对称内高级分形-分数阶微分算子的复杂数学建模

IF 3.3 3区数学 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Fractals-Complex Geometry Patterns and Scaling in Nature and Society Pub Date : 2023-10-20 DOI:10.1142/s0218348x23401941

Rabha W. Ibrahim, Suzan J. Obaiys, Yeliz Karaca, Aydin Secer

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引用次数: 0

摘要

非局部微分算子被赋予了将复杂的自然方程包含到数学方程中的能力。对称作为一组特定变换下的不变性，不仅可以广泛应用于空间图形，还可以广泛应用于抽象对象，如数学表达式，可以说是物理相关性的表达式，特别是动力学方程。从这个观点出发，可以看出，越复杂的物理问题，就需要越复杂的数学微分算子。因此，我们的研究将分形-分数算子扩展到复平面上，并围绕开单位圆盘上的一类唯一的归一化解析函数展开。为了将微分和积分算子纳入归一化的范畴，本研究旨在对微分和积分算子进行几何上的扩展和修正。凹凸性和星形性的特性在本研究中有牵连，其中微分从属技术作为正在考虑的调查的基础。此外，考虑了一组微分FFO不等式，证明了归一化Fox-Wright函数可以包含所有FFO。除了这些步骤之外，还应用了Grunsky因子的概念来研究对称性，同时探讨了涉及ffo的边值问题。因此，相关的性质和应用可以进一步发展，这需要致力于与可行应用相关的微分分数问题和各种复杂问题，指出修改和升级现有方法的空间，以便在具有挑战性的现实问题中获得更优的结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Complex Mathematical Modeling for Advanced Fractal-Fractional Differential Operators within Symmetry

Non-local operators of differentiation are bestowed with capabilities of encompassing complex natural into mathematical equations. Symmetry as invariance under a specified group of transformations can allow for the concept to be applied extensively not only to spatial figures but also to abstract objects like mathematical expressions which can be said to be expressions of physical relevance, in particular dynamical equations. Derived from this point of view, it can be noted that the more complex physical problems are, the more complex mathematical operators of differentiation are required. Accordingly, the fractal–fractional operators (FFOs) are expanded into the complex plane in our research which revolves around a unique class of normalized analytic functions in the open unit disk. To bring FFOs (differential and integral) into the normalized class, the study aims to expand and modify them along with the investigation of the FFOs geometrically. The qualities of convexity and starlikeness are implicated in this study where the differential subordination technique serves as the foundation for the inquiry under consideration. Furthermore, a collection of differential FFO inequalities is taken into account, demonstrating that the normalized Fox–Wright function can contain all FFOs. Besides these steps, the concept of Grunsky factors is applied to investigate symmetry, while boundary value issues involving FFOs are probed. Consequently, the related properties and applications can be further developed, which requires the devotion to differential fractional problems and diverse complex problems in relation to viable applications, pointing out the room to modify and upgrade the existing methods for more optimal outcomes in challenging real-world problems.

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来源期刊

Fractals-Complex Geometry Patterns and Scaling in Nature and Society 数学-数学跨学科应用

CiteScore

7.40

自引率

23.40%

发文量

319

审稿时长

>12 weeks

期刊介绍： The investigation of phenomena involving complex geometry, patterns and scaling has gone through a spectacular development and applications in the past decades. For this relatively short time, geometrical and/or temporal scaling have been shown to represent the common aspects of many processes occurring in an unusually diverse range of fields including physics, mathematics, biology, chemistry, economics, engineering and technology, and human behavior. As a rule, the complex nature of a phenomenon is manifested in the underlying intricate geometry which in most of the cases can be described in terms of objects with non-integer (fractal) dimension. In other cases, the distribution of events in time or various other quantities show specific scaling behavior, thus providing a better understanding of the relevant factors determining the given processes. Using fractal geometry and scaling as a language in the related theoretical, numerical and experimental investigations, it has been possible to get a deeper insight into previously intractable problems. Among many others, a better understanding of growth phenomena, turbulence, iterative functions, colloidal aggregation, biological pattern formation, stock markets and inhomogeneous materials has emerged through the application of such concepts as scale invariance, self-affinity and multifractality. The main challenge of the journal devoted exclusively to the above kinds of phenomena lies in its interdisciplinary nature; it is our commitment to bring together the most recent developments in these fields so that a fruitful interaction of various approaches and scientific views on complex spatial and temporal behaviors in both nature and society could take place.