Comparing Small Area Techniques for Estimating Poverty Measures: the Case Study of Austria and Spain
DOI:
https://doi.org/10.17059/2016-2-6Ключевые слова:
small area estimation, poverty, EU “headline targets”, regional level, NUTS-2, inequality, SEBLUP, cumulation, SILC, Austria, SpainАннотация
The Europe 2020 Strategy has formulated key policy objectives or so-called “headline targets” which the European Union as a whole and Member States are individually committed to achieving by 2020. One of the five headline targets is directly related to the key quality aspects of life, namely social inclusion; within these targets, the European Union Statistics on Income and Living Condition (EU-SILC) headline indicators atrisk-of-poverty or social exclusion and its components will be included in the budgeting of structural funds, one of the main instruments through which policy targets are attained. For this purpose, Directorate-General Regional Policy of the European Commission is aiming to use sub-national/regional level data (NUTS 2). Starting from this, the focus of the present paper is on the “regional dimension” of well-being. We propose to adopt a methodology based on the Empirical Best Linear Unbiased Predictor (EBLUP) with an extension to the spatial dimension (SEBLUP); moreover, we compare this small area technique with the cumulation method. The application is conducted on the basis of EU-SILC data from Austria and Spain. Results report that, in general, estimates computed with the cumulation method show standard errors which are smaller than those computed with EBLUP or SEBLUP. The gain of pooling SILC data over three years is, therefore, relevant, and may allow researchers to prefer this method.Библиографические ссылки
Atkinson, A., Cantillon, B., Marlier, E. & Nolan, B. (2002). Social Indicators: The EU and Social Inclusion. Oxford: Oxford University Press, 24.
Foster, J. E., Greer, J. & Thorbecke E. (1984). A Class of Decomposable Poverty Measures. Econometrica, 52, 716-766.
Handerson, C. R. (1950). Estimation of Genetic Parameters. Annals of Mathematical Statistics, 21, 309-310.
Gosh, M. & Rao, J. N. K. (1994). Small Area Estimation: An Appraisal (with discussion). Statistical Science, 9(1), 55-93.
Rao, J. N. K. (2003). Small Area Estimation. Wiley, London, 24.
Betti, G., Gagliardi, F., Lemmi, A. & Verma, V. (2012). Sub-national Indicators of Poverty and Deprivation in Europe: Methodology and Applications. Cambridge Journal of Regions, Economy and Society, 5(1), 149-162.
Fay, R. E. & Herriot, R. A. (1979). Estimates of Income for Small Places: An Application of James-Stein Procedures to Census Data. Journal of the American Statistical Association, 74, 269-277.
Battese, G. E., Harter, R. M. & Fuller, W. A. (1988). An Error-components Models for Prediction of County Crop Areas Using Survey and Satellite Data. Journal of the American Statistical Association, 83, 1-27.
Elbers, C., Lanjouw, J. O. & Lanjouw, P. (2003). Micro-level Estimation of Poverty and Inequality. Econometrica, 71, 335-364.
O'Muircheataigh, C. & Pedlow, S. (2002). Combining Samples vs. Cumulating Cases: A Comparison of Two Weighting Strategies in NLS97. American Statistical Association. Proceedings of the Joint Statistical Meetings, 2557-2562.
Wells, J. E. (1998). Oversampling Through Households or Other Clusters: Comparison of Methods for Weighting the Oversample Elements. Australian and New Zeeland Journal of Statistics, 40, 269-277.
Lohr, S. L. & Rao, J. N. K. (2000). Inference from Dual Frame Durveys. Journal of American Statistical Association, 95, 271-280.
Verma, V., Gagliardi, F. & Ferretti, C. (2013). Cumulation of Poverty Measures to Meet New Policy Needs. Advances in Theoretical and Applied Statistics. Torelli, N. and Pesarin, F.; Bar-Hen, Avner (Eds.). XIX, Springer.
Verma, V., Betti, G. (2011). Taylor Linearization Sampling Errors and Design Effects for Poverty Measures and Other Complex Statistics. Journal of Applied Statistics, 38(8), 1549-1576.
Verma, V., Betti, G. & Gagliardi, F. (2010). An Assessment of Survey Errors in EU-SILC. Eurostat Methodologies and Working Papers. Eurostat, Luxembourg.
Pratesi, M. & Salvati, N. (2007). Small Area Estimation: The EBLUP Model Based on Spatially Correlated Random Effects. Statistical Methods and Applications, 17(1), 113-141.
Verma, V. (2004). Sampling Errors and Design Effects for Poverty Measures and Other Complex Statistics. Proceedings of the VII International Meeting Quantitative Methods for Applied Sciences: Sampling Designs for Environmental, Economic and Social Surveys: Theoretical and Practical Perspectives. Siena.
Cressie, N. (1993). Statistics for Spatial Data. New York: Wiley, 34.
Cliff, A. & Ord, J. K. (1981). Spatial Processes. Models and Applications. London: Pion, 54.
Banerjee, S., Carlin, B. P. & Gelfand, A. E. (2004). Hierarchical Modeling and Analysis for Spatial Data. Chapman & Hall, New York, 78.
Bivand, R. S., Rubio, V. G. & Pebesma, E. J. (2008). Spatial Analysis with R. Use R!. New York: Springer, 121.
Molina, I., Salvati, N. & Pratesi, M. (2009). Bootsrap for Estimating the MSE of the Spatial EBLUP. Computational Statistics, 85, 163-171.
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Copyright (c) 2016 Federico Crescenzi, Gianni Betti, Francesca Gagliardi
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