Jump to content

Chaplygin's theorem

From Wikipedia, the free encyclopedia
(Redirected from Chaplygin's Theorem)

In mathematical theory of differential equations the Chaplygin's theorem (Chaplygin's method) states about existence and uniqueness of the solution to an initial value problem for the first order explicit ordinary differential equation. This theorem was stated by Sergey Chaplygin.[1] It is one of many comparison theorems.

Important definitions

[edit]

Consider an initial value problem: differential equation

in ,

with an initial condition

.

For the initial value problem described above the upper boundary solution and the lower boundary solution are the functions and respectively, both of which are smooth in and continuous in , such as the following inequalities are true:

  1. ;
  2. and for .

Statement

[edit]

Source:[2][3]

Given the aforementioned initial value problem and respective upper boundary solution and lower boundary solution for . If the right part

  1. is continuous in , ;
  2. satisfies the Lipschitz condition over variable between functions and : there exists constant such as for every , , the inequality

holds,

then in there exists one and only one solution for the given initial value problem and moreover for all

.

Remarks

[edit]

Source:[2]

Weakning inequalities

[edit]

Inside inequalities within both of definitions of the upper boundary solution and the lower boundary solution signs of inequalities (all at once) can be altered to unstrict. As a result, inequalities sings at Chaplygin's theorem concusion would change to unstrict by and respectively. In particular, any of , could be chosen.

Proving inequality only

[edit]

If is already known to be an existent solution for the initial value problem in , the Lipschitz condition requirement can be omitted entirely for proving the resulting inequality. There exists applications for this method while researching whether the solution is stable or not ([2] pp. 7–9). This is often called "Differential inequality method" in literature[4][5] and, for example, Grönwall's inequality can be proven using this technique.[5]

Continuation of the solution towards positive infinity

[edit]

Chaplygin's theorem answers the question about existence and uniqueness of the solution in and the constant from the Lipschitz condition is, generally speaking, dependent on : . If for both functions and retain their smoothness and for a set is bounded, the theorem holds for all .

References

[edit]
  1. ^ Bogolubov, Alexey (1983). Математики. Механики. Биографический справочник [Mathematicians. Mechanics. Biographical handbook.] (in Russian) (1st ed.). Kiev, Ukraine: Киев: Наукова думка. pp. 515–516. ISBN 978-5-906923-56-1.
  2. ^ a b c Vasilyeva, Adelaida (2007). "Теоремы сравнения. Метод дифференциальных неравенств Чаплыгина" [Comparison theorems. Chaplygin's differential inequalities method.] (PDF). Кафедра математики физического факультета МГУ (in Russian). pp. 4–5. Retrieved 2024-08-28.
  3. ^ Nefedov, Nikolay (2019-06-09). "Дифференциальные уравнения -- Лекции" [Differential equations -- Lections] (PDF). Teach-In (in Russian). Retrieved 2024-08-28.
  4. ^ Nefedov, Nikolay (2016). "Обыкновенные дифференциальные уравнения. Курс лекций" [Ordinary differential equations. Lection series.] (PDF). Кафедра математики физического факультета МГУ (in Russian). p. 60. Retrieved 2024-08-30.
  5. ^ a b Hale, Jack (1980). Ordinary differential equations. Pure and applied Mathematics (2nd ed.). Malabar, Fla: Krieger. pp. 30–37. ISBN 978-0-89874-011-0.

Further reading

[edit]