Architecture of a Pan-European Framework for Integrated Soil Water Erosion Assessment. de Rigo, D. and Bosco, C. 359:310–318.
Architecture of a Pan-European Framework for Integrated Soil Water Erosion Assessment [link]Paper  doi  abstract   bibtex   
Soil erosion implications on future food security are gaining global attention because in many areas worldwide there is an imbalance between soil loss and its subsequent deposition. Soil erosion is a complex phenomenon affected by many factors such as climate, topography and land cover (in particular forest resources, natural vegetation and agriculture) while directly influencing water sediment transport, the quality of water resources and water storage loss. A modeling architecture, based on the Revised Universal Soil Loss Equation, is proposed and applied to evaluate and validate at regional scale potential and actual soil water erosion, enabling it to be linked to other involved natural resources. The methodology benefits from the array programming paradigm with semantic constraints (lightweight array behavioural contracts provided by the Mastrave library) to concisely implement models as composition of interoperable modules and to process heterogeneous data.
@article{derigoArchitecturePanEuropeanFramework2011,
  title = {Architecture of a Pan-{{European}} Framework for Integrated Soil Water Erosion Assessment},
  author = {de Rigo, Daniele and Bosco, Claudio},
  editor = {Hreb́ıcek, Jiŕı and Schimak, Gerald and Denzer, Ralf},
  date = {2011},
  journaltitle = {IFIP Advances in Information and Communication Technology},
  volume = {359},
  pages = {310--318},
  issn = {1868-4238},
  doi = {10.1007/978-3-642-22285-6_34},
  url = {https://doi.org/10.1007/978-3-642-22285-6_34},
  abstract = {Soil erosion implications on future food security are gaining global attention because in many areas worldwide there is an imbalance between soil loss and its subsequent deposition. Soil erosion is a complex phenomenon affected by many factors such as climate, topography and land cover (in particular forest resources, natural vegetation and agriculture) while directly influencing water sediment transport, the quality of water resources and water storage loss. A modeling architecture, based on the Revised Universal Soil Loss Equation, is proposed and applied to evaluate and validate at regional scale potential and actual soil water erosion, enabling it to be linked to other involved natural resources. The methodology benefits from the array programming paradigm with semantic constraints (lightweight array behavioural contracts provided by the Mastrave library) to concisely implement models as composition of interoperable modules and to process heterogeneous data.},
  keywords = {*imported-from-citeulike-INRMM,~INRMM-MiD:c-10793234,environmental-modelling,gnu-octave,gnu-r,grass-gis,inrmm,inrmm-relationship-schemata,integrated-natural-resources-modelling-and-management,mastrave-modelling-library,regional-scale,semantic-array-programming,semap,soil-erosion},
  options = {useprefix=true},
  series = {{{IFIP Advances}} in {{Information}} and {{Communication Technology}}}
}
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