many scientific phenomena owing to the advancements of data gathering and machine learning techniques which have raised opportunities for data-driven identification of governing equations derived from experimentally observed data. Given these considerations, while many problems are solvable and have been solved, efforts are still needed to be able to respond to the remaining open questions in the fields that have a broad range of spectrum ranging from mathematics, physics, biology, virology, epidemiology, chemistry, engineering, social sciences to applied sciences. With a view of different aspects of such questions, our special issue provides a collection of recent research focusing on the advances in the foundational theory, methodology and topical applications of fractals, fractional calculus, fractional differential equations, differential equations (PDEs, ODEs, to name some), delay differential equations (DDEs), chaos, bifurcation, stability, sensitivity, machine learning, quantum machine learning, and so forth in order to expound on advanced fractional calculus, differential equations and neural networks with detailed analyses, models, simulations, data-driven approaches as well as numerical computations. tr_TR
dc.language.iso eng tr_TR
dc.relation.isversionof 10.1088/1402-4896/acfe73 tr_TR
dc.rights info:eu-repo/semantics/closedAccess tr_TR
dc.subject Bifurcation tr_TR
dc.subject Differential/Integral Equations tr_TR
dc.subject Fractal-Fractional Differential Equations tr_TR
dc.subject Fractional Calculus tr_TR
dc.subject Neural Networks tr_TR
dc.subject Nonlinear Systems tr_TR
dc.subject Quantum Computing tr_TR
dc.title Advanced fractional calculus, differential equations and neural networks: analysis, modeling and numerical computations tr_TR
dc.type article tr_TR
dc.relation.journal Physica Scripta tr_TR
dc.contributor.authorID 56389 tr_TR
dc.identifier.volume 98 tr_TR
dc.identifier.issue 11 tr_TR
dc.contributor.department Çankaya Üniversitesi, Fen - Edebiyat Fakültesi, Matematik Bölümü tr_TR


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