Compute the spectra: Difference between revisions
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# Convert the spectrum from the time domain to the space domain using the mean speed past the sensor {{FontColor|fg=white|bg=red|text= only for steady flows, not required for surface wave analysis}} | # Convert the spectrum from the time domain to the space domain using the mean speed past the sensor {{FontColor|fg=white|bg=red|text= only for steady flows, not required for surface wave analysis}} | ||
# Compute degrees of freedom (dof) and confidence intervals of the final spectra <ref name="EmeryThomson2001"/> based on the assumption that the spectra observations are <math>\chi | # Compute degrees of freedom (dof) and confidence intervals of the final spectra <ref name="EmeryThomson2001"/> based on the assumption that the spectra observations are <math>\chi</math>-squared distributed i.e., the turbulent velocities are gaussian (normally distributed). | ||
==<span id="specavg">Spectral averaging</span> techniques== | ==<span id="specavg">Spectral averaging</span> techniques== |
Revision as of 15:25, 11 July 2022
To compute the spectrum of the turbulent velocity fluctuations, you need to:
- Determine appropriate fft-length and spectral averaging for each data segment
- Compute the spectrum using standard techniques [1][2]
- Convert the spectrum from the time domain to the space domain using the mean speed past the sensor only for steady flows, not required for surface wave analysis
- Compute degrees of freedom (dof) and confidence intervals of the final spectra [1] based on the assumption that the spectra observations are [math]\displaystyle{ \chi }[/math]-squared distributed i.e., the turbulent velocities are gaussian (normally distributed).
Spectral averaging techniques
Each segment is often subdivided into smaller fft-length long chunks (50% overlap), which are then windowed before estimating numerous spectra (FFT) that are block-averaged for increased statistical significance. Another averaging strategy is band-averaging spectra in the frequency domain, which allows the segment length to be the same as the fft-length. A combination of both strategies is also possible. The final strategy depends on whether you need increased statistical significance for correcting motion-contaminated spectra using cospectral methods, and the lowest frequencies (wavenumbers) you want to resolve.
The spectrum's lowest resolved frequency and final resolution are the inverses of the fft-length. The fft-length dictates the lowest frequencies resolved by the spectra, while the Nyquist frequency (half the sampling rate) dictates the largest frequency of the spectra. Whether these high and low frequencies are used to estimate [math]\displaystyle{ \varepsilon }[/math] depends on the measurement quality and whether they are located in the inertial subrange, respectively.
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References
- ↑ 1.0 1.1 Emery, W. J. and and R. E. Thomson. 2001. Data analysis methods in physical oceanography, 2nd edition, Section 5.6.7-5.6.8. Elsevier. doi:(ISBN)9780080477008
- ↑ Priestly M.B.. 1981. Spectral analysis and time series: Multivariate series prediction and control. Academic Press. doi:(ISBN)0125649010