Correlation dimension

In chaos theory, the correlation dimension (denoted by ν) is a measure of the dimensionality of the space occupied by a set of random points, often referred to as a type of fractal dimension.^[1]^[2]^[3]

For example, if we have a set of random points on the real number line between 0 and 1, the correlation dimension will be ν = 1, while if they are distributed on say, a triangle embedded in three-dimensional space (or m-dimensional space), the correlation dimension will be ν = 2. This is what we would intuitively expect from a measure of dimension. The real utility of the correlation dimension is in determining the (possibly fractional) dimensions of fractal objects. There are other methods of measuring dimension (e.g. the Hausdorff dimension, the box-counting dimension, and the information dimension) but the correlation dimension has the advantage of being straightforwardly and quickly calculated, of being less noisy when only a small number of points is available, and is often in agreement with other calculations of dimension.

For any set of N points in an m-dimensional space

{\vec {x}}(i)=[x_{1}(i),x_{2}(i),\ldots ,x_{m}(i)],\qquad i=1,2,\ldots N

then the correlation integral C(ε) is calculated by:

C(\varepsilon )=\lim _{N\rightarrow \infty }{\frac {g}{N^{2}}}

where g is the total number of pairs of points which have a distance between them that is less than distance ε (a graphical representation of such close pairs is the recurrence plot). As the number of points tends to infinity, and the distance between them tends to zero, the correlation integral, for small values of ε, will take the form:

C(\varepsilon )\sim \varepsilon ^{\nu }

If the number of points is sufficiently large, and evenly distributed, a log-log graph of the correlation integral versus ε will yield an estimate of ν. This idea can be qualitatively understood by realizing that for higher-dimensional objects, there will be more ways for points to be close to each other, and so the number of pairs close to each other will rise more rapidly for higher dimensions.

Grassberger and Procaccia introduced the technique in 1983;^[1] the article gives the results of such estimates for a number of fractal objects, as well as comparing the values to other measures of fractal dimension. The technique can be used to distinguish between (deterministic) chaotic and truly random behavior, although it may not be good at detecting deterministic behavior if the deterministic generating mechanism is very complex.^[4]

As an example, in the "Sun in Time" article,^[5] the method was used to show that the number of sunspots on the sun, after accounting for the known cycles such as the daily and 11-year cycles, is very likely not random noise, but rather chaotic noise, with a low-dimensional fractal attractor.

Notes[]

^ Jump up to: ^a ^b Peter Grassberger and Itamar Procaccia (1983). "Measuring the Strangeness of Strange Attractors". Physica D: Nonlinear Phenomena. 9 (1��2): 189‒208. Bibcode:1983PhyD....9..189G. doi:10.1016/0167-2789(83)90298-1.
^ Peter Grassberger and Itamar Procaccia (1983). "Characterization of Strange Attractors". Physical Review Letters. 50 (5): 346‒349. Bibcode:1983PhRvL..50..346G. doi:10.1103/PhysRevLett.50.346.
^ Peter Grassberger (1983). "Generalized Dimensions of Strange Attractors". Physics Letters A. 97 (6): 227‒230. Bibcode:1983PhLA...97..227G. doi:10.1016/0375-9601(83)90753-3.
^ DeCoster, Gregory P.; Mitchell, Douglas W. (1991). "The efficacy of the correlation dimension technique in detecting determinism in small samples". Journal of Statistical Computation and Simulation. 39 (4): 221–229. doi:10.1080/00949659108811357.
^ Sonett, C., Giampapa, M., and Matthews, M. (Eds.) (1992). The Sun in Time. University of Arizona Press. ISBN 0-8165-1297-3.CS1 maint: multiple names: authors list (link) CS1 maint: extra text: authors list (link)

[grassberger-1] Jump up to: ^a ^b Peter Grassberger and Itamar Procaccia (1983). "Measuring the Strangeness of Strange Attractors". Physica D: Nonlinear Phenomena. 9 (1��2): 189‒208. Bibcode:1983PhyD....9..189G. doi:10.1016/0167-2789(83)90298-1.

[grassberger2-2] Peter Grassberger and Itamar Procaccia (1983). "Characterization of Strange Attractors". Physical Review Letters. 50 (5): 346‒349. Bibcode:1983PhRvL..50..346G. doi:10.1103/PhysRevLett.50.346.

[grassberger3-3] Peter Grassberger (1983). "Generalized Dimensions of Strange Attractors". Physics Letters A. 97 (6): 227‒230. Bibcode:1983PhLA...97..227G. doi:10.1016/0375-9601(83)90753-3.

[4] DeCoster, Gregory P.; Mitchell, Douglas W. (1991). "The efficacy of the correlation dimension technique in detecting determinism in small samples". Journal of Statistical Computation and Simulation. 39 (4): 221–229. doi:10.1080/00949659108811357.

[sit-5] Sonett, C., Giampapa, M., and Matthews, M. (Eds.) (1992). The Sun in Time. University of Arizona Press. ISBN 0-8165-1297-3.CS1 maint: multiple names: authors list (link) CS1 maint: extra text: authors list (link)

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hide v t Fractals
Characteristics	Fractal dimensions Assouad Box-counting Correlation Hausdorff Packing Topological Recursion Self-similarity
Iterated function system	Barnsley fern Cantor set Koch snowflake Menger sponge Sierpinski carpet Sierpinski triangle Apollonian gasket Fibonacci word Space-filling curve Blancmange curve De Rham curve Minkowski Dragon curve Hilbert curve Koch curve Lévy C curve Moore curve Peano curve Sierpiński curve T-square n-flake Vicsek fractal Hexaflake Gosper curve Pythagoras tree
Strange attractor	Multifractal system
L-system	Fractal canopy Space-filling curve H tree
Escape-time fractals	Burning Ship fractal Julia set Filled Newton fractal Douady rabbit Lyapunov fractal Mandelbrot set Misiurewicz point Multibrot set Newton fractal Tricorn Mandelbox Mandelbulb
Rendering techniques	Buddhabrot Orbit trap Pickover stalk
Random fractals	Brownian motion Brownian tree Brownian motor Fractal landscape Lévy flight Percolation theory Self-avoiding walk
People	Michael Barnsley Georg Cantor Bill Gosper Felix Hausdorff Desmond Paul Henry Gaston Julia Helge von Koch Paul Lévy Aleksandr Lyapunov Benoit Mandelbrot Hamid Naderi Yeganeh Lewis Fry Richardson Wacław Sierpiński
Other	"How Long Is the Coast of Britain?" Coastline paradox List of fractals by Hausdorff dimension The Beauty of Fractals (1986 book) Fractal art Chaos: Making a New Science (1987 book) The Fractal Geometry of Nature (1982 book) Kaleidoscope Chaos theory

Correlation dimension

See also[]

Notes[]