Bicoherence: Difference between revisions
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== Bispectrum == | == Bispectrum == | ||
The Fourier transforms of the signals ''X<sub>i</sub>(t)'' are denoted by | |||
:<math>\hat X_i(\omega)</math> | :<math>\hat X_i(\omega)</math> | ||
the bispectrum | Thus, the bispectrum, computed as the Fourier transform of the bicorrelation ''C<sub>2</sub>'', becomes: | ||
:<math>B(\omega_1,\omega_2) = \hat X_1^*(\omega)\hat X_2(\omega_1) \hat X_2(\omega_2)</math> | :<math>B(\omega_1,\omega_2) = \hat X_1^*(\omega)\hat X_2(\omega_1) \hat X_2(\omega_2)</math> | ||
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:<math>\omega = \omega_1 + \omega_2</math> | :<math>\omega = \omega_1 + \omega_2</math> | ||
Hence, the bispectrum is interpreted as a measure of the degree of three-wave coupling. | |||
== Bicoherence == | == Bicoherence == |
Revision as of 14:41, 6 July 2011
The following applies to the analysis of data or signals
For convenience and simplicity of notation, the data can be taken to have zero mean () and unit standard deviation ().
The standard cross spectrum is the Fourier transform of the correlation
where the square brackets imply averaging over t. Similarly, the bispectrum is the Fourier transform of the bicorrelation
The signals Xi can either be different or identical. In the latter case, one speaks of the autocorrelation, autospectrum, auto-bicorrelation or auto-bispectrum.
Bispectrum
The Fourier transforms of the signals Xi(t) are denoted by
Thus, the bispectrum, computed as the Fourier transform of the bicorrelation C2, becomes:
where
Hence, the bispectrum is interpreted as a measure of the degree of three-wave coupling.
Bicoherence
The bicoherence is obtained by averaging the bispectrum over statistically equivalent realizations, and normalizing the result:
The normalization is such that 0 ≤ b2 ≤ 1.
The bicoherence is symmetric under the transformations (ω1,ω2) → (ω2,ω1) and (ω1,ω2) → (-ω1,-ω2), so that only one quarter of the plane (ω1,ω2) contains independent information. Additionally, for discretely sampled data all frequencies must be less than the Nyquist frequency: |ω1|,|ω2|,|ω| ≤ ωNyq. These restrictions define a polygonal subspace of the plane, which is how the bicoherence is usually represented (for an example, see TJ-II:Turbulence).
The summed bicoherence is defined by
where N is the number of terms in the sum. Similarly, the total mean bicoherence is
where Ntot is the number of terms in the sum.
Interpretation
The bicoherence measures three-wave coupling and is only large when the phase between the wave at ω and the sum wave ω1+ω2 is nearly constant over a significant number of realizations.
Notes
- The bicoherence can be computed using the (continuous) wavelet transform instead of the Fourier transform, in order to improve statistics. [1]
- The bicoherence can of course be defined in wavenumber space instead of frequency space by applying the replacements t → x and ω → k.
- Combined temporal-spatial studies are also possible. [2]
Starting from the spatio-temporal bicorrelation
the spatio-temporal bispectrum is
where and .
References
- ↑ B.Ph. van Milligen et al, Wavelet bicoherence: a new turbulence analysis tool, Phys. Plasmas 2, 8 (1995) 3017
- ↑ T. Yamada, S.-I. Itoh, S. Inagaki, Y. Nagashima, S. Shinohara, N. Kasuya, K. Terasaka, K. Kamataki, H. Arakawa, M. Yagi, A. Fujisawa, and K. Itoh, Two-dimensional bispectral analysis of drift wave turbulence in a cylindrical plasma , Phys. Plasmas 17 (2010) 052313