Degree-Day Climatology over Central and Southeast Europe for the Period 1961-2018 – Evaluation in High Resolution

1. Alexander, L.V., et al. Global Observed Changes in Daily Climate Extremes of Temperature and Precipitation. – J. Geophys. Res., Vol. 111, 2006, No D5. DOI: 10.1029/2005jd006290.10.1029/2005JD006290Search in Google Scholar

2. Alexandrov, V., M. Schneider, E. Koleva, J.-M. Moisselin. Climate Variability and Change in Bulgaria during the 20th Century. – Theor. Appl. Climatol., Vol. 79, 2004, pp. 133-149. https://doi.org/10.1007/s00704-004-0073-410.1007/s00704-004-0073-4Search in Google Scholar

3. Bartholy, J., R. Pongrácz. Comparing Tendencies of Some Temperature Related Extreme Indices on Globaland Regional Scales. IDŐJÁRÁS, Vol. 110, 2006, pp. 35-48.Search in Google Scholar

4. Bazile, E., R. Abida, A. Verelle, P. Le Moigne, C. Szczypta. MESCAN-SURFEX Surface Analysis. Deliverable D2.8 of the UERRA Project. 2017. http://www.uerra.eu/publications/deliverable-reports.htmlSearch in Google Scholar

5. Belda, M., P. Skalák, A. Farda et al. CECILIA Regional Climate Simulations for Future Climate: Analysis of Climate Change Signal. – Advances in Meteorology, Vol. 2015, 2015, Article ID 354727. 13 p. https://doi.org/10.1155/2015/35472710.1155/2015/354727Search in Google Scholar

6. Birsan, M.-V., A. Dumitrescu, D. M. Micu, S. Cheval. Changes in Annual Temperature Extremes in the Carpathians since AD 1961. – Nat. Hazards, Vol. 74, 2014, No 3, pp. 1899-1910. https://doi.org/10.1007/s11069-014-1290-510.1007/s11069-014-1290-5Search in Google Scholar

7. Buyukalaca, O., H. Bulut, T. Yılmaz. Analysis of Variable-Base Heating and Cooling Degree-Days for Turkey Applied Energy 69. 2001, pp. 269-283.10.1016/S0306-2619(01)00017-4Search in Google Scholar

8. Chervenkov, H., K. Slavov. Theil-Sen Estimator vs. Ordinary Least Squares – Trend Analysis for Selected ETCCDI Climate Indices. – Compt. Rend. Acad. bulg. Sci., Vol. 72, 2019, No 1, pp. 47-54. https://doi.org/10.7546/CRABS.2019.01.0610.7546/CRABS.2019.01.06Search in Google Scholar

9. Chervenkov, H., K. Slavov. STARDEX and ETCCDI Climate Indices Based on E-OBS and CARPATCLIM. Part Two: ClimData in Use. – In: G. Nikolov et al., Eds. NMA 2018, LNCS 11189, 2019, pp. 368-374. DOI: 10.1007/978-3-030-10692-8 41.10.1007/978-3-030-10692-8Search in Google Scholar

10. Chervenkov, H., K. Slavov. Historical Climate Assessment of Temperature-Based ETCCDI Climate Indices Derived from CMIP5 Simulations. – Compt. rend. Acad. bulg. Sci., Vol. 73, 2020, No 6, pp. 784-790. https://doi.org/10.7546/CRABS.2020.06.0510.7546/CRABS.2020.06.05Search in Google Scholar

11. Chervenkov, H., K. Slavov. ETCCDI Climate Indices for Assessment of the Recent Climate over Southeast Europe. – In: I. Dimov, S. Fidanova, Eds. Advances in High Performance Computing. HPC 2019. Studies in Computational Intelligence. Vol. 902. 2021, Cham, Springer. https://doi.org/10.1007/978-3-030-55347-0_3410.1007/978-3-030-55347-0_34Search in Google Scholar

12. Chervenkov, H., K. Slavov. Geo-Statistical Comparison of UERRA MESCAN-SURFEX Daily Temperatures Against Independent Data Sets. – IDŐJÁRÁS XXX (X) XX–XX (in Press).Search in Google Scholar

13. Chervenkov, H., K. Slavov. Assessment of Agro-Meteorological Indices over Southeast Europe in the Context of Climate Change (1961-2018). – IDŐJÁRÁS XXX (X) XX–XX (in Press).Search in Google Scholar

14. Cheval, S., M.-V. Birsan, A. Dumitrescu. Climate Variability in the Carpathian Mountains Region over 1961-2010. – Global and Planetary Change, Vol. 118, 2014, pp. 85-96. https://doi.org/10.1016/j.gloplacha.2014.04.00510.1016/j.gloplacha.2014.04.005Search in Google Scholar

15. CIBSE, Degree-Days: Theory and Application. Technical Manual 41. Chartered Institution of Building Services Engineers: London, UK. 2006. ISBN-10: 1-903287-76-6. http://www.degreedaysforfree.co.uk/pdf/tm41.pdfSearch in Google Scholar

16. Croitoru, A.-E., I.-H. Holobaca, C. Lazar, F. Moldovan, A. Imbroane. Air Temperature Trend and the Impact on Winter Wheat Phenology in RomaniaClimatic Change. Vol. 111, 2012, pp. 393-410. https://doi.org/10.1007/s10584-011-0133-610.1007/s10584-011-0133-6Search in Google Scholar

17. Dumitrescu, A., M. V. Birsan. ROCADA: A Gridded Daily Climatic Dataset over Romania (1961–2013) for Nine Meteorological Variables. – Nat. Hazards, Vol. 78, 2015, No 2, pp. 1045-1063. https://doi.org/10.1007/s11069-015-1757-z10.1007/s11069-015-1757-zSearch in Google Scholar

18. European Environment Agency, Heating and Cooling Degree Days, 2019. https://www.eea.europa.eu/data-and-maps/indicators/heating-degree-days-2/assessmentSearch in Google Scholar

19. Gadzhev, G., I. Georgieva, K. Ganev, V. Ivanov, N. Miloshev, H. Chervenkov, D. Syrakov. Climate Applications in a Virtual Research Environment Platform. – Scalable Computing: Practice and Experience, Vol. 19, 2018, No 2, pp. 107-118. DOI 10.12694/scpe.v19i2.1347, ISSN: 1895-1767.10.12694/scpe.v19i2.1347Search in Google Scholar

20. Gadzhev, G., V. Ivanov, R. Valcheva, K. Ganev, H. Chervenkov. HPC Simulations of the Present and Projected Future Climate of the Balkan Region. – In: I. Dimov, S. Fidanova, Eds. Advances in High Performance Computing. HPC 2019. Studies in Computational Intelligence. Vol. 902. 2021, Cham, Springer. https://doi.org/10.1007/978-3-030-55347-0_2010.1007/978-3-030-55347-0_20Search in Google Scholar

21. Janković, A., Z. Podraščanin, V. Djurdjevic. Future Climate Change Impacts on Residential Heating and Cooling Degree Days in Serbia. – IDŐJÁRÁS Quarterly Journal of the Hungarian Meteorological Service, Vol. 123, July – September 2019, No 3, pp. 351-370.10.28974/idojaras.2019.3.6Search in Google Scholar

22. Lakatos, M., T. Szentimrey, Z. Bihari, S. Szalai. Investigation of Climate Extremes in the Carpathian Region on Harmonized Data. – In: Int. Scient. Conf. on Environmental Changes and Adaptation Strategies, September 2013, Temperature Thresholds and Crop Production: A Review.Search in Google Scholar

23. Pongrácz, R., J. Bartholy, G. Gelybó, P. Szabó. Detected and Expected Trends of Extreme Climate Indices for the Carpathian Basin. – In: K. Střelcová et al., Eds. Bioclimatology and Natural Hazards. Springer, Dordrecht, 2009. https://doi.org/10.1007/978-1-4020-8876-6_210.1007/978-1-4020-8876-6_2Search in Google Scholar

24. Pongrácz, R., J. Bartholy, P. Szabo, G. Gelybó. A Comparison of the Observed Trends and Simulated Changes in Extreme Climate Indices in the Carpathian Basin by the End of This Century. – Int. J. Global Warming, Vol. 1, 2009, Nos. 1/2/3, pp. 336-355. https://doi.org/10.1504/IJGW.2009.02709710.1504/IJGW.2009.027097Search in Google Scholar

25. Ridal, M., S. Schimanke, S. Hopsch. Documentation of the RRA System: UERRA, Deliverable D322 Lot1.1.1.2 in the Scope of the Copernicus Service C3S 322 Lot1, 2018, Available via Copernicus.Search in Google Scholar

26. Sillmann, J., E. Röckner. Climatic Change, Vol. 86, 2008, No 83. 10.1007/s10584-007-9308-6.10.1007/s10584-007-9308-6Search in Google Scholar

27. Soci, C., E. Bazile, F. Besson, T. Landelius. High-Resolution Precipitation Re-Analysis System for Climatological Purposes. – Tellus A: Dyn. Meteorology & Oceanography, Vol. 68, 2016, No 1. https://doi.org/10.3402/tellusa.v68.2987910.3402/tellusa.v68.29879Search in Google Scholar

28. Spinoni, J., J. Vogt, P. Barbosa. European Degree-Day Climatologies and Trends for the Period 1951-2011. – Int. J. Climatol., Vol. 35, 2015, pp. 25-36. DOI:10.1002/joc.3959.10.1002/joc.3959Search in Google Scholar

29. Spinoni, J., J. V. Vogt, P. Barbosa, A. Dosio, N. McCormick, A. Bigano, H. M. Füssel. Changes of Heating and Cooling Degree-Days in Europe from 1981 to 2100. – Int. J. Climatol, Vol. 38, 2018, pp. e191-e208. DOI:10.1002/joc.5362.10.1002/joc.5362Search in Google Scholar

30. Unden, P. UERRA: Final Report, Project No: 607193, 2018. Period Number: 3rd Ref: 607193 UERRA Final Report-13 20180319 112103 CET.pdfSearch in Google Scholar