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Given the initial measured values <math>x_0</math>, final observed or measured values <math>x_m</math> and final calculated values <math>x_c</math>, there are several goodness-of-fit statistics which can be calculated. The definition for some of the more common ones are provided below. | Given the initial measured values <math>x_0</math>, final observed or measured values <math>x_m</math> and final calculated values <math>x_c</math>, there are several goodness-of-fit statistics which can be calculated. The definition for some of the more common ones are provided below. | ||
= Dimensional Statistics = | |||
== Mean Error == | |||
The mean error (ME), also referred to as bias (B) is given by | |||
{{Equation|<math> | |||
ME = \langle x_c - x_m \rangle = \langle x_c \rangle - \langle x_m \rangle | |||
</math>|1}} | |||
Smaller absolute ME values indicate better agreement between measured and calculated values. Positive values indicate positively biased computed values (overprediction) while negative values indicate negatively biased computed values (underprediction). | |||
Example Matlab code: | |||
ME = mean(xc(:)-xm(:)); | |||
== Mean-Absolute Error == | |||
The mean absolute error is given by | |||
{{Equation|<math> | |||
MAE = \bigg\langle \big| x_c - x_m \big| \bigg\rangle | |||
</math>|2}} | |||
Similarly to the RMSE, smaller MAE values indicate better agreement between measured and calculated values. | |||
Example Matlab code: | |||
MAE = mean(abs(xc(:)-xm(:))); | |||
== Root-Mean-Squared Error == | == Root-Mean-Squared Error == | ||
The Root-Mean-Squared Error (RMSE) also referred to as Root-Mean-Squared Deviation (RMSD) is defined as | The Root-Mean-Squared Error (RMSE) also referred to as Root-Mean-Squared Deviation (RMSD) is defined as | ||
{{Equation|<math> | {{Equation|<math> | ||
RMSE = \sqrt{ \bigg\langle \big( x_m | RMSE = \sqrt{ \bigg\langle \big( x_c - x_m \big)^2 \bigg\rangle } | ||
</math>|3}} | </math>|3}} | ||
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RMSE = sqrt(mean((xc(:)-xm(:)).^2)); | RMSE = sqrt(mean((xc(:)-xm(:)).^2)); | ||
== | == Standard Deviation of Residuals == | ||
The | The standard deviation of residuals (SDR) is calculated as | ||
{{Equation|<math> | {{Equation|<math> | ||
SDR = \sqrt{ \bigg\langle \bigg[ (x_c - x_m \big) - (\langle x_c \rangle - \langle x_m \rangle) \bigg]^2} | |||
</math>|4}} | </math>|4}} | ||
SDR is a measure of the dynamical correspondence. Smaller values indicate better agreement. The RMSE, ME, STD are related by the following formula | |||
{{Equation|<math> | {{Equation|<math> | ||
RMSE^2 = ME^2 + SDR^2 | |||
</math>| | </math>|5}} | ||
Example Matlab Code: | |||
SDR= sqrt(mean((xc(:)-xm(:)-mean(xc(:))+mean(xm(:))).^2)); | |||
== Normalization == | |||
The dimensional statistics above, namely RMSE, MAE, and B; can be normalized to produce a nondimensional statistic. When the variable is normalized the statistic is commonly prefixed by a letter N for normalized or R for relative (e.g. NRMSE, EMAE, and NB). This also has facilitates the comparison between different datasets or models which have different scales. For example, when comparing models to laboratory data the dimensional statistics will produce relatively smaller dimensional goodness-of-fit statistics compared to field data comparisons. One drawback of normalization is that there is no consistent means of normalization. Different types of data or normalized differently literature. For example, water levels are commonly normalized by the tidal range, while wave heights may be normalized by the offshore wave height. In some cases, the range of the measured data is a good choice. The range is defined as the maximum value minus the minimum value. | |||
{{Equation|<math>x_N=range(x_m)=\max(x_m)-\min(x_m)</math>|6}} | |||
{{Equation|<math> | |||
</math>| | |||
Another common approach to nomralization is to use the mean value of the measurements | Another common approach to nomralization is to use the mean value of the measurements | ||
{{Equation|<math> | {{Equation|<math>x_N = mean(x_m) </math>|7}} | ||
</math>| | |||
When the RMS value is normalized by the mean measured value, is sometimes referred to as the scatter index (SI) (Zambresky 1989). When the RMS value is normalized by a specific measured value used to drive a model, it is sometimes referred to as the Operational Performance Index (OPI) (Ris et al. 1999). The OPI can be used for example to give an estimate of the performance of a nearshore wave height transformation model based on the offshore measured wave height. | When the RMS value is normalized by the mean measured value, is sometimes referred to as the scatter index (SI) (Zambresky 1989). When the RMS value is normalized by a specific measured value used to drive a model, it is sometimes referred to as the Operational Performance Index (OPI) (Ris et al. 1999). The OPI can be used for example to give an estimate of the performance of a nearshore wave height transformation model based on the offshore measured wave height. | ||
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More important than the choice of normalization variable is to properly describe how the statistics have been normalized. | More important than the choice of normalization variable is to properly describe how the statistics have been normalized. | ||
= Nondimensional Statistics = | |||
== Performance Scores== | == Performance Scores== | ||
There are several goodness-of-fit statitics in literature of the form | There are several goodness-of-fit statitics in literature of the form | ||
{{Equation|<math> | {{Equation|<math> | ||
PS = 1 - \frac{\bigg\langle \big(x_m | PS = 1 - \frac{\bigg\langle \big(x_c-x_m\big)^2 \bigg\rangle}{\bigg\langle \big(x_m - x_R \big)^2 \bigg\rangle } | ||
</math>| | </math>|8}} | ||
where <math> | where <math> x_R </math> is a reference value(s). When the reference value is equal to the base or initial measurements <math> x_R = x_0</math>, then the Peformance Score is referred to as the Brier Skill Score (BSS) or Brier Skill Index (BSI). When the reference value is equal to the mean measured value <math> x_R = \langle x_m \rangle</math>, then the Performance Score is referred to the Nash-Sutcliffe Coefficient (E) or Nash-Sutcliffe Score (ES) (Nash and Sutcliffe 1970). When the reference value is a specific measured value such as a model forcing value, then it is referred to as the Model Performance Index (MPI) or Model Performance Score (MPS). | ||
The various performance scores ranges between negative infinity and one. A performance score of 1 indicates a perfect agreement between measured and calculated values. Scores equal to or less than 0 indicates that the initial value is as or more accurate than the calculated values. Recommended qualifications for different BSS ranges are provided in Table 1. | The various performance scores ranges between negative infinity and one. A performance score of 1 indicates a perfect agreement between measured and calculated values. Scores equal to or less than 0 indicates that the initial value is as or more accurate than the calculated values. Recommended qualifications for different BSS ranges are provided in Table 1. | ||
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Example Matlab Code: | Example Matlab Code: | ||
BSS = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)- | BSS = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-x0(:)).^2); | ||
ES = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-mean(xm(:))).^2); | ES = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-mean(xm(:))).^2); | ||
MPS = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)- | MPS = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-xR).^2); | ||
== Index of Agreement == | |||
The index of agreement (IA or d) is given by (Willmott et al. 1985) | |||
{{Equation|<math> | |||
IA = 1 - \frac{\bigg\langle \big(x_c-x_m\big)^2 \bigg\rangle}{\bigg\langle \big(| x_c - \langle x_c \rangle | + | x_m - \langle x_m \rangle |\big)^2 \bigg\rangle } | |||
</math>|9}} | |||
The denominator in the above equation is referred to as the potential error. IA is a nondimensional and bounded measure with values closer to 1 indicating better agreement. | |||
Example Matlab code: | |||
IA = 1 - mean((xc(:)-xm(:)).^2)/max(mean((abs(xc(:)-mean(xm(:)))+abs(xm(:)-mean(xm(:)))).^2),eps) | |||
== Correlation Coefficient == | == Correlation Coefficient == | ||
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{{Equation|<math> | {{Equation|<math> | ||
R = \frac { \langle x_m x_c \rangle - \langle x_m \rangle \langle x_c \rangle }{ \sqrt{ \langle x_m^2 \rangle - \langle x_m \rangle ^2} \sqrt{ \langle x_c^2 \rangle - \langle x_c \rangle ^2} } | R = \frac { \langle x_m x_c \rangle - \langle x_m \rangle \langle x_c \rangle }{ \sqrt{ \langle x_m^2 \rangle - \langle x_m \rangle ^2} \sqrt{ \langle x_c^2 \rangle - \langle x_c \rangle ^2} } | ||
</math>| | </math>|10}} | ||
A correlation of 1 indicates a perfect one-to-one linear relationship and -1 indicates a negative relationship. The square of the correlation coefficient describes how much of the variance between two variables is described by a linear fit. | A correlation of 1 indicates a perfect one-to-one linear relationship and -1 indicates a negative relationship. The square of the correlation coefficient describes how much of the variance between two variables is described by a linear fit. | ||
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R = corrcoef(yc,ym); | R = corrcoef(yc,ym); | ||
= References = | |||
* Nash, J.E., and Sutcliffe, J.V. 1970. River flow forecasting through conceptual models part I — A discussion of principles, Journal of Hydrology, 10(3), 282–290. | |||
* Ris, R.C., Holthuijsen, L.H., and Booij, N. 1999. A third-generation wave model for coastal regions 2, verification. Journal of Geophysical Research, 104(C4) 7667-7681. | * Ris, R.C., Holthuijsen, L.H., and Booij, N. 1999. A third-generation wave model for coastal regions 2, verification. Journal of Geophysical Research, 104(C4) 7667-7681. | ||
* Willmott, C.J., Ackleson, S.G., Davis, R.E., Feddema, J.J., Klink, K.M., Legates, D.R., O’Donnell, J., and Rowe, C.M. 1985. Statistics for the evaluation and comparison of models, Journal of Geophysical Research, 90(C5), 8995–9005. | |||
* Zambreskey, L., 1988. A verification study of the global WAM model, December 1987 – November 1988. GKSS Forschungzentrum Geesthacht GMBH Report GKSS 89/E/37. | * Zambreskey, L., 1988. A verification study of the global WAM model, December 1987 – November 1988. GKSS Forschungzentrum Geesthacht GMBH Report GKSS 89/E/37. | ||
= Symbols = | |||
A description of all the symbols in the equations above is provided in Table 3. | A description of all the symbols in the equations above is provided in Table 3. | ||
Latest revision as of 19:48, 5 June 2014
Given the initial measured values , final observed or measured values and final calculated values , there are several goodness-of-fit statistics which can be calculated. The definition for some of the more common ones are provided below.
Dimensional Statistics
Mean Error
The mean error (ME), also referred to as bias (B) is given by
(1) |
Smaller absolute ME values indicate better agreement between measured and calculated values. Positive values indicate positively biased computed values (overprediction) while negative values indicate negatively biased computed values (underprediction).
Example Matlab code:
ME = mean(xc(:)-xm(:));
Mean-Absolute Error
The mean absolute error is given by
(2) |
Similarly to the RMSE, smaller MAE values indicate better agreement between measured and calculated values.
Example Matlab code:
MAE = mean(abs(xc(:)-xm(:)));
Root-Mean-Squared Error
The Root-Mean-Squared Error (RMSE) also referred to as Root-Mean-Squared Deviation (RMSD) is defined as
(3) |
The RMSE has the same units as the measured and calculated data. Smaller values indicate better agreement between measured and calculated values.
Example Matlab Code:
RMSE = sqrt(mean((xc(:)-xm(:)).^2));
Standard Deviation of Residuals
The standard deviation of residuals (SDR) is calculated as
(4) |
SDR is a measure of the dynamical correspondence. Smaller values indicate better agreement. The RMSE, ME, STD are related by the following formula
(5) |
Example Matlab Code:
SDR= sqrt(mean((xc(:)-xm(:)-mean(xc(:))+mean(xm(:))).^2));
Normalization
The dimensional statistics above, namely RMSE, MAE, and B; can be normalized to produce a nondimensional statistic. When the variable is normalized the statistic is commonly prefixed by a letter N for normalized or R for relative (e.g. NRMSE, EMAE, and NB). This also has facilitates the comparison between different datasets or models which have different scales. For example, when comparing models to laboratory data the dimensional statistics will produce relatively smaller dimensional goodness-of-fit statistics compared to field data comparisons. One drawback of normalization is that there is no consistent means of normalization. Different types of data or normalized differently literature. For example, water levels are commonly normalized by the tidal range, while wave heights may be normalized by the offshore wave height. In some cases, the range of the measured data is a good choice. The range is defined as the maximum value minus the minimum value.
(6) |
Another common approach to nomralization is to use the mean value of the measurements
(7) |
When the RMS value is normalized by the mean measured value, is sometimes referred to as the scatter index (SI) (Zambresky 1989). When the RMS value is normalized by a specific measured value used to drive a model, it is sometimes referred to as the Operational Performance Index (OPI) (Ris et al. 1999). The OPI can be used for example to give an estimate of the performance of a nearshore wave height transformation model based on the offshore measured wave height.
More important than the choice of normalization variable is to properly describe how the statistics have been normalized.
Nondimensional Statistics
Performance Scores
There are several goodness-of-fit statitics in literature of the form
(8) |
where is a reference value(s). When the reference value is equal to the base or initial measurements , then the Peformance Score is referred to as the Brier Skill Score (BSS) or Brier Skill Index (BSI). When the reference value is equal to the mean measured value , then the Performance Score is referred to the Nash-Sutcliffe Coefficient (E) or Nash-Sutcliffe Score (ES) (Nash and Sutcliffe 1970). When the reference value is a specific measured value such as a model forcing value, then it is referred to as the Model Performance Index (MPI) or Model Performance Score (MPS).
The various performance scores ranges between negative infinity and one. A performance score of 1 indicates a perfect agreement between measured and calculated values. Scores equal to or less than 0 indicates that the initial value is as or more accurate than the calculated values. Recommended qualifications for different BSS ranges are provided in Table 1.
Table 1. Performance Score Qualifications
Range | Qualification |
0.8<PS<1.0 | Excellent |
0.6<PS<0.8 | Good |
0.3<PS<0.6 | Reasonable |
0<PS<0.3 | Poor |
PS<0 | Bad |
Example Matlab Code:
BSS = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-x0(:)).^2); ES = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-mean(xm(:))).^2); MPS = 1 - mean((xc(:)-xm(:)).^2)/mean((xm(:)-xR).^2);
Index of Agreement
The index of agreement (IA or d) is given by (Willmott et al. 1985)
(9) |
The denominator in the above equation is referred to as the potential error. IA is a nondimensional and bounded measure with values closer to 1 indicating better agreement.
Example Matlab code:
IA = 1 - mean((xc(:)-xm(:)).^2)/max(mean((abs(xc(:)-mean(xm(:)))+abs(xm(:)-mean(xm(:)))).^2),eps)
Correlation Coefficient
The correlation is a measure of the strength and direction of a linear relationship between two variables. The correlation coefficient is defined as
(10) |
A correlation of 1 indicates a perfect one-to-one linear relationship and -1 indicates a negative relationship. The square of the correlation coefficient describes how much of the variance between two variables is described by a linear fit.
Example Matlab code:
R = corrcoef(yc,ym);
References
- Nash, J.E., and Sutcliffe, J.V. 1970. River flow forecasting through conceptual models part I — A discussion of principles, Journal of Hydrology, 10(3), 282–290.
- Ris, R.C., Holthuijsen, L.H., and Booij, N. 1999. A third-generation wave model for coastal regions 2, verification. Journal of Geophysical Research, 104(C4) 7667-7681.
- Willmott, C.J., Ackleson, S.G., Davis, R.E., Feddema, J.J., Klink, K.M., Legates, D.R., O’Donnell, J., and Rowe, C.M. 1985. Statistics for the evaluation and comparison of models, Journal of Geophysical Research, 90(C5), 8995–9005.
- Zambreskey, L., 1988. A verification study of the global WAM model, December 1987 – November 1988. GKSS Forschungzentrum Geesthacht GMBH Report GKSS 89/E/37.
Symbols
A description of all the symbols in the equations above is provided in Table 3.
Table 3. Description of symbols
Symbol | Description |
Measured values | |
Calculated values | |
Initial measured values | |
Normalization value | |
Expectation (averaging) operator |