nse_rel¶

Compute the relative Nash-Sutcliffe efficiency (NSE rel).

\[NSE_{rel}=1-\frac{\sum_{i=1}^{n}\left|\frac{S_i-O_i}{O_i}\right|^2}{\sum_{i=1}^{n}\left|\frac{O_i-\overline{O}}{\overline{O}}\right|^2}\]

Range: -inf < NSE (rel) < 1, does not indicate bias, larger is better.

Notes: The modified Nash-Sutcliffe efficiency metric gives less weight to outliers if j=1, or more weight to outliers if j is higher. Generally, j=1.

Parameters:

simulated_array – An array of simulated data from the time series.
observed_array – An array of observed data from the time series.
replace_nan – If given, indicates which value to replace NaN values with in the two arrays. If None, when a NaN value is found at the i-th position in the observed OR simulated array, the i-th value of the observed and simulated array are removed before the computation.
replace_inf – If given, indicates which value to replace Inf values with in the two arrays. If None, when an inf value is found at the i-th position in the observed OR simulated array, the i-th value of the observed and simulated array are removed before the computation.
remove_neg – If True, when a negative value is found at the i-th position in the observed OR simulated array, the i-th value of the observed AND simulated array are removed before the computation.
remove_zero – If true, when a zero value is found at the i-th position in the observed OR simulated array, the i-th value of the observed AND simulated array are removed before the computation.

Return type:

The relative Nash-Sutcliffe efficiency value.

Examples

>>> import HydroErr as he
>>> import numpy as np

>>> sim = np.array([5, 7, 9, 2, 4.5, 6.7])
>>> obs = np.array([4.7, 6, 10, 2.5, 4, 7])
>>> he.nse_rel(sim, obs)
0.9062004687708474

References

Krause, P., Boyle, D., Bäse, F., 2005. Comparison of different efficiency criteria for hydrological model assessment. Advances in geosciences 5 89-97.