Institute of public finance
Public Sector Economics conference
Call for papers
LOGIN / REGISTER
CELEBRATING Celebrating 50
Public Sector Economics
CURRENT ISSUE
PAST ISSUES
ABOUT PSE
FOR AUTHORS
ETHICAL GUIDELINES
CONTACT
Print page
Search box

413
Views



95
Downloads

Inflation in Croatia: a new era of forecasting with machine learning



Jakov Čorak*
   
Mihael Brusan*
Article   |   Year:  2026   |   Pages:  39 - 65   |   Volume:  50   |   Issue:  1
Received:  June 1, 2025   |   Accepted:  October 14, 2025   |   Published online:  March 18, 2026
Download citation        https://doi.org/10.3326/pse.50.1.3       


  1. Ang, A., Bekaert, G. and Wei, M., 2005. Do macro variables, asset markets, or surveys forecast inflation better? Journal of Monetary Economics, 54(4), pp. 1163-1212 [CrossRef]

  2. Araujo, G. S. and Gaglianone, W. P., 2023. Machine learning methods for inflation forecasting in Brazil: new contenders versus classical models. Latin American Journal of Central Banking, 4(2), 100087 [CrossRef]

  3. Atkeson, A. and Ohanian, L. E., 2001. Are Phillips curves useful for forecasting inflation? Federal Reserve Bank of Minneapolis Quarterly Review, 25(1), pp. 2-11 [CrossRef]

  4. Barhoumi, K., Darné, O. and Ferrara, L., 2009. Are disaggregate data useful for factor analysis in forecasting French GDP? Journal of Forecasting, 29(1-2), pp. 132-144 [CrossRef]

  5. Blinder, A. S., 1997. Is there a core of practical macroeconomics that we should all believe? The American Economic Review, 87(2), pp. 240-243.

  6. Breiman, L., 1996. Bagging predictors. Machine Learning, 24(2), pp. 123-140 [CrossRef]

  7. Breiman, L., 2001. Random forests. Machine Learning, 45(1), pp. 5-32 [CrossRef]

  8. Cebrián, E. and Domenech, J., 2024. Addressing Google Trends inconsistencies. Technological Forecasting and Social Change, 202, p. 123318 [CrossRef]

  9. Chen, T. and Guestrin, C., 2016. XGBoost: a scalable tree boosting system. In: Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining. New York: Association for Computing Machinery, pp. 785-794 [CrossRef]

  10. Chen, Y.-C., Turnovsky, S. J. and Zivot, E., 2014. Forecasting inflation using commodity price aggregates. Journal of Econometrics, 183(1), pp. 117-134 [CrossRef]

  11. Choi, H. and Varian, H., 2012. Predicting the present with Google Trends. Economic Record, 88(s1), pp. 2–9 [CrossRef]

  12. Drucker, H. [et al.], 1997. Support vector regression machines. Advances in Neural Information Processing Systems, 28, pp. 779-784.

  13. Eickmeier, S. and Ziegler, C., 2008. How successful are dynamic factor models at forecasting output and inflation? A meta‐analytic approach. Journal of Forecasting, 27(3), pp. 237-265 [CrossRef]

  14. Forni, M. [et al.], 2003. Do financial variables help forecasting inflation and real activity in the euro area? Journal of Monetary Economics, 50(6), pp. 1243-1255 [CrossRef]

  15. Friedman, J. H., 2001. Greedy function approximation: a gradient boosting machine. The Annals of Statistics, 29(5), pp. 1189-1232 [CrossRef]

  16. Garcia, M. G. P., Medeiros, M. C. and Vasconcelos, G. F. R., 2017. Real-time inflation forecasting with high-dimensional models: the case of Brazil. International Journal of Forecasting, 33(3), pp. 679-693 [CrossRef]

  17. Globan, T., Arčabić, V. and Sorić, P., 2015. Inflation in new EU member states: a domestically or externally driven phenomenon? Emerging Markets Finance and Trade, 52(1), pp. 154-168 [CrossRef]

  18. Groen, J. J. J., Paap, R. and Ravazzolo, F., 2013. Real-time inflation forecasting in a changing world. Journal of Business and Economic Statistics, 31(1), pp. 29-44 [CrossRef]

  19. Hoerl, A.E. and Kennard, R.W., 1970. Ridge regression: applications to nonorthogonal problems. Technometrics, 12(1), pp. 69-82 [CrossRef]

  20. Hyndman, R. J. and Athanasopoulos, G., 2021. Forecasting: principles and practice. 3rd ed. Melbourne: OTexts. 

  21. Hyndman, R. J. and Koehler, A. B., 2006. Another look at measures of forecast accuracy. International Journal of Forecasting, 22(4), pp. 679-688 [CrossRef]

  22. Ivașcu, C., 2023. Can machine learning models predict inflation? Proceedings of the International Conference on Business Excellence, 17(1), pp. 1748-1756 [CrossRef]

  23. Ke, G. [et al.], 2017. LightGBM: a highly efficient gradient boosting decision tree. In: Proceedings of the 31st International Conference on Neural Information Processing Systems (NIPS’17). Red Hook, NY: Curran Associates Inc., pp. 3149-3157.

  24. Kunovac, D., 2007. Factor model forecasting of inflation in Croatia. Financial Theory and Practice, 31(4), pp. 371-393.

  25. Masini, R. P., Medeiros, M. C. and Mendes, E. F., 2021. Machine learning advances for time series forecasting. Journal of Economic Surveys, 37(1), pp. 76-111 [CrossRef]

  26. Medeiros, M. C. [et al.], 2021. Forecasting inflation in a data-rich environment: the benefits of machine learning methods. Journal of Business and Economic Statistics, 39(1), pp. 98-119 [CrossRef]

  27. Medeiros, M. C. and Mendes, E. F., 2016. ℓ1-regularization of high-dimensional time-series models with non-Gaussian and heteroskedastic errors. Journal of Econometrics, 191(1), pp. 255-271 [CrossRef]

  28. Monteforte, L. and Moretti, G., 2013. Real‐time forecasts of inflation: the role of financial variables. Journal of Forecasting, 32(1), pp. 51-61[CrossRef]

  29. Naghi, A. A., O’Neill, E. and Zaharieva, M. D., 2024. The benefits of forecasting inflation with machine learning: new evidence. Journal of Applied Econometrics, 39(7), pp. 1321-1331 [CrossRef]

  30. Nakamura, E., 2004. Inflation forecasting using a neural network. Economics Letters, 86(3), pp. 373-378 [CrossRef]

  31. Payne, J. E., 2002. Inflationary dynamics of a transition economy: the Croatian experience. Journal of Policy Modeling, 24(3), pp. 219-230 [CrossRef]

  32. Pufnik, A. and Kunovac, D., 2006. Short-term inflation forecasting in Croatia using seasonal ARIMA processes. Istraživanja, I-18

  33. Rumelhart, D. E., Hinton, G. E. and Williams, R. J., 1986. Learning representations by back-propagating errors. Nature, 323(6088), pp. 533-536 [CrossRef]

  34. Scornet, E., Biau, G. and Vert, J.-P., 2015. Consistency of random forests. The Annals of Statistics, 43(4), pp. 1716-1741 [CrossRef]

  35. Sorić, P. and Lolić, I., 2017. Economic uncertainty and its impact on the Croatian economy. Public Sector Economics, 41(4), pp. 443-477 [CrossRef]

  36. Stock, J. H. and Watson, M., 2003. Forecasting output and inflation: the role of asset prices. Journal of Economic Literature, 41(3), pp. 788-829 [CrossRef]

  37. Taylor, S. J. and Letham, B., 2018. Forecasting at scale. The American Statistician, 72(1), pp. 37-45 [CrossRef]

  38. Tibshirani, R., 1996. Regression shrinkage and selection via the lasso. Journal of the Royal Statistical Society Series B, 58(1), pp. 267-288.

  39. Ülke, V., Sahin, A. and Subasi, A., 2018. A comparison of time series and machine learning models for inflation forecasting: empirical evidence from the USA. Neural Computing and Applications, 30(5), pp. 1519–1527 [CrossRef]

  40. Zou, H. and Hastie, T., 2005. Regularization and variable selection via the elastic net. Journal of the Royal Statistical Society Series B (Statistical Methodology), 67(2), pp. 301–320 [CrossRef]

  41. Živko, I. and Bošnjak, M., 2017. Time series modeling of inflation and its volatility in Croatia. Notitia – časopis za ekonomske, poslovne i društvene teme, 3(1), pp. 1-10 [CrossRef]

   March, 2026
I/2026
In order to give you a better user experience, cookies have been stored on your computer.
Accept cookie     More information