The **metrica** package compiles +80 functions to assess
regression (continuous) and classification (categorical) prediction
performance from multiple perspectives.

For regression models, it includes 4 plotting functions (scatter,
tiles, density, & Bland-Altman plots), and 48 prediction performance
scores including error metrics (MBE, MAE, RAE, RMAE, MAPE, SMAPE, MSE,
RMSE, RRMSE, RSR, PBE, iqRMSE), error decomposition (MLA, MLP, PLA, PLP,
PAB, PPB, SB, SDSD, LCS, Ub, Uc, Ue), model efficiency (NSE, E1, Erel,
KGE), indices of agreement (d, d1, d1r, RAC, AC, lambda), goodness of
fit (r, R2, RSS, TSS, RSE), adjusted correlation coefficients (CCC, Xa,
distance correlation-dcorr-, maximal information coefficient -MIC-),
variability (uSD, var_u), and symmetric regression coefficients (B0_sma,
B1_sma). Specifically for time-series predictions, `metrica`

also includes the Mean Absolute Scaled Error (MASE).

For supervised models, always keep in mind the concept of
“cross-validation” since predicted values should ideally come from
out-of-bag samples (unseen by training sets) to avoid overestimation of
the prediction performance.

There are two basic arguments common to all `metrica`

functions: (i) `obs`

(Oi; observed, a.k.a. actual, measured,
truth, target, label), and (ii) `pred`

(Pi; predicted, a.k.a.
simulated, fitted, modeled, estimate) values.

Optional arguments include `data`

that allows to call an
existing data frame containing both observed and predicted vectors, and
`tidy`

, which controls the type of output as a list (tidy =
FALSE) or as a data.frame (tidy = TRUE).

For regression, some specific functions for regression also require
to define the axis `orientation`

. For example, the slope of
the symmetric linear regression describing the bivariate scatter (SMA).

# | Metric | Definition | Details | Formula |
---|---|---|---|---|

01 | `RSS` |
Residual sum of squares (a.k.a. as sum of squares) | The sum of squared differences between predicted and observed values. It represents the base of many error metrics using squared scale such as the MSE | \(RSS = \sum{(O_i - P_i)^2}\) |

02 | `TSS` |
Total sum of squares | The sum of the squared differences between the observations and its mean. It is used as a reference error, for example, to estimate explained variance | \(TSS = \sum{(O_i - \bar{O})^2}\) |

03 | `var_u` |
Sample variance, uncorrected | The mean of sum of squared differences between values
of an `x` and its mean (divided by n, not n-1) |
\(var_u = \frac{1}{n}\sum{(x - \bar{x})^2}\) |

4 | `uSD` |
Sample standard deviation, uncorrected | The square root of the mean of sum of squared
differences between values of an `x` and its mean (divided by
n, not n-1) |
\(uSD = \sqrt{\frac{1}{n}\sum{(x_i - \bar{x})^2}}\) |

04 | `B0` |
Intercept of SMA regression | SMA is a symmetric linear regression (invariant results/interpretation to axis orientation) recommended to describe the bivariate scatter instead of OLS regression (classic linear model, which results vary with the axis orientation). B0 could be used to test agreement along with B1 (H0: B0 = 0, B1 = 1) . Warton et al. (2006) | \(\beta_{0_{PO}} = \bar{P} - \frac{S_P}{S_O} \, ;\, \beta_{0_{OP}} = \bar{O} - \frac{S_O}{S_P}\) |

06 | `B1` |
Slope of SMA regression | SMA is a symmetric linear regression (invariant results/interpretation to axis orientation) recommended to describe the bivariate scatter instead of OLS regression (classic linear model, which results vary with the axis orientation). B1 could be used to test isometry of the PO scatter (H0: B1 = 1). B1 also represents the ratio of standard deviations (So and Sp). Warton et al. (2006) | \(\beta_{1_{PO}} = \frac{S_P}{S_O}\, ;\, \beta_{1_{OP}} = \frac{S_O}{S_P}\) |

07 | `r` |
Pearson’s correlation coefficient | Strength of linear association between P and O. However, it measures “precision” but no accuracy. Kirch (2008) | \(r = \frac{{S}_{PO}}{{S}_{P}{S}_{O}}\) |

8 | `R2` |
Coefficient of determination | Strength of linear association between P and O. However, it measures “precision” but no accuracy | \(R^{2} = \frac{{S^2}_{PO}}{{S^2}_{P}{S^2}_{O}}\) |

09 | `Xa` |
Accuracy coefficient | Measures accuracy. Used to adjust the precision
measured by `r` to estimate agreement |
$ X_a = $ |

10 | `CCC` |
Concordance correlation coefficient | Tests agreement. It presents both precision (r) and accuracy (Xa) components. Easy to interpret. Lin (1989) | \(CCC = r * X_a\) |

11 | `MAE` |
Mean Absolute Error | Measures both lack of accuracy and precision in absolute scale. It keeps the same units than the response variable. Less sensitive to outliers than the MSE or RMSE. Willmott & Matsuura (2005) | $MAE = $ |

12 | `RMAE` |
Relative Mean Absolute Error | Normalizes the MAE with respect to the mean of observations | \(RMAE = \frac{\frac{1}{n} \sum{|O_i - P_i|}}{\bar{O}}\) |

13 | `MAPE` |
Mean Absolute Percentage Error | Percentage units (independent scale). Easy to explain and to compare performance across models with different response variables. Asymmetric and unbounded. | \(MAPE = \frac{1}{n}\sum{|\frac{O_i-P_i}{O_i}|}\) |

14 | `SMAPE` |
Symmetric Mean Absolute Percentage Error | SMAPE tackles the asymmetry issues of MAPE and includes lower (0%) and upper (200%) bounds. Makridakis (1993) | \(SMAPE = \frac{1}{n}\sum{|\frac{|O_i-P_i|}{(O_i+P_i)/2}|}\) |

15 | `RAE` |
Relative Absolute Error | RAE normalizes MAE with respect to the total absolute error. Lower bound at 0 (perfect fit) and no upper bound (infinity) | \(RAE = \frac{\sum{|P_i-O_i|}}{\sum{|O_i-\bar{O}|}}\) |

16 | `RSE` |
Relative Squared Error | Proportion of the total sum of squares that corresponds to differences between predictions and observations (residual sum of squares) | \(RSE = \frac{\sum{(P_i-O_i)^2}}{\sum{(O_i-\bar{O})^2}}\) |

17 | `MBE` |
Mean Bias Error | Main bias error metric. Same units as the response variable. Related to differences between means of predictions and observations. Negative values indicate overestimation. Positive values indicate underestimation. Unbounded. Also known as average error. Janssen & Heuberger (1995) | \(MBE = \frac{1}{n} \sum{(O_i - P_i)} = \bar{O}-\bar{P}\) |

18 | `PBE` |
Percentage Bias Error | Useful to identify systematic over or under predictions. Percentage units. As the MBE, PBE negative values indicate overestimation, while positive values indicate underestimation. Unbounded. Gupta et al. (1999) | \(PBE = 100 \frac{\sum{(P_i-O_i)}}{\sum O_i}\) |

19 | `PAB` |
Percentage Additive Bias | Percentage of the MSE related to systematic additive issues on the predictions. Related to difference of the means of predictions and observations | \(PAB = 100\frac{(\bar{O}-\bar{P})^2}{\frac{1}{n} \sum{(P_i - O_i)^2}}\) |

20 | `PPB` |
Percentage Proportional Bias | Percentage of the MSE related to systematic proportionality issues on the predictions. Related to slope of regression line describing the bivariate scatter | \(PPB = 100 \frac{S_O S_P}{\frac{1}{n} \sum{(P_i - O_i)^2}}\) |

21 | `MSE` |
Mean Squared Error | Comprises both accuracy and precision. High sensitivity to outliers | \(MSE = \frac{1}{n} \sum{(P_i - O_i)^2}\) |

22 | `RMSE` |
Root Mean Squared Error | Comprises both precision and accuracy, has the same units than the variable of interest. Very sensitive to outliers | \(RMSE = \sqrt{\frac{1}{n} \sum{(P_i - O_i)^2}}\) |

23 | `RRMSE` |
Relative Root Mean Squared Error | RMSE normalized by the mean of observations | \(RRMSE = 100\frac{\sqrt{\frac{1}{n} \sum{(P_i - O_i)^2}}}{\bar{O}}\) |

24 | `RSR` |
Root Mean Standard Deviation Ratio | RMSE normalized by the standard deviation of observations. Moriasi et al. (2007) | \(RSR = 100\frac{1}{n} \sum{(P_i - O_i)^2}\) |

25 | `iqRMSE` |
Inter-quartile Normalized Root Mean Squared Error | RMSE normalized by the interquartile range length (between percentiles 25th and 75th) | \(iqRMSE = 100\frac{\sqrt{\frac{1}{n} \sum{(P_i - O_i)^2}}}{[75^{th} percentile - 25^{th} percentile]}\) |

26 | `MLA` |
Mean Lack of Accuracy | Bias component of MSE decomposition. Correndo et al. (2021) | \(MLA = (\bar{O}-\bar{P})^2 + (S_O - S_P)^2\) |

27 | `MLP` |
Mean Lack of Precision | Variance component of MSE decomposition. Correndo et al. (2021) | \(MLP = 2 S_O S_P (1-r)\) |

28 | `RMLA` |
Root Mean Lack of Accuracy | Bias component of MSE decomposition expressed on the original units of interest. Correndo et al. (2021) | \(RMLA = \sqrt{(\bar{O}-\bar{P})^2 + (S_O - S_P)^2}\) |

29 | `RMLP` |
Root Mean Lack of Precision | Variance component of MSE decomposition expressed on the original units of interest. Correndo et al. (2021) | \(RMLP = \sqrt{2 S_O S_P (1-r)}\) |

30 | `PLA` |
Percentage Lack of Accuracy | Percentage of the MSE related to lack of accuracy (systematic differences) on the predictions. Correndo et al. (2021) | \(PLA = 100 \frac{(\bar{O}-\bar{P})^2 + (S_O - S_P)^2}{\frac{1}{n} \sum{(P_i - O_i)^2} }\) |

31 | `PLP` |
Percentage Lack of Precision | Percentage of the MSE related to lack of precision (unsystematic differences) on the predictions. Correndo et al. (2021) | \(PLP = 100 \frac{2 S_O S_P (1-r)}{\frac{1}{n} \sum{(P_i - O_i)^2} }\) |

32 | `SB` |
Squared Bias | Additive bias component, MSE decomposition. Kobayashi and Salam (2000) | \(SB=(\bar{O}-\bar{P})^2\) |

33 | `SDSD` |
Product of Standard Deviations | Proportional bias component, MSE decomposition. Kobayashi and Salam (2000) | \(SDSD = S_O S_P\) |

34 | `LCS` |
Lack of Correlation | Random error component, MSE decomposition. Kobayashi and Salam (2000) | \(LCS = 2 S_P S_O (1-r)\) |

35 | `Ue` |
Random error proportion | The Ue estimates the proportion of the total sum of squares related to the random error (unsystematic error or variance) following the sum of squares decomposition suggested by Smith and Rose (1995) also known as Theil’s partial inequalities | \(Ue = \frac{2n(1-r)S_O S_P}{\sum{(O_i-P_i)^2}}\) |

36 | `Uc` |
Lack of Consistency error proportion | The Uc estimates the proportion of the total sum of squares related to the lack of consistency (proportional bias) following the sum of squares decomposition suggested by Smith and Rose (1995) also known as Theil’s partial inequalities | \(Uc = \frac{n(S_O-S_P)^2}{\sum{(O_i-P_i)^2}}\) |

37 | `Ub` |
Mean Bias error proportion | The Ub estimates the proportion of the total sum of squares related to the mean bias following the sum of squares decomposition suggested by Smith and Rose (1995) also known as Theil’s partial inequalities | \(Ub = \frac{n(\bar{O}-\bar{P})^2}{\sum{(O_i-P_i)^2}}\) |

38 | `NSE` |
Nash and Sutcliffe’s Model Efficiency | Model efficiency using squared residuals normalized by the variance of observations. Nash and Sutcliffe (1970) | \(NSE = 1- \frac{\frac{1}{n} \sum{(P_i - O_i)^2}}{\frac{1}{n} \sum{(O_i - \bar{O})^2}}\) |

39 | `E1` |
Absolute Model Efficiency | Model efficiency. Modification of NSE using absolute residuals instead of squared residuals. Legates and McCabe (1999) | \(E1 = 1- \frac{\sum{|P_i - O_i|}}{\sum{|O_i - \bar{O}|}}\) |

40 | `Erel` |
Relative Model Efficiency | Compared to the NSE, the Erel is suggested as more sensitive to systematic over- or under-predictions. Krause et al. (2005) | \(Erel = 1- \frac{\sum{(\frac{P_i - O_i}{Oi})^2}}{\sum{(\frac{O_i - \bar{O}}{Oi})^2}}\) |

41 | `KGE` |
Kling-Gupta Model Efficiency | Model efficiency with accuracy, precision, and consistency components. Kling et al. (2012) | \(KGE = 1- \sqrt{(r-1)^2+ (\frac{S_P}{S_O}-1)^2+(\frac{\bar{P}}{\bar{O}}-1)^2}\) |

42 | `d` |
Index of Agreement | Measures accuracy and precision using squared residuals. Dimensionless (normalized). Bounded [0;1]. Asymmetric Willmott (1981) | \(d = 1- \frac{\sum{(O_i - P_i)^2}}{\sum{(|O_i - \bar{P}| + |P_i - \bar{O}|})^2}\) |

43 | `d1` |
Modified Index of Agreement | Measures accuracy and precision using absolute residuals(1). Dimensionless (normalized). Bounded [0;1]. Asymmetric Willmott et al. (1985) | \(d1 = 1- \frac{\sum{|O_i - P_i}|}{\sum{(|O_i - \bar{O}| + |P_i - \bar{O}|})}\) |

44 | `d1r` |
Refined Index of Agreement | Refines d1 by a modification on the denominator (potential error) to normalize absolute error. Willmott et al. (2012) | \(d1r = 1- \frac{\sum{|O_i - P_i}|}{2\sum{|O_i - \bar{O}|}}\) |

45 | `RAC` |
Robinson’s Agreement Coefficient | RAC measures both accuracy and precision (general agreement). Dimensionless (normalized). Bounded [0;1]. Symmetric. Robinson (1957; 1959) | \(RAC = 1- \frac{\sum{(O_i -
Z_i})^2 + \sum{(P_i - Z_i})^2}{\sum{(O_i - \bar{Z})^2 + \sum{(P_i -
\bar{Z})^2} } }\) where \(Zi = \frac{O_i + P_i}{2}; \bar{Z} = \bar{O} + \bar{P}\) |

46 | `AC` |
Ji and Gallo’s Agreement Coefficient | AC measures both accuracy and precision (general agreement). Dimensionless (normalized). Positively bounded [-infinity;1]. Symmetric. Ji and Gallo (2006) | \(AC = 1 - \frac{\sum{(O_i-P_i)^2}}{\sum{[(|\bar{P}-\bar{O}|+|O_i-\bar{O}|)(|\bar{P}-\bar{O}|+|P_i-\bar{P}|)]}}\) |

47 | `lambda` |
Duveiller’s Lambda Coefficient | `lambda` measures both accuracy and
precision. Dimensionless (normalized). Bounded [-1;1]. Symmetric.
Equivalent to CCC when `r` is greater or equal to 0.
Duveiller et al. (2016) |
\(\lambda = 1 -
\frac{\frac{1}{n}\sum(O_i-P_i)^2}{S^2_P+S^2_O+(\bar{O}-\bar{P})^2+k}\)
where $k = 0,, if,, r $, otherwise \(k = 2|\sum[(O_i-\bar{O})(P_i-\bar{P})]|\) |

48 | `dcorr` |
Distance correlation | Measures the dependency between to random vectors.
Compared to Pearson’s `r` , it offers the advantage of
considering both linear and nonlinear association patterns. It is based
on a matrix of centered Euclidean distances compared to the distance of
many shuffles of the data. It is dimensionless, bounded [0;1], and
symmetric. `dcorr = 0` characterizes independence between
vectors. The closest to 1 the better. A disadvantage for the
predicted-observed case is that values can be negatively correlated but
producing a `dcorr` close to 1. Székely (2007) |
\(dcorr = \sqrt{\frac{\mathcal{V}^2_n~(\mathbf{P,O})}{ {\sqrt{\mathcal{V}^2_n (\mathbf{P}) \mathcal{V}^2_n(\mathbf{O})} } }}\) See Székely (2007) for full details |

49 | `MIC` |
Maximal Information Coefficient | Measures association between two variables based on “binning” (a.k.a. data bucketing) to reduce the influence of small observation errors. It is based on the “mutual information” concept of information theory, which measures the mutual dependence between two variables. It is dimensionless (normalized), bounded [0;1], and symmetric. Reshef et al. (2011) | \(MIC(D) = max_{PO<B(n)}
M(D)_{X,Y} = max_{PO<B(n)}
\frac{I^{(D,P,O)}}{log(\min{P,O})}\) where \(B(n) = n^{\alpha}\) is the search-grid size, \(I^{(D,P,O)}\) is the maximum mutual information over all grids P-by-O, of the distribution induced by \(D\) on a grid having P and O bins (where the probability mass on a cell of the grid is the fraction of points of D falling in that cell). See Reshef et al. 2011, for full details. |

50 | `MASE` |
Mean Absolute Scaled Error | The `MASE` is especially well suited for
time series predictions, as it scales (or normalize) the error based on
in-sample MAE from the naive forecast method (a.k.a. random
walk). It is dimensionless (normalized) and symmetric. The reference
score is MASE = 1, which indicates that the model performs the same than
a naive forecast (error with respect to previous historical
observation). MASE <1 indicates that the model performs better than
naive forecast, and MASE > 1 indicates a bad performance of the
predictions. See Hyndman & Koehler (2006) |
\(MASE = \frac{1}{n}(\frac{|O_i-P_i|}{ \frac{1}{T-1} \sum^T_{t=2}~|O_t - O_{t-1}| })\) |

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