THE SOLUTION OF DIFFERENTIAL EQUATIONS IN TERMS OF INFINITE SERIES

1957 ◽  
pp. 162-185
Keyword(s):  
Differential Equations ◽  
Infinite Series

scholarly journals A comparison of Adomian decomposition method and RK4 algorithm on Volterra integro differential equations of 2nd kind

2015 ◽  
Vol 4 (4) ◽  
pp. 481
Author(s):  
Kekana M.C ◽  
Shatalov M.Y ◽  
Moshokoa S.P
Keyword(s):  
Differential Equations ◽  
Infinite Series ◽  
Decomposition Method ◽  
Adomian Decomposition Method ◽  
Numerical Results ◽  
Adomian Decomposition

In this paper, Volterra Integro differential equations are solved using the Adomian decomposition method. The solutions are obtained in form of infinite series and compared to Runge-Kutta4 algorithm. The technique is described and illustrated with examples; numerical results are also presented graphically. The software used in this study is mathematica10.

scholarly journals A fuzzy solution of nonlinear partial differential equations

2021 ◽  
Vol 5 (1) ◽  
pp. 51-63
Author(s):  
Mawia Osman ◽  
◽  
Zengtai Gong ◽  
Altyeb Mohammed Mustafa ◽  
◽  
...  
Keyword(s):  
Partial Differential Equations ◽  
Differential Equations ◽  
Infinite Series ◽  
Nonlinear Partial Differential Equations ◽  
Differential Transform Method ◽  
Series Expansions ◽  
Partial Differential ◽  
Transform Method ◽  
Differential Transform ◽  
Fuzzy Solution

In this paper, the reduced differential transform method (RDTM) is applied to solve fuzzy nonlinear partial differential equations (PDEs). The solutions are considered as infinite series expansions which converge rapidly to the solutions. Some examples are solved to illustrate the proposed method.

XIII.—“On the Singular Solutions of Partial Differential Equations of the First Order.”

1913 ◽  
Vol 32 ◽  
pp. 150-163
Author(s):  
H. Levy
Keyword(s):  
Differential Equation ◽  
Partial Differential Equations ◽  
Differential Equations ◽  
Existence Theorem ◽  
Infinite Series ◽  
Singular Solutions ◽  
Partial Differential ◽  
First Order ◽  
Independent Variables ◽  
Original Case

The complete integral of the differential equationφ(xyzpq) = 0is a relation among the variables, which includes as many arbitrary constants as there are independent variables. But it is important to distinguish carefully between differential equations which have been formed by the elimination of constants from some complete primitive, and those whose origin is quite unknown, or which may have been constructed by some method totally different from the first.In the original case, the differential equation can always be integrated in finite terms, while in the latter, only under the conditions laid down in Cauchy's Existence Theorem can an integral be obtained, and even then usually as an infinite series.

scholarly journals ON INFINITE SERIES OF NONLOCAL CONSERVATION LAWS FOR PARTIAL DIFFERENTIAL EQUATIONS

2018 ◽  
Vol 21 (3) ◽  
pp. 150-159
Author(s):  
N. G. Khor’kova
Keyword(s):  
Partial Differential Equations ◽  
Differential Equations ◽  
Conservation Laws ◽  
Infinite Series ◽  
Conservation Law ◽  
Integrability Condition ◽  
Normal System ◽  
Partial Differential ◽  
Nonlocal Symmetries ◽  
Nonlocal Conservation Laws

Популярное в математике понятие интегрируемости дифференциальных уравнений (и столь же разнообразно трактуемое) тесно связано с существованием симметрий и законов сохранения. Все известные интегрируемые дифференциальные уравнения обладают бесконечными сериями симметрий и (или) законов сохранения. Однако также имеется целый ряд уравнений, важных для приложений, но имеющих крайне скудный запас симметрий или законов сохранения. Попытки расширить понятия симметрии и закона сохранения предпринимались разными авторами, и на эту тему имеется обширная литература. В данной статье представлен следующий результат. Если ℓ-нормальная система дифференциальных уравнений в частных производных имеет когомологически нетривиальный закон сохранения, то этот закон сохранения порождает бесконечную серию нелокальных законов сохранения. Этот факт обобщает аналогичный результат статьи автора для дифференциальных уравнений (не систем). Результат получен в рамках геометрической теории дифференциальных уравнений в частных производных. Согласно геометрическому подходу, многообразие, снабженное конечномерным распределением, удовлетворяющим условиям интегрируемости Фробениуса, называется диффеотопом (diffiety), если локально оно имеет вид бесконечно продолженного уравнения Ɛ∞. Диффеотопы являются объектами категории дифференциальных уравнений, введенной А.М. Виноградовым. Под симметриями уравнения понимают преобразования (конечные или инфинитизимальные) бесконечного продолжения уравнения, которые сохраняют распределение Картана, а под законами сохранения – (n-1)-e классы когомологий горизонтального комплекса де Рама уравнения, где n – число независимых переменных уравнения. Накрытием называется эпиморфизм  τ:Ɛ⟶ Ɛ∞ в категории дифференциальных уравнений, порождающий изоморфизм распределений. Симметрии и законы сохранения диффеотопа ࣟƐ называются нелокальными симметриями и законами сохранения уравнения ࣟƐ  Выбор подходящего накрытия позволяет получать новые (нелокальные) симметрии и законы сохранения исследуемого уравнения. В работе приведена конструкция одного накрытия и доказано существование бесконечных серий нелокальных законов сохранения у широкого класса систем дифференциальных уравнений в частных производных.системы дифференциальных уравнений в частных производных; накрытия дифференциальных уравнений; нелокальные симметрии и законы сохранения  The notion of integrability of differential equations is closely connected with the existence of symmetries and conservation laws. All known integrable differential equations have infinite series of symmetries and (or) conservation laws. However, there is also a number of equations that are important for applications, but with an extremely scarce stock of symmetries or conservation laws. Attempts to extend the concepts of symmetry and conservation law were made by different authors. This article presents the following result. If a ℓ-normal system of partial differential equations has a cohomologically nontrivial conservation law, then this conservation law generates an infinite series of non-local conservation laws. This fact generalizes the analogous result of the author for differential equations (not systems). The result is obtained within the framework of geometrical theory of partial differential equations (PDE). A manifold supplied with an infinite-dimensional distribution satisfying the Frobenius complete integrability condition is called a diffiety, if it is locally in the form of  Ɛ∞. Diffieties are objects of the category of differential equations introduced by A.M. Vinogradov. Symmetries of PDE are transformations (finite or infinitesimal) of the infinite prolongation  Ɛ∞ preserving the Cartan distribution, while conservation laws are (n-1)-cohomology classes of the horizontal de Rham cohomology. If a covering τ:Ɛ⟶ Ɛ∞ is given, then symmetries and conservation laws of the diffiety Ɛ are called nonlocal symmetries and conservation laws of the equation Ɛ .In appropriate coverings one can get new (nonlocal) symmetries and conservation laws for an equation under consideration. In this paper we investigate one covering and prove the existence of infinite series of nonlocal conservation laws.   

On the application of harmonic analysis to the dynamical theory of the tides. Part II. On the general integration of Laplace's dynamical equations

1898 ◽  
Vol 62 (379-387) ◽  
pp. 209-210 ◽  
Keyword(s):  
General Solution ◽  
Differential Equations ◽  
Infinite Series ◽  
Linear Relation ◽  
Dynamical Theory ◽  
Dynamical Equations ◽  
Harmonic Motion ◽  
Axis Of Rotation ◽  
Present Part ◽  
Tesseral Harmonics

The former part of this paper deals with solutions of Laplace’s differential equations for the tides symmetrical with respect to the axis of rotation. In the present part the restriction of symmetry is no longer imposed, and a general solution is sought, the law of depth of the ocean, however, being limited to the case which will admit of both the interior and exterior surfaces being regarded as spheroids of revolution. It is found that, subject to this limitation, if the solution sought represent a simple harmonic motion of any period whatsoever, and the height of the surface-waves be expressible as an infinite series of tesseral harmonics of the same rank but different orders, a linear relation connecting three successive coefficients of the series can be deduced similar to that obtained in Part I.

scholarly journals Convergence of the Generalized Homotopy Perturbation Method for Solving Fractional Order Integro-Differential Equations

2014 ◽  
Vol 11 (4) ◽  
pp. 1637-1648
Author(s):  
Baghdad Science Journal
Keyword(s):  
Theoretical Analysis ◽  
Differential Equations ◽  
Perturbation Method ◽  
Fractional Order ◽  
Infinite Series ◽  
Homotopy Perturbation Method ◽  
Approximate Solutions ◽  
Powerful Method ◽  
Homotopy Perturbation ◽  
Fractional Order Integral

In this paper,the homtopy perturbation method (HPM) was applied to obtain the approximate solutions of the fractional order integro-differential equations . The fractional order derivatives and fractional order integral are described in the Caputo and Riemann-Liouville sense respectively. We can easily obtain the solution from convergent the infinite series of HPM . A theorem for convergence and error estimates of the HPM for solving fractional order integro-differential equations was given. Moreover, numerical results show that our theoretical analysis are accurate and the HPM can be considered as a powerful method for solving fractional order integro-diffrential equations.

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