Bicoherence

The following applies to the analysis of data or signals

X_{i}(t)\,

For convenience and simplicity of notation, the data can be taken to have zero mean ( $\langle X_{i}\rangle =0$ ) and unit standard deviation ( $\langle X_{i}^{2}\rangle =1$ ).

The standard cross spectrum is the Fourier transform of the correlation

C_{1}(t_{1})=\left\langle X_{1}(t)X_{2}(t+t_{1})\right\rangle

where the square brackets imply averaging over t. Similarly, the bispectrum is the Fourier transform of the bicorrelation

C_{2}(t_{1},t_{2})=\left\langle X_{1}(t)X_{2}(t+t_{1})X_{2}(t+t_{2})\right\rangle

The signals X_i can either be different or identical. In the latter case, one speaks of the autocorrelation, autospectrum, auto-bicorrelation or auto-bispectrum.

Bispectrum

Denoting the Fourier transforms of the signals X_i(t) by

{\hat {X}}_{i}(\omega )

the bispectrum is defined as

B(\omega _{1},\omega _{2})={\hat {X}}_{1}^{*}(\omega ){\hat {X}}_{2}(\omega _{1}){\hat {X}}_{2}(\omega _{2})

where

\omega =\omega _{1}+\omega _{2}

Bicoherence

The bicoherence is obtained by averaging the bispectrum over statistically equivalent realizations, and normalizing the result:

b^{2}(\omega _{1},\omega _{2})={\frac {|\left\langle B(\omega _{1},\omega _{2})\right\rangle |^{2}}{\left\langle |{\hat {X}}_{1}(\omega )|^{2}\right\rangle \left\langle |{\hat {X}}_{2}(\omega _{1}){\hat {X}}_{2}(\omega _{2})|^{2}\right\rangle }}

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| ≤ ω_Nyq. 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

{\frac {1}{N(\omega )}}\sum _{\omega _{1}+\omega _{2}=\omega }{b^{2}(\omega _{1},\omega _{2})}

where N is the number of terms in the sum. Similarly, the total mean bicoherence is

{\frac {1}{N_{tot}}}\sum _{\omega _{1},\omega _{2}}{b^{2}(\omega _{1},\omega _{2})}

where N_tot 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 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. ^[1]
The bicoherence can be computed using the (continuous) wavelet transform instead of the Fourier transform, in order to improve statistics. ^[2]

References

[1] 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

[2] B.Ph. van Milligen et al, Wavelet bicoherence: a new turbulence analysis tool, Phys. Plasmas 2, 8 (1995) 3017

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