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15 Appendix E: Goodness of Fit Statistics | =15 Appendix E: Goodness of Fit Statistics= | ||
Brier Skill Score | |||
==Brier Skill Score== | |||
The Brier Skill Score (BSS) is defined as | The Brier Skill Score (BSS) is defined as | ||
{{Equation|<math>BSS = 1 - \frac{\langle(x_m - x_c)^2 \rangle}{\langle (x_m - x_0)^2 \rangle} </math> |A1}} | |||
where the angled brackets indicate averaging, subscripts m, c, and 0 indi-cate measured, calculated, and initial values, respectively. The BSS ranges between negative infinity and one. A BSS value of 1 indicates a perfect agreement between measured and calculated values. Scores equal to or less than 0 indicates that the mean observed value is as or more accurate than the calculated values. The following quantifications are used for de-scribing the BSS values: 0.8<BSS<1.0 = excellent, 0.6<BSS<0.8 = good, 0.3<BSS<0.6 = reasonable, 0<BSS<0.3 = poor, BSS<0 = bad. | where the angled brackets indicate averaging, subscripts m, c, and 0 indi-cate measured, calculated, and initial values, respectively. The BSS ranges between negative infinity and one. A BSS value of 1 indicates a perfect agreement between measured and calculated values. Scores equal to or less than 0 indicates that the mean observed value is as or more accurate than the calculated values. The following quantifications are used for de-scribing the BSS values: 0.8<BSS<1.0 = excellent, 0.6<BSS<0.8 = good, 0.3<BSS<0.6 = reasonable, 0<BSS<0.3 = poor, BSS<0 = bad. | ||
Room Mean Squared Error | |||
=Room Mean Squared Error= | |||
The Root Mean Squared Error (RMSE) is defined as | The Root Mean Squared Error (RMSE) is defined as | ||
{{Equation|<math>RMSE = \sqrt{\langle (x_c - x_m)^2 \rangle}</math>|A2}} | |||
The RMSE has the same units as the measured data. Lower values of RMSE indicate a better match between measured and computed values. | The RMSE has the same units as the measured data. Lower values of RMSE indicate a better match between measured and computed values. | ||
Normalized Root Mean Squared Error | |||
=Normalized Root Mean Squared Error= | |||
The Normalized Root Mean Squared Error (NRMSE) is | The Normalized Root Mean Squared Error (NRMSE) is | ||
The NRMSE is often expressed in units of percent. The measured data range | {{Equation|<math>NRMSE = \frac{RMSE}{range(x_m)}</math>|A3}} | ||
Mean Absolute Error | |||
The NRMSE is often expressed in units of percent. The measured data range ''range(x<sub>m</sub>) '' can be estimated as max(x<sub>m</sub>) - min(x<sub>m</sub>) . Lower values of NRMSE indicate a better agreement between measured and computed values. | |||
=Mean Absolute Error= | |||
The Mean Absolute Error (MAE) is defined as | The Mean Absolute Error (MAE) is defined as | ||
Normalized Mean Absolute Error | {{Equation|<math>MAE = \langle | x_c - x_m | \rangle</math>|A4}} | ||
=Normalized Mean Absolute Error= | |||
Similarly, the Normalized Mean Absolute Error (NMAE) is given by | Similarly, the Normalized Mean Absolute Error (NMAE) is given by | ||
{{Equation|<math> NMAE = \frac{MAE}{range(x_m)}</math>|A5}} | |||
The NMAE is often expressed in units of percent. Smaller values of NMAE indicate a better agreement between measured and calculated values. | The NMAE is often expressed in units of percent. Smaller values of NMAE indicate a better agreement between measured and calculated values. | ||
Correlation Coefficient | |||
=Correlation Coefficient= | |||
Correlation is a measure of the strength and direction of a linear relation-ship between two variables. The correlation coefficient R is defined as | Correlation is a measure of the strength and direction of a linear relation-ship between two variables. The correlation coefficient R is defined as | ||
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. The interpretation of the correlation coefficient depends on the context and purposes. For the present work, the following qualifications are used: 0.7< | {{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_2 \rangle^2 }} </math>|A5}} | ||
Bias | |||
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. The interpretation of the correlation coefficient depends on the context and purposes. For the present work, the following qualifications are used: 0.7<R<sup>2</sup><1 = strong, 0.4<R<sup>2</sup><0.7 = medium, 0.2<R<sup>2</sup><0.4 = small, and R<sup>2</sup><0.2 = none. | |||
=Bias= | |||
The Bias is defined as | The Bias is defined as | ||
Positive values indicate over-prediction and negative values indicate | {{Equation|<math> Bias = \langle x_c - x_m \rangle </math>|A6}} | ||
Positive values indicate over-prediction and negative values indicate under-prediction. |
Latest revision as of 20:38, 2 May 2015
15 Appendix E: Goodness of Fit Statistics
Brier Skill Score
The Brier Skill Score (BSS) is defined as
(A1) |
where the angled brackets indicate averaging, subscripts m, c, and 0 indi-cate measured, calculated, and initial values, respectively. The BSS ranges between negative infinity and one. A BSS value of 1 indicates a perfect agreement between measured and calculated values. Scores equal to or less than 0 indicates that the mean observed value is as or more accurate than the calculated values. The following quantifications are used for de-scribing the BSS values: 0.8<BSS<1.0 = excellent, 0.6<BSS<0.8 = good, 0.3<BSS<0.6 = reasonable, 0<BSS<0.3 = poor, BSS<0 = bad.
Room Mean Squared Error
The Root Mean Squared Error (RMSE) is defined as
(A2) |
The RMSE has the same units as the measured data. Lower values of RMSE indicate a better match between measured and computed values.
Normalized Root Mean Squared Error
The Normalized Root Mean Squared Error (NRMSE) is
(A3) |
The NRMSE is often expressed in units of percent. The measured data range range(xm) can be estimated as max(xm) - min(xm) . Lower values of NRMSE indicate a better agreement between measured and computed values.
Mean Absolute Error
The Mean Absolute Error (MAE) is defined as
(A4) |
Normalized Mean Absolute Error
Similarly, the Normalized Mean Absolute Error (NMAE) is given by
(A5) |
The NMAE is often expressed in units of percent. Smaller values of NMAE indicate a better agreement between measured and calculated values.
Correlation Coefficient
Correlation is a measure of the strength and direction of a linear relation-ship between two variables. The correlation coefficient R is defined as
(A5) |
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. The interpretation of the correlation coefficient depends on the context and purposes. For the present work, the following qualifications are used: 0.7<R2<1 = strong, 0.4<R2<0.7 = medium, 0.2<R2<0.4 = small, and R2<0.2 = none.
Bias
The Bias is defined as
(A6) |
Positive values indicate over-prediction and negative values indicate under-prediction.