{"title":"Existence and linear independence theorem for linear fractional differential equations with constant coefficients","authors":"P. Dubovski, J. Slepoi","doi":"10.1515/jaa-2023-0009","DOIUrl":null,"url":null,"abstract":"Abstract We consider the l-th order linear fractional differential equations with constant coefficients. Here l ∈ ℕ {l\\in\\mathbb{N}} is the ceiling for the highest derivative of order α, l - 1 < α ≤ l {l-1<\\alpha\\leq l} . If β i < α {\\beta_{i}<\\alpha} are the other derivatives, the existing theory requires α - max { β i } ≥ l - 1 {\\alpha-\\max\\{\\beta_{i}\\}\\geq l-1} for the existence of l linearly independent solutions. Thus, at most one derivative may have order greater than one, but all other derivatives must be between zero and one. We remove this essential restriction and construct l linearly independent solutions. With this aim, we remodel the series approaches and elaborate the multi-sum fractional series method in order to obtain the existence and linear independence results. We consider both Riemann–Liouville or Caputo fractional derivatives.","PeriodicalId":44246,"journal":{"name":"Journal of Applied Analysis","volume":"3 9","pages":""},"PeriodicalIF":0.6000,"publicationDate":"2024-01-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Applied Analysis","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1515/jaa-2023-0009","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"MATHEMATICS, APPLIED","Score":null,"Total":0}
引用次数: 0
Abstract
Abstract We consider the l-th order linear fractional differential equations with constant coefficients. Here l ∈ ℕ {l\in\mathbb{N}} is the ceiling for the highest derivative of order α, l - 1 < α ≤ l {l-1<\alpha\leq l} . If β i < α {\beta_{i}<\alpha} are the other derivatives, the existing theory requires α - max { β i } ≥ l - 1 {\alpha-\max\{\beta_{i}\}\geq l-1} for the existence of l linearly independent solutions. Thus, at most one derivative may have order greater than one, but all other derivatives must be between zero and one. We remove this essential restriction and construct l linearly independent solutions. With this aim, we remodel the series approaches and elaborate the multi-sum fractional series method in order to obtain the existence and linear independence results. We consider both Riemann–Liouville or Caputo fractional derivatives.
Abstract We consider the l-th order linear fractional differential equations with constant coefficients.这里 l∈ ℕ {l\in\mathbb{N}} 是最高导数 α 阶的上限,l - 1 < α ≤ l {l-1<\alpha\leq l} 。如果 β i < α {\beta_{i}<\alpha} 是其他导数,现有理论要求 α - max { β i } ≥ l - 1 {\alpha-\max\{beta_{i}\}geq l-1} 为线性独立解的存在。因此,最多有一个导数的阶数可能大于 1,但所有其他导数必须介于 0 和 1 之间。我们取消了这一基本限制,构建了 l 个线性独立解。为此,我们重塑了数列方法,并详细阐述了多和分数数列方法,以获得存在性和线性独立结果。我们同时考虑黎曼-刘维尔或卡普托分数导数。
期刊介绍:
Journal of Applied Analysis is an international journal devoted to applications of mathematical analysis. Among them there are applications to economics (in particular finance and insurance), mathematical physics, mechanics and computer sciences. The journal also welcomes works showing connections between mathematical analysis and other domains of mathematics such as geometry, topology, logic and set theory. The journal is jointly produced by the Institute of Mathematics of the Technical University of Łódź and De Gruyter. Topics include: -applications of mathematical analysis (real and complex, harmonic, convex, variational)- differential equations- dynamical systems- optimization (linear, nonlinear, convex, nonsmooth, multicriterial)- optimal control- stochastic modeling and probability theory- numerical methods
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