Complex Behavior of Simple Systems
Julien Clinton Sprott
Department of Physics, University of Wisconsin, Madison, Wisconsin
53706, USA
(Submission Date: March 29, 2000)
ABSTRACT
Since the seminal work of Lorenz and Rössler, it has been known that
complex behavior (chaos) can occur in systems of autonomous ordinary differential
equations (ODEs) with as few as three variables and one or two quadratic
nonlinearities. Many other simple chaotic systems have been discovered
and studied over the years, but it is not known whether the algebraically
simplest chaotic flow has been identified. For continuous flows, the Poincaré-Bendixson
theorem implies the necessity of three variables, and chaos requires at
least one nonlinearity. With the growing availability of powerful computers,
many other examples of chaos have been subsequently discovered in algebraically
simple ODEs. Yet the sufficient conditions for chaos in a system of ODEs
remain unknown.
This paper will review the history of recent attempts to identify the
simplest such system and will describe two candidate systems that are simpler
than any previously known. They were discovered by a brute-force numerical
search for the algebraically simplest chaotic flows. There are reasons
to believe that these cases are the simplest examples with quadratic and
piecewise linear nonlinearities. The properties of these systems will be
described.
Ref: J. C. Sprott, InterJournal
Complex Systems, 328
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