| • Science | • People | • Locations | • Timeline |
| Contents | ||
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 non-deterministic systems following the laws of quantum mechanics.
A non-linear dynamical system can in general exhibit one or more of the following types of behaviour:
The type of behaviour may depend on the initial state of the system and the values of its parameters, if any.
The most famous type of behaviour is chaotic motion, a non-periodic complex motion which has given name to the theory. In order to classify the behaviour of a system as chaotic, the system must exhibit the following properties:
Sensitivity to initial conditions means that two such systems with however small a difference in their initial state eventually will end up with a finite difference between their states (however, two deterministic systems with identical initial conditions will remain identical). An example of such sensitivity is the well-known butterfly effect, whereby the flapping of a butterfly's wings produces 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. Other commonly-known examples of chaotic motion are the mixing of colored dyeA dye can generally be described as a coloured substance that has an affinity to the substrate to which it is being applied. The dye is usually used as an aqueous solution and may require a mordant to improve the fastness of the dye on the fibre. In contrs and airflow turbulence.
Transitivity means that application of the transformation on any given Interval I1 stretches it until it overlaps with any other given Interval I2.
The fourth condition means that for any point in the system and any real number ε > 0 there is another point with distance d ≤ ε which is located on a periodic orbit.
One way of visualizing chaotic motion, or indeed any type of motion, is to make a phase diagramA phase diagram or phase space is a useful construct used in mathematics and physics to demonstrate and visualise the changes in a given system. Every degree of freedom or parameter of the system is represented as an axis of a multidimensional space. 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 attractorIn the study of dynamical systems, an attractor is a 'set', 'curve', or 'space' to which that a system irreversibly evolves, if left undisturbed. It is other-wise known as a 'limit set'. There are five known types of attractors; point attractors periodic for the system and is very common for forced dissipative systems.