An evaluation of soil retention potential as an important factor of water balance in the landscape

ANTAL, J. (1999): Applied agrohydrology. Nitra, VŠP.Search in Google Scholar

BEDRNA, Z. (2002): Environmental pedology. Bratislava, Veda.Search in Google Scholar

BLUM, W. E. H. (1990): The challenge of soil protection in Europe. Environmental conservation, 17(1): 72–74.10.1017/S037689290001732XSearch in Google Scholar

BOUMA, J. (1989): Using soil survey data for quantitative land evaluation. Advances in Soil Science, 9: 177–213.10.1007/978-1-4612-3532-3_4Search in Google Scholar

BRODOVÁ, M. (2008): Ohodnocovanie environmentálnych funkcií poľnohospodárskej pôdy. Ekonomika poľnohospodárstva, 8(4): 53–58.Search in Google Scholar

BUJNOVSKÝ, R., BALKOVIČ, J., BARANČÍKOVÁ, G., MAKOVNÍKOVÁ, J., VILČEK, J. (2009): Hodnotenie a oceňovanie ekologických funkcií poľnohospodárskych pôd Slovenska. Bratislava, VÚPOP.Search in Google Scholar

BUJNOVSKÝ, R., JURÁNI, B. (1999): Kvalita pôdy – jej vymedzenie a hodnotenie. Bratislava, VÚPOP.Search in Google Scholar

CORNELIS W. M., RONSYN, J., VAN MEIRVENNE, M., HARTMANN, R. (2001): Evaluation of pedotransfer functions for predicting the soil moisture retention curve. Soil Science Society of America Journal, 65(3): 638–648.10.2136/sssaj2001.653638xSearch in Google Scholar

DŽATKO, M. (2002): Hodnotenie produkčného potenciálu poľnohospodárskych pôd a pôdno-ekologických regiónov Slovenska. Bratislava, VÚPOP.Search in Google Scholar

EUROPEAN COMMISSION (2006): Proposal for a directive of the European Parliament and of the Council establishing a framework for the protection of soil and amending Directive 2004/35/EC.COM (2006) 232 final. European Commission, Brussels.Search in Google Scholar

GROSS, P. (1999): Regionálne geologické mapy Slovenska. Geologická mapa a vysvetlivky ku geologickej mape Popradskej kotliny, Hornádskej kotliny, Levočských vrchov, Spišsko-šarišského medzihoria, Bachurne a Šarišskej vrchoviny 1: 50,000 Bratislava, SGIDS.Search in Google Scholar

GUPTA, S. C., LARSON, W. E. (1979): Estimating soil water characteristic from particle size distribution, organic matter percent, and bulk density. Water Resources Research, 15: 1633–1635.10.1029/WR015i006p01633Search in Google Scholar

HACK-TEN BROEKE, M. J. D, HEGMANS, J. H. B. M. (1996): Use of soil physical characteristics from laboratory measurements or standard series for modelling unsaturated water flow. Agricultural Water Management 29: 201–213.10.1016/0378-3774(95)01190-0Search in Google Scholar

HOUŠKOVÁ, B. (2000): Retenčná kapacita poľnohospodárskych pôd Slovenska. Vedecké práce. Proceedings of Soil Science and Conservation Research Institute (pp. 72–78). Bratislava, VÚPOP.Search in Google Scholar

IMAM, B., SOROOSHIAN, S., MAYR, T., SCHAAP, M., WÖSTEN, J. H. M., SCHOLES, B. (1999): Comparison of pedotransfer functions to compute water holding capacity using the van Genuchten model in inorganic soils. Report to IGBP-DIS Soil Data Tasks, IGBP-DIS Working Paper 22, IGBP-DIS, Toulouse, Cédex.Search in Google Scholar

JURÁNI, B. (2005): Ochrana využívania pôdy a vplyv človeka. In: Štvrté pedologické dni (pp. 178–180). Bratislava, VÚPOP.Search in Google Scholar

KERN, J. S. (1995): Evaluation of soil water retention models based on basic soil physical properties. Soil Science Society of America Journal, 59: 1134–1141.10.2136/sssaj1995.03615995005900040027xSearch in Google Scholar

KRNÁČOVÁ, Z., KRNÁČ, Š. (1995): Application of exploratory factor analysis model to agro-ecological system study. International Journal for Ecological problems of the Biosphere. Ecology, 14(2): 123–140.Search in Google Scholar

KRNÁČOVÁ, Z. (2010): Special soil classification according to selected environmental functions for multifunctional evaluation of land use. In: Barančoková, M., Krajčí, J., Kollár, J., Belčáková, I. [eds.]: Landscape Ecology-methods, applications and interdisciplinary approach. (pp. 837–849). Bratislava, Institute of Landscape Ecology, Slovak Academy of Sciences.Search in Google Scholar

LAMORSKI, K., PACHEPSKY, Y., SLAWINSKI, C., WALCZAK, R. T. (2008): Using Support Vector Machines to Develop Pedotransfer Functions for Water Retention of Soils in Poland. Soil Science Society of America Journal, 72(5): 1243–1247.10.2136/sssaj2007.0280NSearch in Google Scholar

LINKEŠ, V., PESTÚN, V., DŽATKO, M. (1996): Príručka pre používanie máp bonitovaných pôdno-ekologických jednotiek. Bratislava, VUPÚ.Search in Google Scholar

LOVELAND, P. J., THOMPSON, T. R. E. (2002): Identification and development of set of national indicators for soil quality. R & D Project Record P5 – 053/PR/02. Bristol, Environment Agency.Search in Google Scholar

MIKLÓS, L. (2002): Atlas krajiny Slovenskej republiky (Landscape Atlas of the Slovak Republic). Ministry of Environment of the Slovak Republic, Slovak Agency of Environment, Banská Bystrica: 94.Search in Google Scholar

MINASNY, B., MCBRATNEY, A. B. (2002): The Neuro-m method for fitting neural network parametric pedotransfer functions. Soil Science Society of America Journal, 66: 352–361.10.2136/sssaj2002.1407aSearch in Google Scholar

MOJSES, M., PETROVIČ, F. (2013): Land use changes of historical structures in the agricultural landscape at the local level-Hriňová case study. Ekologia, 32(1): 1–12.10.2478/eko-2013-0001Search in Google Scholar

MUCHOVÁ, Z., LEITMANOVÁ, M., PETROVIČ, F. (2016): Possibilities of optimal land use as a consequence of lessons learned from land consolidation projects (Slovakia). Ecological Engineering, 90: 294–306.10.1016/j.ecoleng.2016.01.018Search in Google Scholar

NEMES, A. (2003): Unsaturated soil hydraulic database of Hungary: HUNSODA. Agrokémia és Talajtan, 51(1–2): 17–26.Search in Google Scholar

NPPC (2014): Vektorové databázy BPEJ pre modelové územia Hriňová, Levoča (M 1:10,000). Bratislava.Search in Google Scholar

PACHEPSKY, Y. A, RAWLS, W. J, TIMLIN D. J. (1999): The current status of pedotransfer functions: their accuracy, reliability and utility in field- and regional-scale modelling. In: Corwin, D. L. et al. [eds.]: Assessment of Non-point Source Pollution in the Vadose Zone, Geophysical Monograph 108 (pp. 223–234). Washington, DC, American Geophysical Union.10.1029/GM108p0223Search in Google Scholar

PACHEPSKY, Y. A., TIMLIN, D. J., VARALLYAY, G. (1996): Artificial neural networks to estimate soil water retention from easily measurable data. Soil Science Society of America Journal, 60: 727–733.10.2136/sssaj1996.03615995006000030007xSearch in Google Scholar

PACHEPSKY, Y. A., RAWLS, W. J. [eds.] (2005): Development of pedotransfer functions in Soil Hydrology. Developments in Soil Science, 30, Amsterdam, Elsevier.Search in Google Scholar

SCHAAP, M. G, LEIJ, F. J. (1998): Database-related accuracy and uncertainty of pedotransfer functions. Soil Science, 163(10): 765–779.10.1097/00010694-199810000-00001Search in Google Scholar

SOET, M., STRICKER, J. N. M. (2003): Functional behaviour of pedotransfer functions in soil water flow simulation. Hydrological Processes, 17: 1659–167010.1002/hyp.1207Search in Google Scholar

SWANSON, T. M., BARBIER, E. B. [eds.] (1992): Economics for the Wilds: wildlife, wildlands, diversity and development. London, Earthscan.Search in Google Scholar

ŠÚTOR, J., ŠTEKAUEROVÁ, V. (1999): Určovanie bodov vlhkostnej retenčnej čiary zo základných fyzikálnych charakteristík pôdy. In: Proceedings of the III. Conference „Vplyv antropogénnej činnosti na vodný režim nížinného územia ÚH SAS, Michalovce – Zemplínska Šírava, pp. 151–157.Search in Google Scholar

ŠTEKAUEROVÁ, V., SKALOVÁ, J., ŠÚTOR, J. (2002): Using of pedotransfer functions for assessment of hydrolimits. Rostlinná Výroba, 48: 407–412.10.17221/4388-PSESearch in Google Scholar

TIETJE, O., TAPKENHINRICHS, M. (1993): Evaluation of pedo-transfer function. Soil Science Society of America Journal, 57: 1088–1095.10.2136/sssaj1993.03615995005700040035xSearch in Google Scholar

TIETJE, O., HENNINGS, V. (1996): Accuracy of the saturated hydraulic conductivity prediction bypedo-transfer functions compared to the variability within FAO textural classes. Geoderma, 69: 71–84.10.1016/0016-7061(95)00050-XSearch in Google Scholar

VAN ALPHEN B. J, BOOLTINK H. W. G., BOUMA J. (2001): Combining pedotransfer functions with physical measurements to improve the estimation of soil hydraulic properties. Geoderma, 103: 133–147.10.1016/S0016-7061(01)00073-8Search in Google Scholar

VÚPOP (2000): Morfogenetický klasifikační systém pôd Slovenska. Bazálná referenčná taxonomia. Bratislava.Search in Google Scholar

WÖSTEN, J. H. M, PACHEPSKY, Y. A., RAWLS, W. J. (2001): Pedotransfer functions: bridging the gap between available basic soil data and missing soil hydraulic characteristics. Journal of Hydrology, 251(3–4): 123–150.10.1016/S0022-1694(01)00464-4Search in Google Scholar

WÖSTEN, J. H. M, FINKE, P. A, JANSEN, M. J. W. (1999): Comparison of class and continuous pedotransfer functions to generate soil hydraulic characteristics. Geoderma, 66: 227–237.10.1016/0016-7061(94)00079-PSearch in Google Scholar

WAGNER, B., TARNAWSKI, V. R., HENNINGS, V., MÜLLER, U., WESSOLEK, G., PLAGGE, R. (2001): Evaluation of pedo-transfer functions for unsaturated soil hydraulic conductivity using an independent data set. Geoderma, 102: 275–297.10.1016/S0016-7061(01)00037-4Search in Google Scholar

WÖSTEN, J. H. M. (1999): The Hypress database of hydraulic properties of European soils Source In: Feyen, J., Wiyo, K. [eds.]: Modelling of transport processes in soils at various scales in time and space; international workshop of EurAgEng's field of interest on soil and water. Wageningen, Wageningen Pers, (pp. 675–681). Department(s) Winand Staring Centre for Integrated Land, Soil and Water Research Database of Hydraulic Properties of European Soils (HYPRES), version 1.0Search in Google Scholar

YAALON, D. H., ARNOLD, W. (2000): Attitudes toward soils and their societal relevance: Then and now. Soil Science, 165(1): 5–12.10.1097/00010694-200001000-00003Search in Google Scholar