Chaos theory
From Academic Kids

Chaos theory, in mathematics and physics, deals with the behavior of certain nonlinear dynamical systems that (under certain conditions) exhibit the phenomenon known as chaos, most famously characterised by sensitivity to initial conditions (see butterfly effect). Examples of such systems include the atmosphere, the solar system, plate tectonics, turbulent fluids, economies, and population growth.
Systems that exhibit mathematical chaos are deterministic and thus orderly in some sense; this technical use of the word chaos is at odds with common parlance, which suggests complete disorder. See the article on chaos for a discussion of the origin of the word in mythology, and other uses. When we say that chaos theory studies deterministic systems, it is necessary to mention a related field of physics called quantum chaos theory that studies nondeterministic systems following the laws of quantum mechanics.
Contents 
Description of the theory
A nonlinear dynamical system can, in general, exhibit one or more of the following types of behavior:
 forever at rest
 forever expanding (only for unbounded systems)
 periodic motion
 quasiperiodic motion
 chaotic motion
The type of behavior may depend on the initial state of the system and the values of its parameters, if any. The most famous type of behavior is chaotic motion, a nonperiodic complex motion which has given name to the theory.
Chaotic motion
In order to classify the behavior of a system as chaotic, the system must exhibit the following properties:
 it must be bounded
 it must be sensitive to initial conditions
 it must be transitive
 its periodic orbits must be dense
Sensitivity to initial conditions means that two such systems may move in vastly different trajectories in their phase space even if the difference in their initial configurations were to be very small. The systems behave identically only if their initial configurations were exactly the same. An example of such sensitivity is the socalled "butterfly effect", whereby the flapping of a butterfly's wings is imagined to create tiny changes in the atmosphere which over the course of time cause it to diverge from what it would have been and potentially cause something as dramatic as a tornado to occur. The butterfly flapping its wings represents a "small" change in the initial condition of the system which causes a chain of events leading to largescale phenomena like tornadoes. Had the butterfly not flapped its wings, the trajectory of the system might have been vastly different.
Other commonlyknown examples of chaotic motion are the mixing of colored dyes and airflow turbulence.
Transitivity means that application of the transformation on any given Interval <math>I_1<math> stretches it until it overlaps with any other given Interval <math>I_2<math>.
Attractors
One way of visualizing chaotic motion, or indeed any type of motion, is to make a phase diagram of the motion. In such a diagram time is implicit and each axis represents one dimension of the state. For instance, a system at rest will be plotted as a point and a system in periodic motion will be plotted as a simple closed curve.
A phase diagram for a given system may depend on the initial state of the system (as well as on a set of parameters), but often phase diagrams reveal that the system ends up doing the same motion for all initial states in a region around the motion, almost as though the system is attracted to that motion. Such attractive motion is fittingly called an attractor for the system and is very common for forced dissipative systems.
Strange attractors
While most of the motion types mentioned above give rise to very simple attractors, such as points and circlelike curves called limit cycles, chaotic motion gives rise to what are known as strange attractors, attractors that can have great detail and complexity. For instance, a simple threedimensional model of the Lorenz weather system gives rise to the famous Lorenz attractor. The Lorenz attractor is perhaps one of the bestknown chaotic system diagrams, probably because not only was it one of the first, but it is one of the most complex and as such gives rise to a very interesting pattern which looks like the wings of a butterfly. Another such attractor is the Rössler Map, which experiences periodtwo doubling route to chaos, like the logistic map.
Strange attractors often have fractal structure.
History
The roots of chaos theory date back to about 1900, in the studies of Henri Poincaré on the problem of the motion of three objects in mutual gravitational attraction, the socalled threebody problem. Poincaré found that there can be orbits which are nonperiodic, and yet not forever increasing nor approaching a fixed point. Later studies, also on the topic of nonlinear differential equations, were carried out by G.D. Birkhoff, A.N. Kolmogorov, M.L. Cartwright, J.E. Littlewood, and Stephen Smale. Except for Smale, who was perhaps the first pure mathematician to study nonlinear dynamics, these studies were all directly inspired by physics: the threebody problem in the case of Birkhoff, turbulence and astronomical problems in the case of Kolmogorov, and radio engineering in the case of Cartwright and Littlewood. Although chaotic planetary motion had not been observed, experimentalists had encountered turbulence in fluid motion and nonperiodic oscillation in radio circuits without the benefit of a theory to explain what they were seeing.
Chaos theory progressed more rapidly after midcentury, when it first became evident for some scientists that linear theory, the prevailing system theory at that time, simply could not explain the observed behavior of certain experiments like that of the logistic map. The main catalyst for the development of chaos theory was the electronic computer. Much of the mathematics of chaos theory involves the repeated iteration of simple mathematical formulas, which would be impractical to do by hand. Electronic computers made these repeated calculations practical. One of the earliest electronic digital computers, ENIAC, was used to run simple weather forecasting models.
An early pioneer of the theory was Edward Lorenz whose interest in chaos came about accidentally through his work on weather prediction in 1961. Lorenz was using a basic computer, a Royal McBee LPG30, to run his weather simulation. He wanted to see a sequence of data again and to save time he started the simulation in the middle of its course. He was able to do this by entering a printout of the data corresponding to conditions in the middle of his simulation which he had calculated last time.
To his surprise the weather that the machine began to predict was completely different to the weather calculated before. Lorenz tracked this down to the computer printout. The printout rounded variables off to a 3digit number, but the computer worked with 5digit numbers. This difference is tiny and the consensus at the time would have been that it should have had practically no effect. However Lorenz had discovered that small changes in initial conditions produced large changes in the longterm outcome.
The term chaos as used in mathematics was coined by the applied mathematician James A. Yorke.
Moore's law and the availability of cheaper computers broadens the applicability of chaos theory. Currently, chaos theory continues to be a very active area of research.
Popular conceptions
Chaos theory has been used (and misused) in popular science fiction books and movies, according to which its importance can be illustrated by the following observations:
 In popular terms, a linear system is exactly equal to the sum of its parts, whereas a nonlinear system can be more than the sum of its parts. This means that in order to study and understand the behavior of a nonlinear system one needs in principle to study the system as a whole and not just its parts in isolation.
 It has been said that if the universe is an elephant, then linear theory can only be used to describe the last molecule in the tail of the elephant and chaos theory must be used to understand the rest. Or, in other words, linear systems in nature are relatively rare, and almost all interesting realworld systems are described by nonlinear systems.
Everyday predictable nonchaotic deterministic systems (like good billiard tables) might seem boring because, in most cases, scientists discovered exactly how they work centuries ago, and nobody who knows how they work will ever be very surprised by them. A nonchaotic system is generally better understood than a chaotic system and therefore perhaps less interesting as a plot device in science fiction. For example, chaos theory is used as a plot device in the novel Jurassic Park, and plays a central role in Ray Bradbury's short story, A Sound of Thunder. It has also entered into popular culture as reflected in video games such as Tom Clancy's Splinter Cell: Chaos Theory and with the "chaos" emeralds in Sonic the Hedgehog.
Consumer devices (such as Chaos washing machines) have exploited the popularity of chaos theory by integrating additional control features.
Mathematical theory
Mathematicians have devised many additional ways to make quantitative statements about chaotic systems. These include:
 fractal dimension of the attractor
 Lyapunov exponents
 recurrence plots
 Poincaré maps
 bifurcation diagrams
 Transfer operator
Minimum complexity of a chaotic system
Many simple systems can also produce chaos without relying on differential equations, such as the logistic map, which is a difference equation (recurrence relation) that describes population growth over time.
Even discrete systems, such as cellular automata, can heavily depend on initial conditions. Stephen Wolfram has investigated a cellular automaton with this property, termed by him rule 30.
Other examples of chaotic systems
See also
 fractal
 dynamical system
 Benoit Mandelbrot
 Mandelbrot set
 Julia set
 predictability
 Mitchell Feigenbaum
 edge of chaos
 AUTODYN
References
Textbooks and technical works
 Chaotic and Fractal Dynamics, by Francis C. Moon, ISBN 0471545716
 Chaos in Classical and Quantum Mechanics, by Martin Gutzwiller, ISBN 0387971734
 Chaos: an introduction to dynamical systems, by K. T. Alligood, T. Sauer and J. A. Yorke, ISBN 0387946772
 Chaotic dynamics, by J. P. Gollub and G. L. Baker, ISBN 0521476852
 Chaos, Scattering and Statistical Mechanics, by P.Gaspard, ISBN 0521395119
 Nonlinear Dynamics and Chaos, by Steven H. Strogatz, ISBN 0738204536
 Chaos Theory in the Social Sciences : Foundations and Applications, by L. Douglas Kiel (Editor), Euel W. Elliott (Editor), ISBN 0472084720
Semitechnical and popular works
 The Beauty of Fractals, by H.O. Peitgen and P.H. Richter
 Chance and Chaos, by David Ruelle
 Computers, Pattern, Chaos, and Beauty, by Clifford A. Pickover
 Fractals, by Hans Lauwerier
 Fractals Everywhere, by Michael Barnsley
 Order Out of Chaos, by Ilya Prigogine and Isabelle Stengers
 Chaos and Life, by Richard J Bird
 Does God Play Dice?, by Ian Stewart
 The Science of Fractal Images, by HeinzOtto Peitgen and Dietmar Saupe, Eds.
 Explaining Chaos, by Peter Smith
 Chaos, by James Gleick
 Complexity, by M. Mitchell Waldrop
 Chaos, Fractals and Selforganisation, by Arvind Kumar
 Chaotic Evolution and Strange Attractors, by David Ruelle
 Sync: The emerging science of spontaneous order, by Steven Strogatz
External links
 http://www.nbi.dk/ChaosBook/
 Chaos Theory and Education (http://www.libraryreference.org/chaos.html)
 Chaos Theory: A Brief Introduction (http://www.imho.com/grae/chaos/chaos.html)
 Linear and Nonlinear Dynamics and Vibrations Laboratory at the University of Illinois (http://www.ae.uiuc.edu/lndvl)
 The Chaos Hypertextbook (http://hypertextbook.com/chaos/). An introductory primer on chaos and fractals.
 Chaos Theory in the Social Sciences edited by L Douglas Kiel, Euel W Elliott (Google Print) (http://print.google.com/print?id=8GOECQrBRiwC&prev=http://print.google.com/print%3Fq%3Dchaos%2Btheory%2Bin%2Bthe%2Bsocial%2Bsciences&pg=19&sig=jh2fhVOYfHhZpssNTNZBZYC9d2s)
Chaos Theory is also the name of a certain album created by the artist Jumpsteady of Psychopathic Records  For more info on that, go to Chaos Theory (Album)cs:Teorie chaosu de:Chaostheorie es:Teoría del caos fr:Théorie du chaos hu:Káosz elmélet id:Teori chaos it:Teoria del caos ja:カオス理論 he:תורת הכאוס nl:Chaostheorie pl:Teoria chaosu pt:Teoria do caos fi:Kaaosteoria th:ทฤษฎีความอลวน tr:Dinamik Sistemler ve Kaos Teorisi zh:混沌理论