Stochastic Imaging of Environmental Data
Jean-Jacques Royer and Arben Shtuka. ( 1997 )
in: Geosciences and Water Resources: Environmental Data Modeling, pages 101-114, Springer Berlin Heidelberg
Abstract
Home Geosciences and Water Resources: Chapter Stochastic Imaging of Environmental Data Jean-Jacques Royer & Arben Shtuka Chapter 250 Accesses Part of the Data and Knowledge in a Changing World book series (DATAKNOWL) Abstract Interpretation of environmental data is currently confronted with the problem of estimating the spatial variation of a parameter from a limited number of sample points irregularly distributed in space. The challenge is to extract the relevant information for a given problem from the individual observations at control points. For example, in risk analysis (water resource monitoring, overflow forecasting, pollution monitoring), the emphasis is on detecting the maximum value or the anomalies of the appropriate parameter. Within this framework, classical numerical mapping techniques such as spline interpolation, multivariate regression or kriging, are of little use, because they provide an estimation of the mean local value while the expected distribution of the parameter would be more relevant. In this paper, a stochastic simulation technique based on indicator functions is presented. It provides at each unknown point an estimation of the conditional probability function which can be further used to produce a “Stochastic image” or a realistic simulation map of the unknown parameter. This technique is also used to build various non-parametric estimators of an expected value (such as minimum, maximum, median, inter quartile range) which can be used in risk analysis. A case study in environmental monitoring is presented to illustrate the procedure.
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BibTeX Reference
@incollection{royer:hal-04041209, abstract = {Home Geosciences and Water Resources: Chapter Stochastic Imaging of Environmental Data Jean-Jacques Royer & Arben Shtuka Chapter 250 Accesses Part of the Data and Knowledge in a Changing World book series (DATAKNOWL) Abstract Interpretation of environmental data is currently confronted with the problem of estimating the spatial variation of a parameter from a limited number of sample points irregularly distributed in space. The challenge is to extract the relevant information for a given problem from the individual observations at control points. For example, in risk analysis (water resource monitoring, overflow forecasting, pollution monitoring), the emphasis is on detecting the maximum value or the anomalies of the appropriate parameter. Within this framework, classical numerical mapping techniques such as spline interpolation, multivariate regression or kriging, are of little use, because they provide an estimation of the mean local value while the expected distribution of the parameter would be more relevant. In this paper, a stochastic simulation technique based on indicator functions is presented. It provides at each unknown point an estimation of the conditional probability function which can be further used to produce a “Stochastic image” or a realistic simulation map of the unknown parameter. This technique is also used to build various non-parametric estimators of an expected value (such as minimum, maximum, median, inter quartile range) which can be used in risk analysis. A case study in environmental monitoring is presented to illustrate the procedure.}, author = {Royer, Jean-Jacques and Shtuka, Arben}, booktitle = {{Geosciences and Water Resources: Environmental Data Modeling}}, doi = {10.1007/978-3-642-60627-4\_11}, editor = {Bardinet and C. AND Royer and Jean-Jacques}, hal_id = {hal-04041209}, hal_version = {v1}, keywords = {Risk assessment ; stochastic modeling ; mathematical model ; geostatistic ; simulation ; GOCAD ; pollution ; environment}, pages = {101-114}, publisher = {{Springer Berlin Heidelberg}}, series = {Data and Knowledge in a Changing World}, title = {{Stochastic Imaging of Environmental Data}}, url = {https://hal.univ-lorraine.fr/hal-04041209}, year = {1997} }