Flow chart for shear probes

The following steps are recommended to obtain estimates of the turbulent dissipation rate of kinetic energy ([math]\displaystyle{ \varepsilon }[/math]).

1. Extract the section to estimate dissipation time series ("Section" selection).
2. High-pass filter the shear-probe and (optionally) the vibration data.
3. Identify each diss-length segment in the section.
4. De-spike the shear-probe data, and track the fraction of data affected by de-spiking within each diss-length segment. This will become a quality-control metric.
5. Calculate the frequency spectra and cross-spectra of shear and vibrations for each detrended diss-length segment.
6. Extract the original and the vibration-coherent clean shear-probe frequency spectra with the Goodman algorithm.
7. Correct shear and vibration frequency spectra for the high-pass filter.
8. Correct the cleaned frequency spectra for the bias induced by the Goodman algorithm.
9. Convert the frequency spectra into wavenumber spectra using the mean speed, [math]\displaystyle{ U }[/math], for each diss-length segment. That is, make the wavenumber [math]\displaystyle{ k=f/U }[/math] and the spectrum [math]\displaystyle{ E(k)=UE(f) }[/math] .
10. Correct the spectra of shear for the wavenumber response of the shear probe.
11. Apply an iterative spectral integration algorithm to estimate the variance of shear.
12. If the dissipation estimate is larger than shear inertial subrange fit use the method fit to the inertial subrange
13. Calculate the turbulent dissipation rate by multiplying the shear variance by [math]\displaystyle{ \frac{15}{2}\nu }[/math] where [math]\displaystyle{ \nu }[/math] is the temperature-dependent kinematic viscosity.
14. Determine the figure of merit (FOM) for each shear-probe spectrum.
15. Calculate the expected variance of each dissipation estimate.

Please note that most choices made must be included in a data set, as described in the list of meta data.

Shear-probe data can be corrupted or compromised in several different ways. These include but are not limited to (i) collision with plankton and other materials, (ii) unremovable vibrational contamination. (iii) electronic noise, and (iv) interference from other instrumentation on a platform that carries the shear probes. This section describes the quality control metrics and the coding used to identify them. Quality-control metrics that are currently identified include;

• figure of merit (FOM)
• fraction of shear-probe data altered by the de-spiking routine
• number of iterations of the de-spiking routine required to clean the data
• agreement between dissipation estimates from redundant sensors (i.e. two or more shear probes)

The numerical threshold for these metrics should depend, as much as possible, on the known statistical properties of a turbulence shear measurement. The numerical values of the QC codes (or flags) is found in QC-flags.

Please note that most choices made must be included in a data set, as described in the list of meta data.