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ENSEMBLE MODELING IN SOIL HYDROLOGY

Asoc. Milan Cisty

First published: 2014-06-20https://doi.org/10.5593/sgem2014/b31/s12.031View metrics

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  • Citations
  • CrossRef - Citation Indexes: 1
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  • Mendeley - Readers: 4

Publication details

Title
ENSEMBLE MODELING IN SOIL HYDROLOGY
Authors
Asoc. Milan Cisty
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 14th SGEM GeoConference on WATER RESOURCES. FOREST, MARINE AND OCEAN ECOSYSTEMS
Publisher
Stef92 Technology
Year
2014
Pages
Not available yet
ISSN
1314-2704
ISBN
978-619-7105-13-1
Language
en
Publication type
Conference Paper
References22
  1. Haverkamp R. & Parlange J.Y. Predicting the water-retention curve from particle- size distribution: 1. Sandy soils without organic matter, Soil Sci., vol. 142/issue 6, pp 325-339, 1986.

  2. Botula Y.D., Cornelis W. M., Baert G., Mafuka P. & Van Ranst E. Particle size distribution models for soils of the humid tropics, J Soils Sediments., vol. 13, pp –698, 2013.

  3. Breiman L. Random forests, Machine learning, vol. 45/issue 1, pp 5-32, 2001.

  4. Zhao P., Shao M. & Horton R., Performance of Soil Particle-Size Distribution Models for Describing Deposited Soils Adjecent to Constructed Dams in the China Loess Plateau, Acta Geophysica, Versita, pp 124-138, 2011.

  5. Assouline S. Tessier D. & Bruand A., A conceptual model of the soil water retention curve, Water Resour Res., vol. 34, pp 223–231, 1998.

  6. Jauhiainen M. Relationships of particle size distribution curve, soil water retention curve and unsaturated hydraulic conductivity and their implications on water balance of forested and agricultural hillslopes, Ph.D dissertation, Helsinki University of Technology, Finland, 2004.

  7. Andersson S. Markfysikaliska undersökningar i odlad jord, XXVI. Om mineraljordens och mullens rumsutfyllande egenskaper En teoretisk studie (In Swedish), Swedish University of Agricultural Sciences, Uppsala, 1990.

  8. Nemes A., Wosten J. H. M., Lilly A. &. Voshaar J. H. O. Evaluation of different procedures to interpolate particle-size distributions to achieve compatibility within soil databases, Geoderma., vol. 90, pp 187– 202, 1999.

  9. Botula Y.D., Cornelis W. M., Baert G. & Van Ranst E. Evaluation of pedotransfer functions for predicting water retention of soils in Lower Congo (D.R. Congo), Agr Water Manage, vol. 111, pp 1– 10, 2012.

  10. Botula Y . D., Cornelis W. M., Baert G., Mafuka P. & Van Ranst E. Particle Size Distribution Models for Soils of the Humid Tropics, Journal of Soils and Sediments, Vol. 13/issue 4, pp 686–698, 2013.

  11. Kuhn M. & Johnson K. Applied predictive modeling. New York: Springer, 2013.

  12. Haverkamp R. & Parlange J.Y. Predicting the water-retention curve from particle- size distribution: 1. Sandy soils without organic matter, Soil Sci., vol. 142/issue 6, pp 325-339, 1986.

  13. Botula Y.D., Cornelis W. M., Baert G., Mafuka P. & Van Ranst E. Particle size distribution models for soils of the humid tropics, J Soils Sediments., vol. 13, pp –698, 2013.

  14. Breiman L. Random forests, Machine learning, vol. 45/issue 1, pp 5-32, 2001.

  15. Zhao P., Shao M. & Horton R., Performance of Soil Particle-Size Distribution Models for Describing Deposited Soils Adjecent to Constructed Dams in the China Loess Plateau, Acta Geophysica, Versita, pp 124-138, 2011.

  16. Assouline S. Tessier D. & Bruand A., A conceptual model of the soil water retention curve, Water Resour Res., vol. 34, pp 223–231, 1998.

  17. Jauhiainen M. Relationships of particle size distribution curve, soil water retention curve and unsaturated hydraulic conductivity and their implications on water balance of forested and agricultural hillslopes, Ph.D dissertation, Helsinki University of Technology, Finland, 2004.

  18. Andersson S. Markfysikaliska undersökningar i odlad jord, XXVI. Om mineraljordens och mullens rumsutfyllande egenskaper En teoretisk studie (In Swedish), Swedish University of Agricultural Sciences, Uppsala, 1990.

  19. Nemes A., Wosten J. H. M., Lilly A. &. Voshaar J. H. O. Evaluation of different procedures to interpolate particle-size distributions to achieve compatibility within soil databases, Geoderma., vol. 90, pp 187– 202, 1999.

  20. Botula Y.D., Cornelis W. M., Baert G. & Van Ranst E. Evaluation of pedotransfer functions for predicting water retention of soils in Lower Congo (D.R. Congo), Agr Water Manage, vol. 111, pp 1– 10, 2012.

  21. Botula Y . D., Cornelis W. M., Baert G., Mafuka P. & Van Ranst E. Particle Size Distribution Models for Soils of the Humid Tropics, Journal of Soils and Sediments, Vol. 13/issue 4, pp 686–698, 2013.

  22. Kuhn M. & Johnson K. Applied predictive modeling. New York: Springer, 2013.

Citing literature

Number of times cited according to Crossref: 1

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