Processing your ADCP data using structure function techniques

To calculate the dissipation rate at a specific range bin and a specific time ensemble:

1. Extract or compute the along-beam bin center separation [${\displaystyle \delta r_0}$] based on the instrument geometry
2. Calculate the along-beam velocity fluctuation time-series in each bin ${\displaystyle n}$, where [Failed to parse (syntax error): {\displaystyle b’(n, t_s)} ] from the along-beam velocity data that has met the QC criteria (i.e. the data in Level 2 of the netcdf file). Note ${\displaystyle t_s}$ is the timeseries index within a segment.
3. Select the maximum distance (${\displaystyle r_{max}}$) over which to compute the structure function based on conditions of the flow (e.g., expected max overturn, spectral range corresponding to Failed to parse (unknown function "\math"): {\displaystyle k^{-5/3} <\math>). The corresponding number of bins is [<math>n_{\text{rmax}} = r_{max} / \delta r_0} ]
4. Calculate the structure function ${\displaystyle D_{ll}}$ for all possible bin separations ${\displaystyle \delta }$ within ${\displaystyle r_{max}}$ using either a bin-centred difference scheme or a forward-difference scheme.
5. Perform a regression of ${\displaystyle D_{ll}(n,\delta )}$ against ${\displaystyle (\delta r{)}^{2/3}}$ for the appropriate range of bins and ${\displaystyle \delta }$r separation distances. Be aware of special considerations for forward-difference, center-difference schemes in setting up the regression calculation. The regression is typically done as a least-squares fit, either as:
   
   ${\displaystyle D_{ll}=a_0+a_1(\delta r{)}^{2/3}}$;

or as

${\displaystyle D_{ll}=a_0+a_1(\delta r{)}^{2/3}+a_3((\delta r{)}^{2/3}{)}^3}$

the former being the canonical method that excludes non-turbulent velocity differences between bins, whereas the latter is a modified method that includes non-turbulent velocity differences between bins due to any oscillatory signal (e.g. surface waves, motion of the ADCP on a mooring).

6. Use the coefficient ${\displaystyle a_1}$ to calculate ${\displaystyle \epsilon }$ as
   
   ${\displaystyle \epsilon ={\left(\frac{a_1}{C_2}\right)}^{2/3}}$
   
   where ${\displaystyle C_2}$ is an empirical constant, typically taken as 2.0 or 2.1.

Next step: Apply quality-control on dissipation rates (QA2)

Previous step: Apply quality-control on velocity time series data (QA1)

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