Outline

This vignette is organized as follows:

  1. Getting started

  2. Exploring the data

  3. Model specification

  4. Parameter estimation

  5. Robust prediction of the area-level means

  6. Mean square prediction error

Citable companion paper of the package

Schoch, T. (2012). Robust Unit-Level Small Area Estimation: A Fast Algorithm for Large Datasets. Austrian Journal of Statistics 41(4), pp. 243–265. URL: www.stat.tugraz.at/AJS/ausg124/124Schoch.pdf

1 Getting started

In small area estimation (SAE), we distinguish two types of models:

The classification of the models (A or B) is from Rao (2003, Chapter 7). The current version of the package implements the following estimation methods under the unit-level model (model B):

IMPORTANT.

The implemented M-estimator is the RML II estimator of Richardson and Welsh (1995); see Schoch, (2012). This method is different from the estimators in Sinha and Rao (2009).

The package can be installed from CRAN using install.packages("rsae"). Once the rsae package has been installed, we need to load it to the current session by library("rsae").

Work flow

The prediction of the area-level means takes three steps.

2 Exploring the data

We use the landsat data of Battese et al. (1988), which is loaded by

> data("landsat")

The landsat data is a compilation of survey and satellite data from Battese et al. (1988). It consists of data on segments (primary sampling unit; 1 segement approx. 250 hectares) under corn and soybeans for 12 counties in north-central Iowa.

In the three smallest counties (Cerro Gordo, Hamilton, and Worth), data is available only for one sample segment. All other counties have data for more than one sample segment (i.e., unbalanced data). The largest area (Hardin) covers six units.

The data for the observations 32, 33, and 34 are shown below

> landsat[32:34,]
   SegmentsInCounty SegementID HACorn HASoybeans PixelsCorn PixelsSoybeans
32              556          1  88.59     102.59        220            262
33              556          2  88.59      29.46        340             87
34              556          3 165.35      69.28        355            160
   MeanPixelsCorn MeanPixelsSoybeans outlier CountyName
32         325.99             177.05   FALSE     Hardin
33         325.99             177.05    TRUE     Hardin
34         325.99             177.05   FALSE     Hardin

We added the variable outlier to the original data. It flags observation 33 as an outlier, which is in line with the discussion in Battese et al. (1988).

3 Model specification

We consider estimating the parameters of the basic unit-level model (Battese et al. , 1988)

\[ \begin{equation*} \mathrm{HACorn}_{i,j} = \alpha + \beta_1 \mathrm{PixelsCorn}_{i,j} + \beta_2 \mathrm{PixelsSoybeans}_{i,j} + u_i + e_{i,j}, \end{equation*} \]

where \(j=1,\ldots, n_i\), \(i=1, \ldots,12\), and

The model is defined with the help of thesaemodel()function:

> bhfmodel <- saemodel(formula = HACorn ~ PixelsCorn + PixelsSoybeans,
+                      area = ~ CountyName,
+                      data = subset(landsat, subset = (outlier == FALSE)))

where

If you need to know more about a particular model, you can use the summary() method.

4 Parameter estimation

Having specified bhfmodel, we consider estimating its parameters by different estimation method.

4.1 Maximum-likelihood estimation

The maximum likelihood (ML) estimates of the parameters are computed by

> mlfit <- fitsaemodel(method = "ml", bhfmodel)

On print, object mlfit shows the following.

> mlfit
ESTIMATES OF SAE-MODEL (model type B) 
Method:  Maximum likelihood estimation 
---
Fixed effects
Model: HACorn ~ (Intercept) + PixelsCorn + PixelsSoybeans 

Coefficients: 
   (Intercept)      PixelsCorn  PixelsSoybeans  
       50.9676          0.3286         -0.1337  
---
Random effects

Model: ~1| CountyName 
           (Intercept)  Residual
Std. Dev.  11.00        11.72   
---
Number of Observations:  36 
Number of Areas:  12 

IMPORTANT. Failure of convergence

If the algorithm did not converge, see Appendix.

Inferential statistics for the object mlfit are computed by the summary() method.

> summary(mlfit)
ESTIMATION SUMMARY
Method: Maximum likelihood estimation 
---
Fixed effects
                  Value Std.Error  t-value df  p-value    
(Intercept)    50.96756  23.47509  2.17113 22   0.0410 *  
PixelsCorn      0.32858   0.04798  6.84772 22 7.05e-07 ***
PixelsSoybeans -0.13371   0.05306 -2.51984 22   0.0195 *  
---
Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1

Function coef() extracts the estimated coefficients from a fitted model.

  • By default, function coef() is called with argument type = "both", which implies that the fixed effects and the random effect variances are returned.
  • Calling the function with type = "ranef" or type = "fixef" returns the random effect variances or the fixed effects, respectively.

Function convergence() can be useful if the algorithm did not converge; see Appendix.

Good to know. When the mixed linear model is not appropriate

Suppose that our data do not have area-specific variation. If we nevertheless fit the basic unit-level model to the data, the output looks as follows.

ESTIMATES OF SAE-MODEL (model type B) 
Method:  Maximum likelihood estimation 
---
Fixed effects
Model: y ~ (Intercept) + x 

Coefficients: 
(Intercept)            x  
      1.080        1.034  
---
Random effects

Model: ~1| areaid 
---
NOTE THAT THE VARIANCE OF THE AREA-LEVEL RANDOM
EFFECT IS ALMOST ZERO! DO YOU REALLY NEED THE
RANDOM EFFECT? IF SO, GO AHEAD. HOWEVER, YOU
SHOULD CONSIDER FITTING A (ROBUST) GLS MODEL.
---
           (Intercept)  Residual
Std. Dev.  0.0000       0.9552  
---
Number of Observations:  200 
Number of Areas:  10 
The report indicates that the random-effect variance is close to zero or equal to zero. Thus, it is more appropriate to use a linear regression model instead of the basic unit-level model.

4.2 Huber-type M-estimation

The Huber-type M-estimator is appropriate for situations where the response variable is supposed to be (moderately) contaminated by outliers. The M-estimator downweights residual outliers, but it does not limit the effect of high-leverage observations.

The Huber-type M-estimator of bhfmodel is

> huberfit <- fitsaemodel("huberm", bhfmodel, k = 1.5)

where k is the robustness tuning constant of the Huber \(\psi\)-function (\(0<k < \infty\)). On print, we have

> huberfit
ESTIMATES OF SAE-MODEL (model type B) 
Method:  Huber-type M-estimation 
Robustness tuning constant: k = 1.5 
---
Fixed effects
Model: HACorn ~ (Intercept) + PixelsCorn + PixelsSoybeans 

Coefficients: 
   (Intercept)      PixelsCorn  PixelsSoybeans  
       50.2849          0.3285         -0.1392  
---
Random effects

Model: ~1| CountyName 
           (Intercept)  Residual
Std. Dev.  11.95        12.36   
---
Number of Observations:  36 
Number of Areas:  12 

Good to know. Selection of robustness tuning constant

In the simple location-scale model, the tuning constant k = 1.345 defines an M-estimator of location that has an asymptotic relative efficiency w.r.t. the ML estimate of approx. 95% at the Gaussian core model. This property does not directly carry over to robust estimators of mixed-linear models. Therefore, we should not blindly select k = 1.345.

If the algorithm did not converge, see paragraph safe mode (below) and Appendix. Inferential statistics for huberfit are computed by the summary() method.

> summary(huberfit)
ESTIMATION SUMMARY
Method: Huber-type M-estimation 
Robustness tuning constant: k = 1.5 
---
Fixed effects
                  Value Std.Error  t-value df  p-value    
(Intercept)    50.28489  24.84651  2.02382 22   0.0553 .  
PixelsCorn      0.32845   0.05077  6.46906 22 1.65e-06 ***
PixelsSoybeans -0.13916   0.05618 -2.47711 22   0.0214 *  
---
Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
---
Degree of downweighting/winsorization:

                 sum(wgt)/n
fixeff           0.9841    
residual var     0.9723    
area raneff var  0.9841    

The output is separated into 2 blocks. The first block shows inferential statistics of the estimated fixed effects. The second block reports the degree of downweighting that is applied to outlying residuals at the final iteration (by estimating equations, EE, separately). The more the value of “sum(wgt)/n” deviates from 1.0, the more downweighting has been applied.

The methods coef() and convergence() are also available.

Safe mode

In the safe mode, the algorithm is initialized by a high-breakdown-point regression estimator. Note. In order to use the safe mode, the robustbase package of Maechler et al. (2021) must be installed.

The safe mode is entered by specifying one the following initialization methods:

in the call of fitsaemodel(). The safe mode uses a couple of internal tests to check whether the estimates at consecutive iterations behave well. Notably, it tries to detect cycles in the sequence iteratively refined estimates; see Schoch (2012).

5 (Robust) prediction of the area-level means

The package implements the following methods to predict the area-level means:

Good to know. Robust prediction method

The implemented robust prediction method is different from the method of Sinha and Rao (2009), who proposed to solve the robustified mixed model equations Fellner (1986) by a Newton-Raphson-type updating scheme that is obtained from a Taylor-series expansion of the robustified mixed model equations.

EBLUP and robust predictions are computed by

> robpredict(fit, areameans = NULL, k = NULL, reps = NULL, progress_bar = TRUE)

where

Good to know. Robust prediction

The robustness-tuning constant k does not necessarily have to be the same as the one used in fitsaemodel().

If areameans = NULL, the prediction is based on the same data that have been used in estimating the model parameters (i.e., within-sample prediction). This is rarely used in SAE.

In the landsat data, the county-specific population means of pixels of the segments under corn and soybeans are recorded in the variables MeanPixelsCorn and MeanPixelsSoybeans, respectively. Each sample segment in a particular county is assigned the county-specific means. Therefore, the population mean of the variables MeanPixelsCorn and MeanPixelsSoybeans occurs \(n_i\) times. The unique county-specific population means are obtained using

> dat <- unique(landsat[-33, c("MeanPixelsCorn", "MeanPixelsSoybeans", "CountyName")])
> dat <- cbind(rep(1,12), dat)
> rownames(dat) <- dat$CountyName
> dat <- dat[,1:3]
> dat
            rep(1, 12) MeanPixelsCorn MeanPixelsSoybeans
Cerro Gordo          1         295.29             189.70
Hamilton             1         300.40             196.65
Worth                1         289.60             205.28
Humboldt             1         290.74             220.22
Franklin             1         318.21             188.06
Pocahontas           1         257.17             247.13
Winnebago            1         291.77             185.37
Wright               1         301.26             221.36
Webster              1         262.17             247.09
Hancock              1         314.28             198.66
Kossuth              1         298.65             204.61
Hardin               1         325.99             177.05

The first column of dat is a dummy variable (because bhfmodel has a regression intercept). The second and third column represent, respectively, the county-specific population means of segments under corn and soybeans.

Consider the ML estimate, mlfit, of the bhfmodel model. The EBLUP of the area-level means is computed by

> pred <- robpredict(mlfit, areameans = dat)
> pred
Robustly Estimated/Predicted Area-Level Means:
             raneff   fixeff   area mean
Cerro Gordo   -0.348  122.629  122.281  
Hamilton       2.731  123.379  126.110  
Worth        -11.522  118.677  107.154  
Humboldt      -8.313  117.053  108.741  
Franklin      13.641  130.380  144.021  
Pocahontas     9.529  102.425  111.954  
Winnebago     -9.043  122.052  113.009  
Wright         1.648  120.358  122.006  
Webster       11.082  104.073  115.155  
Hancock       -3.229  127.671  124.442  
Kossuth      -14.621  121.740  107.119  
Hardin         8.445  134.408  142.853  

because (by default) k = NULL . By explicitly specifying k in the call of robpredict(), we can—in principle—compute robust predictions for the ML estimate instead of the EBLUP.

Consider the Huber M-estimate huberfit (with tuning constant k = 1.5, see call of above). If k is not specified in the call of robpredict(), robust predictions are computed with \(k\) equal to 1.5; otherwise, the robust predictions are based on the value of k in the call of robpredict().

Object pred is a list with slots "fixeff", "raneff", "means", "mspe", etc. For instance, the predicted means can be extracted by pred$means or pred[["means"]].

A plot() function is available to display the predicted means.

Function residuals() computes the residuals.

6 Mean square prediction error

Function robpredict() can be used to compute bootstrap estimates of the mean squared prediction errors (MSPE) of the predicted area-level means; see Sinha and Rao (2009). To compute the MSPE, we must specify the number of bootstrap replicates (reps). If reps = NULL, the MSPE is not computed.

Consider (for instance) the ML estimate. EBLUP and MSPE of the EBLUP based on 100 bootstrap replicates are computed by

> pred <- robpredict(mlfit, areameans = dat, reps = 100,
+                    progress_bar = FALSE)
> pred
Robustly Estimated/Predicted Area-Level Means:
             raneff   fixeff   area mean  MSPE   
Cerro Gordo   -0.348  122.629  122.281     82.418
Hamilton       2.731  123.379  126.110     99.031
Worth        -11.522  118.677  107.154     60.627
Humboldt      -8.313  117.053  108.741     64.231
Franklin      13.641  130.380  144.021     39.708
Pocahontas     9.529  102.425  111.954     39.070
Winnebago     -9.043  122.052  113.009     43.537
Wright         1.648  120.358  122.006     42.533
Webster       11.082  104.073  115.155     32.976
Hancock       -3.229  127.671  124.442     32.567
Kossuth      -14.621  121.740  107.119     28.018
Hardin         8.445  134.408  142.853     20.681
(MSPE: 100 boostrap replicates)

The number of reps = 100 is kept small for illustration purposes; in practice, we should choose larger values. The progress bar has been disabled as it is not suitable for the automatic vignette generation.

A visual display of the predicted area-level means obtains by plot(pred, type = "l", sort = "means").

References

COPT, S. and M.-P. VICTORIA-FESER (2009). Robust prediction in mixed linear models, Tech. rep., University of Geneva.

BATTESE, G. E., R. M. HARTER and W. A. FULLER (1988). An error component model for prediction of county crop areas using, Journal of the American Statistical Association 83, 28–36. DOI: 10.2307/2288915

FELLNER, W. H. (1986). Robust estimation of variance components, Technometrics 28, 51–60. DOI: 10.1080/00401706.1986.10488097

HERITIER, S., E. CANTONI, S. COPT, and M.-P. VICTORIA-FESER (2009). Robust Methods in Biostatistics, New York: John Wiley & Sons.

MAECHLER, M., P. J. ROUSSEEUW, C. CROUX, V. TODOROC, A. RUCKSTUHL, M. SALIBIAN-BARRERA, T. VERBEKE, M. KOLLER, M. KOLLER, E. L. T. CONCEICAO and M. A. DI PALMA (2021). robustbase: Basic Robust Statistics. R package version 0.93-9. URL: CRAN.R-project.org/package=robustbase.

RAO, J.N.K. (2003). Small Area Estimation, New York: John Wiley and Sons.

RICHARDSON, A. M. and A. H. WELSH (1995). Robust Restricted Maximum Likelihood in Mixed Linear Models, Biometrics 51, 1429–1439. DOI: 10.2307/2533273

ROUSSEEUW, P. J. (1984). Least Median of Squares Regression, Journal of the American Statistical Association 79, 871–880. DOI: 10.2307/2288718

ROUSSEEUW, P. J. and K. VAN DRIESSEN (2006). Computing LTS Regression for Large Data Sets, Data Mining and Knowledge Discovery 12, 29–45. DOI: 10.1007/s10618-005-0024-4

ROUSSEEUW, P. J. and V. YOHAI (1984). Robust Regression by Means of S Estimators, in Robust and Nonlinear Time Series Analysis, ed. by FRANKE, J., W. HÄRDLE AND R. D. MARTIN, New York: Springer, 256–274.

SALIBIAN-BARRERA, M. and V. J. YOHAI (2006). A Fast Algorithm for S-Regression Estimates, Journal of Computational and Graphical Statistics 15, 414–427. DOI: 10.1198/106186006x113629

SCHOCH, T. (2012). Robust Unit-Level Small Area Estimation: A Fast Algorithm for Large Datasets. Austrian Journal of Statistics 41, 243–265. URL: www.stat.tugraz.at/AJS/ausg124/124Schoch.pdf

SINHA, S.K. and J.N.K. RAO (2009). Robust small area estimation. Canadian Journal of Statistics 37, 381–399. DOI: 10.1002/cjs.10029

Appendix

A Failure of convergence

Suppose that we computed

> est <- fitsaemodel("ml", bhfmodel, niter = 3)

The algorithm did not converge and we get the following output

> est
THE ALGORITHM DID NOT CONVERGE!
---
 1) use convergence() of your fitted model to learn more
 2) study the documentation using the command ?fitsaemodel
 3) you may call fitsaemodel with 'init' equal to (either) 'lts'
    or 's' (this works also for ML, though it may no be very efficient)
 4) if it still does not converge, the last resort is to modify
   'acc' and/or 'niter'

ESTIMATES OF SAE-MODEL (model type B) 
Method:  Maximum likelihood estimation 
---
Fixed effects
Model: HACorn ~ (Intercept) + PixelsCorn + PixelsSoybeans 

Coefficients: 
   (Intercept)      PixelsCorn  PixelsSoybeans  
            NA              NA              NA  
---
Random effects

Model: ~1| CountyName 
           (Intercept)  Residual
Std. Dev.  NA           NA      
---
Number of Observations:  36 
Number of Areas:  12 

To learn more, we call convergence(est) and get

> convergence(est)
CONVERGENCE REPORT
NOTE: ALGORITHM DID NOT CONVERGE!
---
User specified number of iterations (niter) and
numeric precision (acc):

                niter   acc
overall loop        3 1e-05
fixeff            200 1e-05
residual var      200 1e-05
area raneff var   100 1e-05
---
Number of EE-specific iterations in each call
(given the user-defined specs), reported for
each of the3overall iterations:

  fixeff residual var area raneff var
1      2            2              18
2      2            2              11
3      2            2              12

Clearly, we have deliberately set the number of (overall or outer loop) iterations equal to niter = 3 to illustrate the behavior; see also “niter = 3” on the line “overall loop” in the above table. As a consequence, the algorithm failed to converge.

The maximum number of iterations for the fixed effects (“fixeff”) is 200, for the residual variance estimator (“residual var”) is 200, for the area-level random effect variance is (“area raneff var”) is 100. The default values can be modified; see documentation of fitsaemodel.control().

The last table in the above output shows the number of iterations that the algorithm required for the niter = 3 overall loop iteration (i.e., in the first loop, we have fixef = 2, residual var = 2 and area raneff var = 18 iterations). From this table we can learn how to adjust the default values in case the algorithm does not converge.