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TitreOn blind tests and spatial prediction models
AuteurFabbri, A G; Chung, C -J
SourceNatural Resources Research vol. 17, no. 2, 2008 p. 107-118, https://doi.org/10.1007/s11053-008-9072-y (Accès ouvert)
Année2008
Séries alt.Secteur des sciences de la Terre, Contribution externe 20080556
ÉditeurSpringer Nature
Documentpublication en série
Lang.anglais
DOIhttps://doi.org/10.1007/s11053-008-9072-y
Mediapapier; en ligne; numérique
Référence reliéeCette publication est reproduite dans Fabbri, A G; Fabbri, A G; Chung, C -J; Chung, C -J; (2008). On blind tests and spatial prediction models, Progress in geomathematics
Formatspdf (Adobe® Reader®)
Sujetsgéomathématique; statistiques; modèles; potentiel minier; effets sur l'environnement; géomathématique; géologie économique; géologie de l'ingénieur; géologie de l'environnement
Illustrationsflow charts; graphs
Diffusé2008 05 28
Résumé(disponible en anglais seulement)
This contribution discusses the usage of blind tests, BT, to cross-validate and interpret the results of predictions by statistical models applied to spatial databases. Models such as Bayesian probability, empirical likelihood ratio, fuzzy sets, or neural networks were and are
being applied to identify areas likely to contain events such as undiscovered mineral resources, zones of high natural hazard, or sites with high potential environmental impact. By processing the information in a spatial database, the models establish the relationships between the distribution of known events and their contextual settings, described by both thematic and continuous data layers. The relationships are to locate situations where similar events are likely to occur. Maps of predicted relative resource potential or of relative hazard/impact levels are generated. They consist of relative values that need careful quantitative scrutiny to be interpreted for taking decisions on further action in exploration or on hazard/impact mitigation and avoidance. The only meaning of such relative values is their rank. Obviously, to assess the reliability of the predicted ranks, tests are indispensable. This is also a consequence of the impracticality of waiting for the future to reveal the goodness of our prediction. During the past decade only a few attempts have been made by some researchers to cross-validate the results of spatial predictions. Furthermore, assumptions and applications of cross-validations differ considerably in a number of recent case studies. A perspective for all such experiments is provided using two specific examples, one in mineral exploration and the other in landslide hazard, to answer the fundamental question: how good is my prediction?
GEOSCAN ID226222