Kneser's theorem (differential equations) explained

In mathematics, the Kneser theorem can refer to two distinct theorems in the field of ordinary differential equations:

the first one, named after Adolf Kneser, provides criteria to decide whether a differential equation is oscillating or not;
the other one, named after Hellmuth Kneser, is about the topology of the set of all solutions of an initial value problem with continuous right hand side.

Statement of the theorem due to A. Kneser

Consider an ordinary linear homogeneous differential equation of the form

y''+q(x)y=0

with

q:[0,+infty)\toR

continuous.We say this equation is oscillating if it has a solution y with infinitely many zeros, and non-oscillating otherwise.

The theorem states^[1] that the equation is non-oscillating if

\limsup_xx²q(x)<\tfrac{1}{4}

and oscillating if

\liminf_xx²q(x)>\tfrac{1}{4}.

Example

To illustrate the theorem consider

q(x)=\left(

	1
	4

-a\right)x^-2 for x>0

where

is real and non-zero. According to the theorem, solutions will be oscillating or not depending on whether

is positive (non-oscillating) or negative (oscillating) because

\limsup_xx²q(x)=\liminf_xx²q(x)=

	1
	4

-a

To find the solutions for this choice of

q(x)

, and verify the theorem for this example, substitute the 'Ansatz'

y(x)=xⁿ

which gives

n(n-1)+

	1
	4

-a=\left(n-

	1
	2

\right)²-a=0

This means that (for non-zero

) the general solution is

y(x)=A

	1	+\sqrt{a
	2

} + B x^

where

and

are arbitrary constants.

It is not hard to see that for positive

the solutions do not oscillate while for negative

a=-\omega²

the identity

	1	\pmi\omega
	2

=\sqrt{x} e^\pm

} = \sqrt\ (\cos \pm i \sin) shows that they do.

The general result follows from this example by the Sturm–Picone comparison theorem.

Extensions

There are many extensions to this result, such as the Gesztesy–Ünal criterion.^[2]

Statement of the theorem due to H. Kneser

While Peano's existence theorem guarantees the existence of solutions of certain initial values problems with continuous right hand side, H. Kneser's theorem deals with the topology of the set of those solutions. Precisely, H. Kneser's theorem states the following:^[3]

Let

f\colon\R x \Rⁿ → \Rⁿ

be a continuous function on the region

l{R}:=[t_0,t_0+a] x \{x\inR^n:\Vertx-x_0\Vert\leb\}

, and such that

|f(t,x)|\leM

for all

(t,x)\inl{R}

Given a real number

satisfying

t_0<c\let_0+min(a,b/M)

, define the set

S_c

as the set of points

x_c

for which there is a solution

x=x(t)

•

=f(t,x)

such that

x(t_0)=x₀

and

x(c)=x_c

. Then

S_c

is a closed and connected set.

Notes and References

Book: Teschl. Gerald Teschl
. Gerald. Gerald Teschl. Ordinary Differential Equations and Dynamical Systems. American Mathematical Society. Providence. 2012. 978-0-8218-8328-0.
Krüger . Helge . Teschl . Gerald . 2008 . Effective Prüfer angles and relative oscillation criteria . Journal of Differential Equations . en . 245 . 12 . 3823–3848 . 10.1016/j.jde.2008.06.004. 0709.0127 . 2008JDE...245.3823K . 6693175 .
Book: Hartman, Philip . Ordinary Differential Equations . 2002 . Society for Industrial and Applied Mathematics . 978-0-89871-510-1 . Second . en . 10.1137/1.9780898719222.ch2.