-pseudo orbit is obtained by
successively following the system, each time making an "error" of size
less than
. ![[More]](pix/Link.gif){kind=small}
The notion of a "pseudo-orbit" has had important applications in several different areas of dynamical systems. Most important has been the concept of "shadowing", which has been used to prove the existence of orbits corresponding to symbol shifts. Hammel, Yorke and Grebogi [7,8] have exploited extensively the fact that a pseudo-orbit is the actual object computed by a computer. They are able to show rigorously that certain orbits found by simulation correspond to real orbits for the original system.
Roughly speaking, an
-pseudo orbit is obtained by
successively following the system, each time making an "error" of size
less than
.
It turns out that attractor blocks can be constructed from
-pseudo-orbits. If one considers the set of all points which
can be reached from an attractor
by an
-pseudo-orbit,
then, for sufficiently small
, that
set is an attractor block corresponding to
. This statement will be
made precise and proved in this section.
The following notation will be used to denote the set of all
-pseudo-orbits of length
starting in the set
.
It will be convenient to have a notation for the
th coordinate of a
pseudo-orbit. For
and
for
, define
It is clear that
-pseudo-orbits are closely related to the
map
. Indeed,
an
-pseudo-orbit is simply a sequence of points picked out
of successive iterates of
. More precisely,
is an
-pseudo-orbit if and only if
Observe that the notation
is used. The following lemma
states that points in the
th iterate of
under
are precisely those points in the
th
coordinate of some
-pseudo-orbit staring in
.
Lemma 4.1 Fix
. For every
,
The set of all points on all
-pseudo-orbits of length
starting on the set
will be denoted
Note that
The following lemma states that the set of all points on
-pseudo-orbits starting on a set
is identical to the union of
iterates of
under the map
.
Lemma 4.2:
.
The set of all points on all
-pseudo-orbits of arbitrary
length will be important in what is to follow. This set will be denoted
Some elementary properties of this set are collected in the following lemma.
Lemma 4.3: The following properties hold whenever they are defined.
Note that this last property implies that the set
of
all points accessible by
-pseudo-orbits starting on
maps
into itself by a distance at least
. In view of
Corollary 3.12,
would be an attractor block if it were compact.
Corollary 4.4 If
is nonempty and if
is compact, then
is an attractor block.
This property is exploited in the next lemma.
Lemma 4.5 Let
be an attractor, let
, and define
. If
is compact and if
, then
is an
attractor block associated
with
.
It remains to show that
is close to
for small
.
Theorem 4.6 If
is an attractor,
then
, as
.
An immediate consequence of this theorem is the following corollary.
Corollary 4.7 If
is a neighborhood of
an attractor
, then there exists an
such that
is compact and is a subset of
.
![[Left]](pix/Left.gif){kind=small}
Attractor blocks
![[Right]](pix/Right.gif){kind=small}
Intensity
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Main entry point
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Copyright (c) 1998 by Richard
McGehee, all rights reserved.