Long-range correlation: Difference between revisions

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The expression 'long-range correlation' specifically refers to the slow decay of the (temporal or spatial) [[:Wikipedia:Correlation|correlation]] function.  
The expression 'long-range correlation' specifically refers to the slow decay of the (temporal or spatial) [[:Wikipedia:Correlation|correlation]] function, defined as
:<math>\gamma_{XY}(\Delta) = \langle X(t) Y(t+\Delta)\rangle.</math>
Here, <math>\langle . \rangle</math> refers to an average over ''t'' and the observables ''X'' and ''Y'' depend on the time ''t'', but an analogous expression can be written down for spatial dependence.


Ignoring coherent states ('modes', to which the concept does not apply), the correlation function typically decays exponentially and can be characterized by a 'decorrelation time' (or length), calculated as the distance at which the correlation has dropped from its maximum value by an amount ''1/e''.  
Ignoring coherent states (regular oscillations or 'modes', to which the concept does not apply), the correlation function typically decays exponentially as a function of &Delta; and can be characterized by a 'decorrelation time' (or length), calculated as the distance at which the correlation has dropped from its maximum value by a factor ''1/e''.  


When the correlation exhibits a slower decay for large values of the delay (or distance) &Delta;, namely an algebraic decay proportional to 1/&Delta;<sup>&alpha;</sup> (&alpha; > 0 but not too large, < 2), the correlations at large delay may be quite important to understand the global system behaviour (contrasting sharply with the exponential decay case, in which large values of &Delta; can be safely ignored).<ref>[[doi:10.1063/1.873192|B.A. Carreras, D.E. Newman, B.Ph. van Milligen, and C. Hidalgo, ''Long-range time dependence in the cross-correlation function'', Phys. Plasmas '''6''' (1999) 485]]</ref>
When the correlation exhibits a slower decay for large values of the delay (or distance) &Delta;, namely an algebraic decay proportional to 1/&Delta;<sup>&alpha;</sup> (&alpha; > 0 but not too large, < 2), the correlations at large delay may be quite important to understand the global system behaviour (contrasting sharply with the exponential decay case, in which large values of &Delta; can be safely ignored).


This unusual, slow decay of the correlation function has important consequences, implying that the system exhibits 'memory effects' or 'non-local behaviour', which can be understood in the framework of [[Self-Organised Criticality]] and the concept of self-similarity. Also see [[Non-diffusive transport]] and [[Continuous Time Random Walk]].
This unusual, slow decay of the correlation function has important consequences, implying that the system exhibits 'memory effects' or 'non-local behaviour' (self-similarity), which can be understood in the framework of [[Self-Organised Criticality]]. Also see [[Non-diffusive transport]] and [[Continuous Time Random Walk]].
 
It can be shown that determining the long-range behaviour of the correlation function directly from &gamma;<sub>XY</sub> is not a good idea, due to its sensitivity to noise.<ref>[[doi:10.1063/1.873192|B.A. Carreras, D.E. Newman, B.Ph. van Milligen, and C. Hidalgo, ''Long-range time dependence in the cross-correlation function'', Phys. Plasmas '''6''' (1999) 485]]</ref>
Rather, techniques such as the [[:Wikipedia:Rescaled range|Rescaled Range]], [[:Wikipedia:Hurst exponent|Hurst]] analysis, or Structure functions should be used to determine long-range correlations in data series.


== References ==
== References ==
<references />
<references />

Revision as of 19:14, 4 April 2012

The expression 'long-range correlation' specifically refers to the slow decay of the (temporal or spatial) correlation function, defined as

Here, refers to an average over t and the observables X and Y depend on the time t, but an analogous expression can be written down for spatial dependence.

Ignoring coherent states (regular oscillations or 'modes', to which the concept does not apply), the correlation function typically decays exponentially as a function of Δ and can be characterized by a 'decorrelation time' (or length), calculated as the distance at which the correlation has dropped from its maximum value by a factor 1/e.

When the correlation exhibits a slower decay for large values of the delay (or distance) Δ, namely an algebraic decay proportional to 1/Δα (α > 0 but not too large, < 2), the correlations at large delay may be quite important to understand the global system behaviour (contrasting sharply with the exponential decay case, in which large values of Δ can be safely ignored).

This unusual, slow decay of the correlation function has important consequences, implying that the system exhibits 'memory effects' or 'non-local behaviour' (self-similarity), which can be understood in the framework of Self-Organised Criticality. Also see Non-diffusive transport and Continuous Time Random Walk.

It can be shown that determining the long-range behaviour of the correlation function directly from γXY is not a good idea, due to its sensitivity to noise.[1] Rather, techniques such as the Rescaled Range, Hurst analysis, or Structure functions should be used to determine long-range correlations in data series.

References